tooth for attachment to the edge of a bucket of an operational machine and adapter for attachment to

专利摘要:
TOOTH FOR FIXING THE EDGE OF AN OPERATIONAL MACHINE, LIKE AN EXCAVATOR OR LOADING MACHINE, THROUGH AN ADAPTER, ADAPTER FOR FITTING A TOOTH ON THE EDGE OF AN OPERATING MACHINE BUCKETER, LIKE AN EXCAVATOR OR MACHINE MACHINE. The present disclosure refers to a tooth (1) for attaching to the edge of a bucket of an operational machine, such as an excavator or loader, by means of an adapter, the tooth (1) comprising a cavity (103) to receive a part of said adapter, the cavity (103) extending between said first and second opposing external functional surfaces (12, 14) from an open end (104), on said tooth attachment end, to a lower end (105) ; the cavity (103) being delimited by an internal wall (102); said internal wall (102) comprising first and second internal walls facing internally (106, 107), which are the internal surfaces associated with said first external functional surface and said second external functional surface (12,14), respectively, and side walls opposite sides (108), which interconnect said first and second inner walls (106, 107), the cavity defining a rear part (BP) extending along the Y axis, the rear part being at least partially located between the covered plane by the X and Z axes and (...)
公开号:BR112016025243B1
申请号:R112016025243-8
申请日:2014-04-29
公开日:2021-02-09
发明作者:Francisco Perez Soria；Fermin Sanchez Guisado；Javier Rol Corredor；Jorge Triginer Boixeda
申请人:Metalogenia Research & Technologies S.L；
IPC主号:

专利说明:

FIELD OF THE INVENTION
[001] The present invention relates to a tooth for attachment to the edge of a bucket of an operational machine, such as an excavator or a loader, by means of an adapter. The invention also relates to an adapter for attaching the tooth to the edge of a bucket of an operational machine. BACKGROUND OF THE INVENTION
[002] Operational machines, such as excavators and loaders having buckets or furrowers for digging or digging, for example, earth or rock debris, are commonly provided with one or more teeth, fixed to the bucket by means of an adapter. The teeth are parts of wear that are removable from the adapters, in order to allow the replacement of worn teeth with new ones.
[003] To carry out excavation or digging operations, the teeth must be able to penetrate the material, such as earth or clay. For this purpose, the teeth may have an elongated external shape, which narrows from an attachment part adjacent to the adapter (towards the bucket) to a relatively thin tip part. With this, at least towards the tip of the tooth, the tooth will assume a tooth-like appearance, having two important surfaces that converge towards and meet at the tip of the tooth. that converge towards and meet at the tip of the tooth.
[004] To acquire the desired penetration capacity, the external shape of the teeth, therefore, must be of sufficient length and adequate fineness.
[005] In use, the teeth will be subjected to considerable loads and, in general, to a harsh environment. Therefore, the teeth must be strong and robust enough to resist breaking.
[006] In addition, there is a general requirement that teeth, being replacement parts, must be available at a reasonable price. This raises a desire to reduce the amount of material used for the tooth. The requirements for an external shape that provides sufficient penetration, the requirements for strength and strength of the teeth, and the desire to reduce the amount of material are divergent. With this, it is a challenge to find a successful compromise between the requirements. To this end, a wide variety of teeth with different designs has been proposed in the past.
[007] The tooth and the adapter must include corresponding aspects to allow the coupling of the tooth to the adapter. These corresponding aspects are hereinafter referred to as a “coupling”. This coupling must allow secure and fixed attachment of the tooth to the adapter, and must have sufficient strength and strength to withstand the forces involved when the tooth is in use.
[008] Furthermore, the coupling should desirably allow the removal of a worn tooth from an adapter, and allow the attachment of a new tooth to the same adapter.
[009] In summary, it is desired that a coupling between one and an adapter should meet several different requirements.
[010] The need for a well-functioning coupling must be met taking into account, also, the general requirements of the tooth as a whole, as mentioned above.
[011] In order to achieve a suitable coupling between a tooth and an adapter, it is known to provide the tooth with a cavity extending from a tooth attachment end, and to provide the adapter with a tip part corresponding to the cavity, so that the tooth can be installed by the adapter with the tip part disposed inside the cavity. To fix the tooth to the adapter, it is known to use a fixing pin, which extends through hollow holes aligned in the tooth cavity and through corresponding hollow holes in the tip part of the adapter.
[012] Adapters can be attached to the blade in different ways, as welded, they can be part of the blade as a molten tip or they can be mechanically attached. For example, in mining, three-part systems are used, where the tip part of the adapter forms part of the bucket blade, with a molten tip.
[013] In couplings that use a fixing pin, it is desirable to reduce the risk of breaking the fixing pin when the tooth, in use, is subjected to considerable loads.
[014] Another issue with these couplings is that, even if the fixing pin does not break, when the tooth is in use, the pin could be deformed. A deformed pin can be quite difficult to remove from the hollow holes in the tooth and adapter, so removing a worn tooth from the adapter can be complicated. Generally, in this situation, the pin should be hammered out of the hollow holes.
[015] This procedure is highly undesired, and to remove its inconvenience, so-called hammerless couplings have been proposed.
[016] In view of the above, it is generally desired to allow a coupling of the type having a cavity and a corresponding tip part, through which a fixing pin can extend, and which ensures easy application and removal of the fixing pin. display, preferably by a maneuver without a hammer.
[017] US 2010 0236108 describes a tooth for attaching an excavator to a tip (adapter) by means of a fixture that extends through at least one of the side walls of the tooth. The excavator tooth includes side walls having interface surfaces that fit with the essentially planar tip formed in each other, one surface resisting rotation of the tooth on the longitudinal axis in one direction, and another interface surface resisting rotation of the tooth in one direction. opposite.
[018] US 5 709043 describes an excavating tooth that has support faces that are formed to enlarge significantly as they extend backwards, to provide wide support surfaces at the rear ends of the wear member. The support faces are placed at obtuse angles to the converging walls and the side walls, in order to avoid areas of stress concentration.
[019] A first objective of the invention is to provide a tooth that allows coupling of said tooth to the edge of a bucket of an operational machine by means of an adapter, and which presents an alternative to or an advantage over previous solutions in relation to a or more of the aspects mentioned above.
[020] A second objective of the invention is to provide an adapter that allows coupling a tooth to the edge of a bucket of an operational machine by means of said adapter, and which presents an alternative to or an advantage over previous solutions in relation to a or more of the aspects mentioned above. SUMMARY OF THE INVENTION
[021] The first objective mentioned above is achieved by a tooth, according to claim 1 attached.
[022] The second objective mentioned above is achieved by an adapter, according to claim 46 attached.
[023] In a first aspect, the invention refers to a tooth for attachment to the edge of the bucket of an operational machine, such as an excavator or loader, by means of an adapter, the tooth having an outer surface comprising two external functional surfaces , externally opposed, namely, a first functional surface and a second functional surface, the functional surfaces having a width in a horizontal direction, intended to extend along said edge of a bucket, and having a length that extends between a affixing end and a tip of said tooth, the functional surfaces extending along said length, while converging in a vertical direction to be connected to said tip of the tooth. The tooth further comprises a cavity for receiving a portion of said adapter, the cavity extending between said first and second external functional surfaces opposite an open end at said end of affixing the tooth, to a lower end; the cavity being delimited by an internal wall. The inner wall comprising first and second inner walls facing inwardly, the inner surfaces being associated with said first outer functional surface and said second outer functional surface, respectively, and opposite side walls, which interconnect said first and second inner walls. The opposite side walls delimit opposite hollow holes to receive a pin that extends through the cavity to affix the tooth to the adapter part, a first X axis being defined, extending through the centers of the opposite hollow holes, a second Y axis that extends along the cavity of the open end of the cavity towards the lower end of the cavity, and a third Z axis being orthogonal to the said first and second axes X, Y, the three axes X, Y, Z, thereby forming a system of orthogonal axes, which are in an origin, with which, each point of the inner wall can be defined by Cartesian coordinates (x, y, z).
[024] The cavity defines a rear part that extends along the Y axis, the rear part being at least partially located between the plane covered by the X and Z axes and the open end of the cavity, a front part that extends along the Y axis, the front part being located between the plane covered by the X and Z axes and the lower end of the cavity; and a staggered part, interconnecting the rear and the front.
[025] At the rear, the first and second inner walls, each, comprise a pair of essentially planar rear contact surfaces, each pair of rear contact surfaces being symmetrical over and facing away from the plane covered by the Z and Z axes Y, in order to form an angle (beta, gamma) with the plane covered by the X and Y axes being less than 35 degrees, each pair of rear contact surfaces being separated by a rear dividing region, which extends behind the first pair contact surfaces in the Z direction away from the plane covered by the X and Y axes.
[026] At the front, the first and second internal walls, each one comprises a pair of essentially planar front contact surfaces, being symmetrical over the plane covered by the Z and Y axes.
[027] All contact surfaces form an angle (alpha) less than 5 degrees with the Y axis, as seen in any plane parallel to the plane covered by the Z and Y axes.
[028] The first and / or second front contact surfaces being located closer to the plane covered by the X and Y axes than the corresponding rear contact surfaces, and
[029] the first and / or second inner wall of the staggered part forming a slope in which at least a part of the inner wall approaches the XY plane towards the lower wall, interconnecting said first and / or second rear contact surfaces and the first and / or second corresponding front contact surfaces.
[030] A first stepped distance along the Z axis is bridged by the first inner wall along the stepped part, between the first rear contact surfaces and the first front contact surfaces; and a second stepped distance along the Z axis is bridged by the second inner wall along the stepped part, between the second rear contact surfaces and the second front contact surfaces; where 0 <= D2 <= 0.80 D1.
[031] The aspects mentioned above applied to the rear of the cavity convey several advantages to the proposed tooth.
[032] First, the proposed rear part allows an advantageous force distribution in the coupling between the tooth and the adapter.
[033] When the tooth is connected to the adapter, contact between the tooth and the adapter should occur in the pairs of the first and second rear contact surfaces, but not in the first and second rear dividing regions, separating the respective pairs of rear contact surfaces . The first and second rear dividing regions of the internal cavity wall are, therefore, parts of the internal tooth wall that are not intended to be in contact with the adapter.
[034] Likewise, along the rear, on the first inner wall and on the second inner wall, the contact between the tooth and the adapter must occur through two contact surfaces that are spaced along the X axis. This means that loads that will be distributed over the first inner wall or the second inner wall at the rear must be distributed between two separate planar contact surfaces, which operate in parallel. This will decrease the stress on the tooth material. The separation of the contact surfaces using a dividing region will reduce the bending moment and, consequently, the stresses in the tooth material of the first or second inner wall in the center of the tooth, along the plane covered by the Z and Y axes. By reducing the stresses , the risk of the tooth cracking or breaking is reduced. Likewise, the thickness of the tooth wall (between the first and / or second internal wall and the corresponding external functional surface) can be reduced, which allows the use of a smaller amount of material, with maintained strength and robustness.
[035] In addition, each pair of first and second rear contact surfaces is symmetrical over and turns away from the plane covered by the Z and Y axes, so as to form an angle (beta / gamma) with the plane covered by the X axes and Y that is less than 35 degrees.
[036] When one of the pairs of rear contact surfaces is active, distributing loads to the corresponding rear contact surfaces on the tip part of the adapter, the forces involved will therefore have a component that acts in a direction towards the plane covered by the Y and Z axes. This, in turn, means that when loads are applied to the contact surfaces, their effect will be that the tooth is additionally fixed to the adapter. This contributes to secure coupling.
[037] Also, the arrangement with the inclined rear contact surface pairs being separated by the rear dividing region, which extends behind the inclined rear contact surfaces in a direction away from the plane covered by the X and Y axes, allows the contour of the internal walls and, consequently, also the contour of the external surfaces, the tooth is optimized in relation to wear.
[038] As briefly mentioned above, when the tooth is in use, the first and second external functional surfaces will be subject to wear, gradually removing the material from said external functional surfaces. In general, wear will start at the tip of the tooth and, eventually, through continuous wear, the tooth will decrease. If wear reaches the contact surfaces between the tooth and the adapter, the connection between the tooth and the adapter will be compromised, and the tooth must be replaced.
[039] In general, when subjected to wear, the external functional surfaces of the tooth will be changed, in order to follow a wear curve, since the material will be gradually removed from the first and second functional surfaces of the tooth. With this, the first and / or second functional surface can assume a curved external shape, which is different from the original shape. This wear curve can be described, when viewed in a transverse direction along the XZ plane, as a symmetrical curve having an apex on the Z axis and declining towards the lateral walls of the tooth.
[040] In the suggested tooth, if a functional outer surface is subject to wear, and gradually conforms to this wear curve, it will be understood that the rear contact surfaces of the corresponding inner wall will be protected by the rear dividing region that extends behind the rear contact surfaces. In other words, the rear contact surfaces will be the last parts of the cavity's inner wall to be affected by wear. This ensures that the tooth remains firmly attached to the adapter, even when considerable wear occurs.
[041] Furthermore, advantageously, the first and / or second rear dividing region and the outermost parts (towards the lateral surfaces) of the corresponding rear contact surfaces can be positioned along a curve approximately corresponding to a curve of wear. With this, it can be guaranteed that when wear occurs, the contact surfaces are the last surfaces to be affected by it. Also, the arrangement will make good use of the material in the tooth, since the tooth will work satisfactorily until much of the material originally provided between the outer surfaces and the inner walls is worn. With this, there is an efficient use of material, since a relatively large part of the used material of the tooth will be available for use and wear. When the tooth is finally worn out and needs to be replaced, a relatively small proportion of the initial amount of tooth material remains.
[042] Also, the rear dividing region that extends behind the rear contact surfaces on the first and second inner walls of the cavity allows the corresponding rear dividing regions at the tip end of the adapter to extend behind the rear contact surfaces of the adapter. With this, the rear partitioning regions of the tip part will add material to the tip part, with this, the strength of the tip part can be improved.
[043] It will be understood that the explanations above apply equally to the first rear contact surfaces and to the first rear dividing region and to the second rear contact surfaces and to the second rear dividing region.
[044] According to the embodiments, the angle (beta, gamma) is less than 25 degrees, preferably 10 to 20 degrees, preferably 12 to 17 degrees, more preferred about 15 degrees.
[045] In general, the respective angles of inclination of the first and second rear contact surfaces must be selected, in order to achieve the desired clamping effect, while still allowing the distribution of the vertical forces to which the tooth is subjected during the use. In addition, the shape of the wear curve, as explained above, can be taken into account when selecting a suitable angle. The angles mentioned above were found to be particularly useful in order to provide the desired effects.
[046] According to the first aspect of the invention, the cavity defines a rear part that extends along the Y axis, the rear part being at least partially located between the plane covered by the X and Z axes and the open end of the cavity ,
[047] a front part that extends along the Y axis, the front part being located between the plane covered by the X and Z axes and the lower end of the cavity; and a staggered part, interconnecting the rear and the front.
[048] Contact surfaces are provided at the rear and at the front of the cavity, on the first and second internally opposite internal walls. When in use, the first and second contact surfaces at the rear and front of the tooth will be in contact with corresponding surfaces of the adapter and, thus, will be efficient in transferring forces applied to the tooth to the adapter.
[049] When the tooth is in use, attached to a bucket through the adapter, vertical loads applied to the first or second external surface of the tooth, and adjacent to the tip of the tooth, will appear frequently. Furthermore, these forces can be relatively large. Likewise, it is desired that the coupling must be well adapted to withstand these vertical loads.
[050] Vertical loads will generally be transferred from the first or second external functional surface, adjacent to the tip of the tooth, to the first or second contact surfaces of the first or second internal cavity wall. The front and rear contact surfaces will be working in pairs. If a vertical force is acting towards the second outer wall adjacent to the tip of the tooth, the first rear contact surfaces and second front contact surfaces will form a pair that transmits the charge created by the vertical force to the tip portion of the adapter.
[051] Similarly, if a vertical force is acting towards the first external wall adjacent to the tip of the tooth, the second rear contact surfaces and the first front contact surfaces will form a pair that transmits the load to the tip part of the tooth. adapter.
[052] In order for the contact surfaces to efficiently transfer vertical loads, it is generally desired that the contact surfaces should be as close as possible to being parallel to each other, and to the Y axis (as seen in any parallel plane to the plane covered by the Y and Z axes). However, in order to allow adjustment and removal of the tooth to / from the adapter, a slight deviation from the parallel surfaces may be necessary. The deviation could be up to 5 degrees, preferably no more than 2 degrees.
[053] Therefore, all said first and second rear and front contact surfaces are to form an angle (alpha) less than 5 degrees with the Y axis, as seen in any plane parallel to the plane covered by the Z and Y axes. Preferably , the alpha angle can be less than 2 degrees.
[054] At least the first and second rear contact surfaces must form the same angle (alpha) less than 5 degrees with the Y axis. This defines the Y axis in the bisector between the first and second rear contact surfaces.
[055] The rear part extends along the Y axis, and is at least partially located between the plane covered by the X and Z axes and the open end of the cavity. This means that the entire rear part can be located between the XZ plane and the open end, and said rear part may or may not extend from the XZ plane. Alternatively, the rear part can extend from a position behind the XZ plane, through the XZ plane and towards a position located in front of the XZ plane. (Backwards meaning towards the open end of the cavity and forwards meaning towards the lower end of the cavity.)
[056] As will be described below, the first and second pairs of rear contact surfaces, with the corresponding rear dividing regions, are extending at the rear of the cavity, and with that, the rear contact surfaces will be extending at least partially behind the plane covered by the X and Z axes, which is behind the centers of the pin holes. The first and second front contact surfaces are, on the contrary, arranged on the front, which is located in front of the centers of the holes for the attachment pin. Through this arrangement, and since the front and rear contact surfaces are working in pairs, as explained above, a force distribution is allowed, which reduces the tension in the tooth area adjacent to the holes for the fixation pin. This can decrease the risk that the tooth will be broken or damaged in the area adjacent to the hollow holes for the attachment pin.
[057] Likewise, the display pin arrangement is protected from excessive load. This, in turn, means that the function of the pin can be maintained during use of the tooth, resulting in a stable attachment and maintaining possibilities for easy removal of the tooth from the adapter.
[058] At least one pair of the two pairs of first and second front contact surfaces is located closer to the plane covered by the X and Y axes than the corresponding rear contact surfaces.
[059] The provision of at least one of the first and second rear and front contact surfaces in different planes, with the front contact surfaces closer to the plane covered by the X and Y axes than the corresponding rear contact surfaces, contributes for controlled force distribution that protects the pin area of the connection. In addition, the arrangement provides a cavity that becomes narrower in the direction towards the tip of the tooth, thereby following the general requirement for a tooth having an outer surface that tapers towards the tip.
[060] The cavity defines a staggered part, which interconnects the rear and the front. In the staggered part, the first and / or second inner wall forms a slope that interconnects the first and / or second rear contact surface and the corresponding first and / or second front contact surface (these surfaces are located in different planes).
[061] The slope should be advantageously curved. Preferably, the slope can be S-shaped.
[062] It will be understood that to be a “slope”, the slope must deviate from the plane of the first (or second) rear contact surface, and approach the plane covered by the X and Y axes, in order to interconnect with the first (or second) front contact surface.
[063] The “slope” could comprise one or more slope regions on the internal wall of the staggered part.
[064] Advantageously, the slope could interconnect a front and rear contact surface that are mutually arranged, so that, if they were interconnected by a straight line, that line would form an angle of more than 10 degrees, preferably more than 20 degrees with the plane covered by the X and Y axes. (As seen in any plane parallel to the plane covered by the Y and Z axes, and referring to the smallest angle between the planes).
[065] An “essentially planar” surface is defined here as a surface that substantially coincides with an imaginary planar square having the dimensions DxD, where any deviation from that square is less than 0.2 D. This surface can be a contact surface , provided that other conditions defined herein are met. Preferably, an essentially planar surface here could be a surface that substantially coincides with an imaginary planar square having the dimensions DxD, where any deviation from that square is less than 0.1 D.
[066] According to the achievements, the second rear contact surfaces and the second essentially planar front contact surfaces can be essentially the same distance from the plane covered by the X and Y axes. This provides a relatively flat shape of the second wall which can be particularly advantageous for loader applications.
[067] According to the embodiments, the second rear contact surfaces and the second essentially planar front contact surfaces can be arranged on the same planes.
[068] In this case, on the inclined part of the cavity, the second inner wall can advantageously form a planar surface, interconnecting the second rear contact surfaces and the second front contact surfaces. (In this case, on the sloping part of the cavity, only the first inner wall will comprise a slope.)
[069] All the first and second front and rear contact surfaces can advantageously form an alpha angle less than 2 degrees with the Y axis, preferably the same alpha angle.
[070] At the rear, the first inner wall will comprise a pair of first essentially planar rear contact surfaces that are symmetrical over, and which turn in opposition to the plane covered by the Z and Y axes, in order to form a beta angle with the plane covered by the X and Y axes that is less than 35 degrees. In addition, the pair of first rear contact surfaces is separated by a first rear dividing region in which the first inner wall extends beyond the pair of first contact surfaces in the Z direction away from the XY plane.
[071] Similarly, at the rear, the second inner wall will comprise a pair of second essentially planar rear contact surfaces, which are symmetrical over and turn away from the plane covered by the Z and Y axes, in order to form a gamma angle with the plane covered by the X and Y axes that is less than 35 degrees, the pair of second rear contact surfaces being separated by a second rear dividing region where the second inner wall extends beyond the pair of second contact surfaces in the Z direction away from the XY plane.
[072] The aspects mentioned above applied to the back of the cavity allow a proposed tooth, with several advantages over the previous technique, as outlined above.
[073] In general, the respective angles of inclination of the first and second rear contact surfaces must be selected, in order to achieve the desired clamping effect, while still allowing the distribution of the vertical forces to which the tooth is subjected during the use. In addition, the shape of the wear curve, as explained above, can be considered when selecting the angles.
[074] For this purpose, the beta angle can be 10 to 20 degrees, preferably 12 to 17 degrees, more preferably about 15 degrees.
[075] Similarly, the gamma angle can be 10 to 20 degrees, preferably 12 to 17 degrees, more preferably about 15 degrees.
[076] In particular for applications where the first outer surface of the tooth will be subjected to more load and more wear than the second outer surface, the gamma angle of the second inner wall may be less than the beta angle of the first inner wall, advantageously range ranges from 5 to 15 degrees and beta ranges from 10 to 20 degrees.
[077] According to the embodiments, the pairs of first and / or second rear contact surfaces extend substantially from the opposite side walls and, preferably, substantially in the path of the respective rear dividing region.
[078] The provision of the rear contact surfaces that extend substantially from the opposite side walls will allow the greatest possible separation from the pair of contact surfaces, and will move the load transfer between the tooth and the adapter away from the plane covered by the Z axes. and Y.
[079] The rear contact surfaces that extend substantially from the opposite side walls, to the respective rear dividing region, allow the provision of relatively large rear contact surfaces.
[080] Advantageously, the first and / or second inner wall may, at the rear, consist substantially of the corresponding rear contact surface pair and the corresponding rear dividing region.
[081] In general, sharp corners and edges should be avoided when forming the tooth cavity and the tip of the adapter, since any sharp parts of these will be a risk, giving rise to load concentrations, which can weaken the coupling .
[082] Likewise, while it is desired that the pair of essentially planar rear contact surfaces should extend substantially from opposite side walls, it is understood that a slightly curved corner region between each side wall and rear contact surface can be provided .
[083] According to the realizations, the rear part, comprising the first and second rear contact surfaces, can extend from the plane covered by the Z and X axes and a distance along the Y axis towards the open end of the tooth corresponding to at least the largest radius r of the opposing holes, preferably at least 2r.
[084] Likewise, the rear contact surfaces are at least partially located behind the hollow holes in the tooth. This provides an advantageous load distribution on the coupling, decreasing the tension and / or force in the hollow orifice area.
[085] According to the realizations, the rear part, comprising the first and second rear contact surfaces, can also extend in front of the plane covered by the Z and X axes, and preferably by a distance along the Y axis in the direction to the lower end of the cavity corresponding to at least the largest radius r of the opposite hollow holes.
[086] With this, the rear part can advantageously extend towards the front of the plane covered by the Z and X axes, at least through the entire hollow hole. This arrangement can contribute to an advantageous load distribution in the hollow orifice area.
[087] According to the achievements, along the rear, each of the pair of the first and / or second rear contact surfaces can extend at least a distance along the X axis of 0.2 x WI, where WI is an extension of the first or second inner wall along the X axis, as seen in a cross section parallel to the plane covered by the X and Z axes.
[088] According to the realizations, and in particular for more load applications where large vertical loads are likely to appear on the first external working surface of the tooth, and therefore be transmitted to the second rear contact surfaces, it is it is appropriate that, along most of the rear, the extension along the X axis of the first rear contact surfaces is less than the extension along the X axis of the second opposite rear contact surfaces.
[089] With the expression “a greater extent” we must understand here at least 50%, preferably at least 70%, more preferred at least 80%.
[090] When referring to the greater extent of any of the rear part, the staggered part, or the front part, unless stated otherwise, refers to the greater part of an extension of the back, staggered part, or front part, along the Y axis.
[091] This provides relatively broad rear second contact surfaces, which are used to balance the vertical load applied to the first outer surface adjacent to the tip of the tooth.
[092] Also, the first relatively narrow rear contact surfaces allow the provision of a relatively large first rear dividing region. With this, the tip part of the adapter can be provided with a relatively broad rear first dividing region, adding material to the adapter and acting as a bar that enhances the power of the tip part on its first side.
[093] The first and second rear contact surfaces are each separated by a first and second rear dividing regions, respectively.
[094] Advantageously, the first and / or second rear dividing region may comprise a pair of rear dividing lateral surfaces, which are symmetrical over and face towards the plane covered by the Z and Y axes.
[095] Advantageously, the first and / or second pair of rear dividing surfaces extends substantially from the first and / or second rear contact surfaces, respectively.
[096] As explained earlier, sharp corners and edges should be avoided, which is why the dividing side surfaces can be joined to the rear contact surfaces by means of smoothly curved joint regions.
[097] The extent of the first and / or second rear dividing region in the Z direction distant from the XY plane can therefore be determined by an extension of the respective pair of rear dividing lateral surfaces in said direction.
[098] According to the embodiments, the first and / or second rear dividing region and, accordingly, the corresponding rear dividing lateral surfaces may form part of a larger continuous structure formed by the inner wall, like a ridge. This larger continuous structure can extend through one or more of the rear, the staggered part, and the front part.
[099] According to the realizations, due to a greater extension of the rear part of the cavity, the extension of the first rear dividing region in the Z direction distant from the XY plane is greater than the extension of the second rear dividing region in the Z direction distant from the XY plane .
[0100] According to the realizations, an extension of the first and / or second rear dividing region in the Z direction away from the XY plane has a maximum adjacent to the open end of the cavity and decreases, as seen along the Y axis towards the lower end of the cavity.
[0101] With an extension of the dividing region in the Z direction decreasing towards the lower end of the cavity, it is possible to project a tooth having an outer surface that narrows towards its tip, as is desired to ensure sufficient penetration of the tooth, when in use. In addition, it will be understood that the advantages with the dividing region that separates the first and second rear contact surfaces are more pronounced at the rear of the tooth cavity.
[0102] The dividing side surfaces of the cavity are generally not intended to be in contact with the tip portion of the adapter. Likewise, some variation in the shape of the dividing side surfaces can be tolerated, as long as the tooth fits on the tip part of the intended adapter.
[0103] However, in general, it is desired that the dividing side surfaces form curved or slightly curved parts, again, avoiding sharp edges or corners.
[0104] According to the embodiments, for the first and / or the second rear dividing region, each of the pair of dividing lateral surfaces may comprise a more staggered region, in which a tangent to the lateral surface in an XZ plane forms an angle more than 45 degrees with the X axis, followed by a flatter region, where a tangent to the side surface in an XZ plane forms an angle of less than 45 degrees with the X axis.
[0105] With this, the most staggered region of each of the pair of dividing side surfaces may have a greater extension along the Z axis than along the X axis. Since this surface is not intended to hold any vertical loads applied substantially parallel to the Z axis, this configuration is adequate.
[0106] However, to provide sufficient strength, while avoiding load concentrations on the tooth and / or adapter, according to the realizations, for the first and / or second rear dividing region, over a greater length extension along the X axis of the most staggered region, a tangent to the dividing lateral surface in the XZ plane forms an angle of more than 45 degrees and less than 80 degrees with the X axis towards the Z axis, preferably less than 70 degrees.
[0107] According to the realizations, for the first and / or second rear dividing region, along a greater length extension along the X axis of the flatter region, a tangent to the dividing lateral surface in the XZ plane can form a angle less than 5 degrees with the X axis towards the Z axis.
[0108] With this, the flatter region can, at least along a part of it, be essentially parallel to the X axis.
[0109] At the front, the first and second internal walls, each, comprise a pair of first or second front contact surfaces essentially planar, symmetrical sense on the plane covered by the Z and Y axes.
[0110] According to the realizations, the pair of first and / or second front contact surfaces can comprise two front contact surfaces that are located on the same plane, parallel to the plane covered by the X and Y axes. In this case, the definition of the two surfaces that form a “pair” is simply made by referring to the surface that extends on one side of the ZY plane as one of the surfaces of the pair, and the surface extending on the other side of the ZY plane than the other surface in the pair .
[0111] However, it is preferred that the pair of first and / or second front contact surfaces comprise two front contact surfaces that are symmetrical about, and which face away from the plane covered by the Z and Y axes.
[0112] According to the realizations, on the front, the first and / or second inner wall may comprise a pair of first and / or second essentially planar front contact surfaces, being symmetrical on and facing away from the plane covered by the Z and Y axes, in order to form a respective delta, epsilon angle with the plane covered by the X and Y axes that is less than 35 degrees.
[0113] According to the embodiments, the delta angle and / or the epsilon angle is less than 25 degrees, preferably 10 to 20 degrees, preferably 12 to 17 degrees, more preferred about 15 degrees.
[0114] The aspects mentioned above applied to the front will provide essentially the same advantages as when the aspects are applied to the rear of the cavity.
[0115] Preferably, the delta angle is substantially equal to the beta angle, and the epsilon angle is substantially equal to the gamma angle. As a result, the first front and rear contact surfaces will extend in parallel with each other, and the second front and rear contact surfaces will extend in parallel with each other.
[0116] According to the embodiments, the first and / or second corresponding front and rear contact surfaces can be arranged in parallel planes, the planes being in a transformed relationship, so that the first and / or second frontal contact surfaces are located closer to the plane covered by the Y and Z axes, than the corresponding rear contact surfaces.
[0117] As mentioned above, in particular for loader applications, the second front and rear contact surfaces can be arranged not only in parallel planes, but in the same planes.
[0118] According to the realizations, in the front part, there is at least one divided part, in which the pair of first and / or the pair of second front contact surfaces can be separated by a first and / or second frontal dividing region , respectively, in which the first and / or second inner wall extends beyond the pair of first / second frontal contact surfaces in the Z direction away from the XY plane.
[0119] It will be understood that a separation of the contact surfaces by a dividing region in the front parts of the cavity will provide essentially the same advantages as in the rear parts of the cavity. However, due to the distribution of force, the advantages of providing a dividing region at the front of the cavity are not as pronounced as at the back. Furthermore, since the need for penetration of the tooth requires that its external shape narrows towards its tip, the provision of a dividing region must therefore be balanced with the available environment.
[0120] Likewise, although the pair of front contact surfaces can be separated by a dividing region, this is not necessary to achieve some of the advantages mentioned earlier here.
[0121] The frontal dividing region may comprise one or more of the aspects mentioned above concerning the rear dividing region.
[0122] In an alternative or additional way to the one mentioned above, at the front, according to the realizations, there is at least one connected part in which the pair of first and / or pair of second front contact surfaces can be connected by a first / second frontal connection region, where the first and / or second inner wall extends in the Z direction along or towards the XY plane.
[0123] With this, the connecting region is directed along or towards the XY plane, which, unlike the dividing region, is directed away from the XY plane. The connecting region, however, should not have an extension along the Z axis being comparable to that of the dividing regions. Alternatively, the connection region should form a light curved connection between the pair of front contact surfaces.
[0124] According to the embodiments, the connected part comprising the first and / or second frontal contact surfaces and the corresponding connection region between them can form part of a larger continuous structure. This structure can be a continuous shoulder also comprising the first and / or second rear contact surfaces, and extending so as to partially surround a continuous ridge, as described above.
[0125] Advantageously, any connected part of that of the front part must be located closer to the lower end of the cavity than a divided part of the front part.
[0126] According to the realizations, at the front, the pair of second and / or first front contact surfaces can be joined by a connection region, at least in a connected part located towards the lower end of the cavity. Most preferred, both pairs of second and first front contact surfaces can be joined by a connection region on that connected part. In this case, a more frontal part of the front part of the cavity, towards the lower end, can form a shape of approximately four sides, comprising the opposite side walls, the pair of first contact surfaces with its connected region, and the pair of second contact surfaces with their connected region.
[0127] However, an extension along the Y axis of the connected part of the first wall need not be similar to the length of the connected part of the second side wall.
[0128] The staggered part of the cavity extends between the rear and the front part of the cavity. By definition, the rear part of the cavity is a part along the length of the Y axis within which both of the first and second inner walls exhibit a pair of first or second rear contact surfaces, respectively, separated by a region divider and as described above. The front part of the cavity is a part along the length of the Y axis within which both of the first and second inner walls exhibit a pair of first or second front contact surfaces.
[0129] The staggered part of the cavity interconnects the rear and the front. One or more of the essentially planar contact surfaces can optionally extend from the rear or front to the stepped part of the cavity. (For example, if the second rear surfaces are to extend more in one direction along the Y axis than the first rear surfaces, the rear is defined so that they end at the end of the first rear surfaces. With this, the second surfaces rear end would extend to the staggered part.)
[0130] The staggered part must interconnect at least the first and / or second rear contact surfaces and the corresponding first and / or second front contact surfaces that are located in different planes. For this purpose, the stepped part comprises an inclination.
[0131] The term “slope” is used in a general way. The slope can comprise one or more surfaces, surface structures or surface regions.
[0132] According to the realizations, in the staggered part, the first and / or second inner wall merges with the first and / or second rear contact surfaces, the first and / or second rear dividing region, and with the first and / or second or second front contact surfaces, forming said slope (s) at least between the first and / or second rear contact surfaces and the first and / or second front contact surfaces.
[0133] According to the achievements, the slope is curved, preferably forming an S shape.
[0134] With the shape of an S, it should be understood, not that the curve follows the complete outline of an S, but that it includes a flatter part, sloping towards the plane covered by the X and Y axes to a lesser degree, followed by by a more staggered part, in which a greater inclination towards the plane covered by the X and Y axes occurs, followed by another more flat part. This shape can be seen as slightly similar to the middle section of the letter S.
[0135] According to the realizations, the staggered part may, on the first and / or second inner wall, form a pair of first or second inclined surfaces, which extend between and merge with the corresponding rear contact surfaces and the surfaces of corresponding front contacts.
[0136] Advantageously, the pair of first inclination surfaces can be symmetrical about, and at least partially turning away from the plane covered by the Z and Y axes, in order to merge with the corresponding front and rear contact surfaces.
[0137] According to the realizations, the staggered part can form an intermediate dividing region, extending between the first inclination surfaces and, in addition, extending between and merging with the first rear dividing region and the first region front divider or the first front connected region.
[0138] Although the intermediate dividing region can advantageously have an inclined or staggered shape, in order to follow a general contour that narrows the tooth, this is not necessary. The front contact surfaces must be closer to the plane covered by the X and Y axes than the rear contact surfaces, which means that the surfaces of the staggered part that interconnect these contact surfaces must be inclined - that is, the first surfaces of inclination mentioned above. However, since the purpose of the dividing region in the stepped part of the tooth is to make room for a dividing region that protrudes corresponding to the adapter, which in turn provides resistance to the adapter, the dividing region could be arranged having other shapes in the staggered region. Likewise, the dividing region in the stepped part of the cavity is referred to as an “intermediate” dividing region rather than an “inclined” dividing region - since there is, in fact, no requirement for that particular region to be inclined .
[0139] The first rear dividing region, the intermediate dividing region, and any first frontal dividing region can thus form a continuous dividing region, the maximum extent in the Z direction distant from the XY plane is decreasing from a maximum adjacent to the open end. of the cavity along the Y axis towards the lower end of the cavity.
[0140] This continuous dividing region can form a ridge, which extends from the open end of the cavity towards its lower end. The ridge can be partially surrounded by a shoulder, as described above.
[0141] As discussed above, the dividing regions (rear, front and / or intermediate) contribute to several advantages with the wear connection. The separation of the contact surfaces contributes to a more uniform force distribution in the wall surrounding the tooth cavity. Likewise, less material is needed to form a sufficiently strong tooth, and a tooth having a relatively thin wall of material that surrounds the cavity can be formed.
[0142] When considering the dividing region (s) of the tip part of the adapter, the opposite will be true. In the divider region (s) of the adapter, more material is added, contributing to the power of the adapter. Likewise, the arrangement with the contact surfaces and the dividing region contributes to an advantageous volume distribution between the tooth cavity walls and the adapter part of the total volume available for the connection between tooth and adapter.
[0143] The dividing regions can advantageously form a continuous dividing region, being formed in order to follow the general narrowing space of the tooth. Likewise, the continuous dividing region can form a structure, for example, a ridge. Preferably, the height of the continuous dividing region (direction Z) can decrease towards the lower end of the cavity.
[0144] According to the realizations, a first and / or second continuous dividing region (formed by the rear, intermediate and / or frontal dividing regions) can extend across the rear of the cavity, and at least at a distance r in front of the plane covered by the X and Z axes, where r is the radius of the hollow hole, preferably at least 1.5 r.
[0145] With this, the continuous dividing region will extend through the hollow hole of the tooth (or the adapter part) and, for the adapter part, it will contribute to the strength of the adapter in the region of the hollow hole.
[0146] Advantageously, the height (z-direction) of the continuous dividing region can decrease smoothly towards the lower end, preferably following a radius R.
[0147] The continuous dividing region may decrease in height along the Z axis, and width along the X axis, in a direction along the Y axis towards the lower end. Advantageously, it can be the most staggered regions of the dividing lateral surfaces that decrease in height and width (Z and X). The flatter region of the dividing lateral surfaces can then remain essentially constant, interconnecting the most staggered regions, until eventually merging with the frontal contact surface.
[0148] Advantageously, parts of or, preferably, the entire continuous dividing region may comprise one or more of the aspects, as described in connection with the rear dividing region.
[0149] According to the achievements of a tooth, as proposed here, for the first and / or second rear dividing region, a pair of first and / or second secondary rear contact surfaces, essentially planar, extends from the dividing lateral surfaces towards the YZ plane, the first and / or second secondary rear contact surfaces being symmetrical over and turning in opposition to the plane covered by the Z and Y axes, so as to form an angle (eta, theta) with the covered plane by the X and Y axes which is less than 35 degrees.
[0150] Advantageously, the first and / or second secondary rear contact surfaces, essentially planar, are substantially parallel to the respective first and / or second rear contact surfaces.
[0151] In an initial state, when the tooth and the tip part of the adapter are interconnected, the rear dividing regions of the tooth and the tip part must not be in contact with each other. Likewise, the height of the rear dividing regions of the tooth cavity is slightly greater, and the width of the rear dividing regions of the tooth cavity is slightly wider than the height and width of the corresponding rear dividing regions of the tip part. On the contrary, contact between the tooth and the tip part is guaranteed by means of first / second front and rear contact surfaces.
[0152] However, during use, and under certain loading conditions, the adapter tooth and / or tip may become subject to internal deformation, affecting the contact surfaces. In this case, a situation may arise in which the secondary contact surfaces of the rear dividing regions of the tooth and the tip of the adapter come into contact with each other. Likewise, secondary contact surfaces can be effective in taking control of the distribution of some of the loads to which the tooth and adapter are affected.
[0153] According to the realizations, secondary contact surfaces, as described above, can also be applied to the frontal dividing region (s) and / or the dividing region (s) intermediate (s).
[0154] According to the embodiments, continuous secondary contact surfaces can be formed, extending over a continuous dividing region, for example, through the rear, the staggered part, and / or the front part of the cavity.
[0155] As discussed above, the first and second internal walls of the cavity will be effective in transferring vertical loads applied to the tip of the tooth, when in action. However, the tip of the tooth can also be subjected to horizontal loads.
[0156] These horizontal loads will generally be transferred to the adapter part via the opposite side surfaces of the cavity, and the opposite side surfaces of the adapter. Again, as for the first / second inner walls, the side surfaces will work in pairs. Each functional pair will include a front side surface that extends from the front of the cavity, and a rear side surface that extends from the rear of the cavity, said side, front and rear surfaces being located on opposite sides of the plane covered by the Z axes. and Y.
[0157] For this purpose, at least at the rear of the cavity, the opposite side surfaces advantageously comprise the rear, essentially planar, opposite side contact surfaces.
[0158] Furthermore, at the front of the cavity, the opposite side surfaces can advantageously comprise opposite, frontal, essentially planar, opposite contact surfaces.
[0159] Preferably, the side, rear contact surfaces and the side, front contact surfaces are located in different planes. Likewise, the opposite side walls are adapted to provide a thinner shape of the cavity towards its lower end.
[0160] Advantageously, all the front, lateral contact surfaces are located closer to the plane covered by the Z and Y axes than all the rear, lateral contact surfaces.
[0161] Advantageously, the opposite, frontal, opposite contact surfaces can extend substantially from the lower end of the cavity.
[0162] According to the realizations, the opposite side, rear, contact surfaces extend at least from the plane covered by the X and Z axes, in a direction towards the open end of the cavity along the Y axis, by a distance r , preferably 2r, where r is the maximum radius of the hollow holes.
[0163] Likewise, the tooth and the adapter part can be kept relatively large in the area around the hollow holes, so that sufficient material and thus sufficient strength of the components can be achieved regardless of the presence of said holes .
[0164] According to the realizations, the opposite side, rear, contact surfaces can extend at least from the plane covered by the X and Z axes, in a direction towards the lower end of the cavity along the Y axis, at least by a distance r, where r is the maximum radius of the hollow holes.
[0165] Advantageously, the opposing side surfaces can define lateral, inclined, opposing surfaces that interconnect the lateral, rear contact surfaces and the lateral, frontal contact surfaces.
[0166] The inclined side surfaces will thus be tilted in a direction towards the plane covered by the Z and Y axes.
[0167] For this purpose, the inclined side surfaces may comprise curved surfaces.
[0168] According to the realizations, the pair of lateral, front contact surfaces and the pair of lateral, rear contact surfaces can preferably form an angle with the YZ plane that is less than 5 degrees, preferably less than 2 degrees .
[0169] This is due, similar to the situation with the first and second front and rear contact surfaces, when considering the load distribution, it is preferred that the side, front contact surfaces and the side, rear contact surfaces are parallel to the plane covered by the Z and Y axes. However, to allow the assembly of the tooth and the adapter part, a slight deviation from this must be allowed.
[0170] According to the realizations, the lateral, rear contact surfaces can extend for a distance in the direction of the Z axis corresponding to at least 3 r, where r is the maximum radius of the hollow holes.
[0171] Advantageously, the lateral, rear contact surfaces also extend in front of the plane covered by the X and Z axes, at least by a distance r, in order to extend throughout the hollow hole. Preferably, the rear, side contact surfaces can extend for a distance of at least 1.5 r in front of the X and Z axes.
[0172] By definition, all rear contact surfaces (lateral, first or second) must have an extension at the rear of the cavity. However, the rear contact surfaces do not need to be confined to the rear of the cavity, but they can continue their extension beyond the plane covered by the X and Z axes. In this case, the rear contact surface will have a part of the area that extends behind the plane covered by the X and Z axes, and a part of the area that extends in front of the plane covered by the X and Z axes.
[0173] The respective extensions of the rear contact surfaces (lateral, first or second) need not be the same. The first and second rear contact surfaces must extend across the rear (by definition). However, this is not necessary for the side, rear surfaces, although it is advantageous that the side, rear surfaces also extend across the rear.
[0174] Having discussed the vertical forces and transverse forces that can affect the tip of the tooth, when in operational condition, longitudinal forces will now be mentioned briefly. Longitudinal forces can act on the tip of the tooth and, in general, along a direction of its length. These forces are mainly assumed by a contact surface in the form of an inner lower wall of the cavity.
[0175] The lower internal wall of the cavity, therefore, when in use, will come in contact with the free end of the adapter, and forces can be transmitted between its surfaces.
[0176] An alternative way to describe a desired geometry for the cavity is to consider the contour of the cavity along the rear. Likewise, a tooth having a cavity defined as described above, in which, at the rear, the first and / or second inner walls exhibit a contour formed by points x, z, the contour being symmetrical on the Z axis and having a maximum WI width along the X axis.
[0177] The contour can be defined by the following:
[0178] In peripheral parts in abs (x) greater than or equal to 0.9 x WI / 2, a first maximum abs (z) is defined in a pair of points (x1, z1).
[0179] (In a pair of points (x, z), as mentioned here, x will be negative in one of the points in the pair, and positive in one of the points in the pair. The value of x is the same in both points of the pair. pair Z will be positive or negative at both points in the pair, and the value of z is the same at both points in the pair).
[0180] For abs (x) less than abs (x1): abs (z) is decreasing until a minimum abs (z) is defined in a pair of points (x2, z2), and for abs (x) less than abs (x2): abs (z) is increasing until a maximum abs (z) is defined at a pair of points (x3, z3), where abs (z3)> abs (z1)> abs (z2).
[0181] The points (x1, z1); (x2, z2), and (x3, z3) of the first wall need not be similar to those of the second wall. On the contrary, the appearance of the contour of the first inner wall and the contour of the second wall can vary and be adapted to different applications.
[0182] By "abs (coordinate)" we must understand the absolute value of the coordinate.
[0183] It should be noted that if x = 0, which may be the case with (x3, z3), the two points in the pair will coincide.
[0184] The description mentioned above explains the contour that allows inclined surfaces to provide a locking effect, as well as the favorable appearance of the contour when subjected to wear.
[0185] Advantageously, abs (z3) -abs (z1)> 0.03 x WI. This establishes a relationship between the width of the first or second wall, and the height of the rear dividing region, which is advantageous in terms of the distribution of strength and resistance.
[0186] Advantageously, abs (z3) -abs (z1) <0.6 x WI.
[0187] According to the achievements, at least one among (x1, z1); (x2, z2) and (x3, z3) can be different from the first inner wall and the second inner wall.
[0188] It will be understood that with the above description, between the pairs of (x1, z1) and (x2, z2), the contour generally follows a straight line z = k x abs (x) + K, where k and K are constants. The straight line corresponds to the pairs of essentially planar rear contact surfaces, which will thus extend between the pairs of points (x1, z1) and (x2, z2); with the first and second rear dividing regions extending between the points (x2, z2) (x2 negative) and (x2, z2) (x2 positive), including the maximum points (x3, z3).
[0189] The constant k = tan (beta) (or k = tan (gamma)), where beta, gamma can be as described above.
[0190] The minimum abs (z) points (in (x2, z2)) will be defined at the junctions between the essentially planar rear contact surfaces and the rear dividing region.
[0191] In fact, one could consider the contour of the first and second internal walls of the cavity as deviations from opposite imaginary planes that incorporate minimal z points.
[0192] Therefore, along the rear, the minimum z of the contours of the first and second internal walls, respectively, are located in rear, minimal, imaginary, opposite z planes; and along the front, the minimum z of the contours of the first and second inner walls, respectively, are located in two opposite, minimal, imaginary, frontal z planes.
[0193] The minimum front and rear z planes, all forming the same alpha angle that is less than 5 degrees with the Y axis.
[0194] In the first and / or second inner wall, the minimum front plane z is located closer to the XY plane than the minimum rear plane z and, in the staggered part of the cavity, said first / second inner wall interconnects the front plane z minimum with the rear plane z minimum.
[0195] In fact, it is believed that the aforementioned contour and the suggested relationships between the points on the contour, it can also be advantageous that a tooth and a corresponding adapter, which do not have the other aspects mentioned above referring to the front and the staggered part of the device. Several of the advantages mentioned above, for example, allowing the use of smaller amounts of material and favorable behavior during wear and tear, could be achieved with other designs of the cavity than described above and in the realizations.
[0196] With this, the objectives mentioned above can be achieved, alternatively, by
[0197] a tooth for attaching to the edge of a bucket of an operational machine, such as an excavator or loader, by means of an adapter, the tooth having an outer surface comprising two external functional surfaces, externally opposite, namely, a first functional surface (and a second functional surface, functional surfaces having a width (W) in a horizontal direction (H), intended to extend along said edge of a bucket, and having a length (L) extending between an attachment end and a tip of said tooth, the functional surfaces extending along said length (L), while converging in a vertical direction (V) to be connected at said tip of the tooth, the tooth still comprising a cavity for receiving a part of said adapter, the cavity extending between said first and second opposing external functional surfaces of an open end, at said tooth attachment end, to a lower end; the cavity being delimited by an internal wall; said internal wall comprising first and second internal walls facing internally, which are the internal surfaces associated with said first external functional surface and said second external functional surface, respectively, and opposite side walls, which interconnect said first and second internal walls, the opposite side walls delimiting opposite hollow holes to receive a pin that extends through the cavity for affixing the tooth to the adapter part, a first X axis being defined, extending through the centers of the opposite hollow holes, a second Y axis extending along of the cavity of the open end of the cavity towards the lower end of the cavity, and a third Z axis being orthogonal to said first and second axes X, Y, the three axes X, Y, Z, thereby forming a system of orthogonal axes , which are in an origin, with this, each point of the inner wall can be defined by Cartesian coordinates (x, y, z), the cavity defining a rear part that extends along the Y axis, the rear part being at least partially located between the plane covered by the X and Z axes and the open end of the cavity; and
[0198] in which, at the rear, for each point y along the x axis, the first rear wall and the second rear wall, each, exhibit a contour formed by the points (x, z), the contour being symmetrical over the Z axis and having a maximum width WI along the X axis,
[0199] the contour being defined by the following: in the peripheral parts in abs (x) greater than or equal to 0.9 x WI / 2, a first maximum abs (z) is defined in a pair of points (x1, z1),
[0200] for abs (x) less than abs (x1), abs (z) is decreasing until a minimum abs (z) is defined in a pair of points (x2, z2),
[0201] and for abs (x) less than abs (x2), z is increasing until a maximum abs (z) is defined in a pair of points (x3, z3), where abs (z3)> abs (z1) > abs (z2), and abs (z3) - abs (z1)> 0.03 x WI, preferably abs (z3) -abs (z1) <0.6 x WI.
[0202] Advantageously, abs (z3) -abs (z1)> 0.1 x WI. Preferably, abs (z3) -abs (z1) <0.3 x WI.
[0203] The second variation of a tooth, as described above, can be combined with any of the aspects mentioned in relation to the first variation of a tooth above.
[0204] In a tooth, as described here, a first stepped distance (D1) along the Z axis is bridged by the first inner wall along the stepped part, between the first rear contact surfaces and the first contact surfaces frontal; and a second stepped distance (D2) along the Z axis is bridged by the second inner wall along the stepped part, between the second rear contact surfaces and the second front contact surfaces; where 0 <= D2 <= 0.80 D1.
[0205] In the staggered part, at least one between the first and the second internal walls, each one, will form a slope between the respective front surface and the respective rear surface. The staggered part will thus bridge the distance along the Z axis between the front surfaces and the corresponding rear surfaces.
[0206] The "staggered distance" must be measured over the entire staggered part, that is, from the rear surfaces at the junction between the rear and the staggered part, to the front surfaces at the junction between the staggered part and the front part.
[0207] If the front and rear contact surfaces do not extend in parallel, the distance, as measured along the Z axis, could have different values in different planes parallel to the plane covered by the Z and Y axes. In this case, the distance The minimum distance along the Z axis must be the “stepped distance”.
[0208] The relationship between the first stepped distance D1 and the second stepped distance D2 will be relevant to the degree of symmetry of the cavity.
[0209] If the first stepped distance is different from the second stepped distance, the first and second front and rear contact surfaces are arranged asymmetrically. Such achievements could be particularly advantageous for certain applications, such as loader applications.
[0210] These asymmetric arrangements can be defined by 0 <= D2 <= 0.80 D1.
[0211] According to the achievements, 0 <= D2 <= 0.50 D1.
[0212] According to the achievements, D2 can be approximately zero. In this case, the second pairs of front and rear contact surfaces are located on the same planes. Thus, the staggered region can comprise a slope only on its first inner wall. Such an embodiment may be particularly suitable for a loading machine application.
[0213] It will be understood that the above description of aspects and advantages made in relation to a tooth is also applicable to the adapter to which the tooth is to be connected. In general, all aspects described in relation to the tooth have a corresponding counterpart in the adapter.
[0214] In view of the aforementioned, the purpose of the invention is achieved by an adapter for attaching a tooth to the edge of a bucket of an operational machine, such as an excavator or loader, the adapter comprising a connector part for disposal or in a bucket, and a tip part for disposal in a corresponding cavity of a tooth, the tip part having a width in a horizontal direction (H), intended to extend along the edge of the bucket, and having a length extending in a longitudinal direction (L) from a connecting end adjacent to the connecting part of the adapter, to a free end, and having an outer wall, the outer wall comprising a first outer wall and a second outer wall, externally opposite, and externally opposite side walls, interconnecting said first and second external walls, the tip part delimiting a hollow hole, which extends between said side walls opposite, to receive a pin that extends through the tip part for affixing the tooth to the adapter, a first X axis being defined, which extends through the center of the hollow hole, a second Y axis extending along the tip part of the connecting end of the tip part towards the free end of the tip part, and a third Z axis being orthogonal to said first and second axes X, Y, the three axes X, Y, Z, thereby forming a system of axes orthogonal, that are in an origin, with that, each point of the external wall can be defined by Cartesian coordinates (x, y, z), in which the tip part that defines a rear part that extends along the axis Y, the rear part being at least partially located between the plane covered by the X and Z axes and the connecting end of the tip part, a front part extending along the Y axis, the front part being located between the plane covered by the X and Z axes and the li end vre of the tip part; and a staggered part, which interconnects the rear and the front; at the rear, the first and second outer walls, each, comprise a pair of essentially planar rear contact surfaces, each pair of rear contact surfaces being symmetrical over and facing towards the plane covered by the Z and Y axes, from so as to form an angle (beta, gamma) with the plane covered by the X and Y axes that is less than 35 degrees, each pair of rear contact surfaces being separated by a rear dividing region, extending beyond the pair of first surfaces contact in the Z direction away from the XY plane; at the front, the first and second outer walls each comprise a pair of essentially planar front contact surfaces, being symmetrical over the plane covered by the Z and Y axes, all contact surfaces forming an angle (alpha) less than 5 degrees with the Y axis, as seen in any plane parallel to the plane covered by the Z and Y axes, the first and / or second front contact surfaces being located closer to the plane covered by the X and Y axes than the corresponding rear contact surfaces , and the first and / or second outer wall of the staggered part forming a slope in which at least a part of the outer wall approaches the XY plane towards the lower wall, interconnecting said first and / or second rear contact surfaces and the first and / or second corresponding front contact surface.
[0215] A first stepped distance (D1) along the Z axis is bridged by the first outer wall along the stepped part, between the first rear contact surfaces and the first front contact surfaces; and a second stepped distance (D2) along the Z axis is bridged by the second outer wall along the stepped part (SP), between the second rear contact surfaces and the second front contact surfaces; where 0 <= D2 <= 0.80 D1.
[0216] The connector part can form a part for attaching the adapter to a bucket. However, the term connector part must also encompass the part of an adapter that is cast as an integral part of a bucket that is directed to the rest of the bucket.
[0217] According to the embodiments, the angle (beta, gamma) is less than 25 degrees, preferably 10 to 20 degrees, preferably 12 to 17 degrees, more preferred about 15 degrees.
[0218] According to the realizations, the gamma angle of the second outer wall is smaller than the beta angle of the first outer wall, preferably the gamma varies from 5 to 15 degrees and beta varies from 10 to 20 degrees.
[0219] According to the embodiments, the pairs of first and / or second rear contact surfaces extend substantially from the opposite side walls, and, preferably, substantially to the respective rear dividing region.
[0220] According to the realizations, the rear part, comprising the first and second rear contact surfaces that extend at least from the plane covered by the Z and X axes, and for a distance along the Y axis, in a direction to the connecting end, corresponding to at least the largest radius (r) of the opposite hollow hole, preferably at least 2r.
[0221] According to the realizations, the rear part, comprising the first and second rear contact surfaces that also extend in front of the plane covered by the Z and X axes and preferably by a distance along the Y axis, in one direction towards the free end, corresponding at least to the largest radius (r) of the hollow hole.
[0222] According to the achievements, each of the pair of first and / or second rear contact surfaces extends at least a distance along the X axis of 0.2 x WI, where WI is an extension of the first / second outer wall along the X axis.
[0223] According to the realizations, throughout a greater extent of the rear part, the extension along the X axis of the first rear contact surfaces is less than the extension along the X axis of the second opposite rear contact surfaces.
[0224] According to the realizations, the first and / or second rear dividing region comprises a pair of lateral dividing surfaces, being symmetrical over and turning in opposition to the ZY plane.
[0225] According to the embodiments, the pair of dividing side surfaces of the first and / or second rear dividing region extends substantially from the first and / or second rear contact surfaces, respectively.
[0226] According to the realizations, the extent of the first and / or second rear dividing region in the Z direction distant from the XY plane is determined by the extension of the corresponding dividing lateral surface pair in said direction.
[0227] According to the realizations, due to a greater extension of the rear part of the tip, the extension of the first rear dividing region in the Z direction far from the XY plane is greater than the extension of the second rear dividing region in the Z direction far from the XY plane.
[0228] According to the realizations, the extension of the first and / or second rear dividing region in the Z direction far from the XY plane has a maximum adjacent to the connecting end of the tip part and decreases along the Y axis towards the end free of the tip part.
[0229] According to the realizations, for the first and / or second rear dividing region, each of the pair of dividing lateral surfaces comprises a more staggered region, in which a tangent to the lateral surface in the XZ plane forms an angle of more than 45 degrees with the X axis, followed by a flatter region, where a tangent to the lateral surface in the XZ plane forms an angle less than 45 degrees with the X axis.
[0230] According to the realizations, the said most staggered region of each of the pair of dividing lateral surfaces has a greater extension along the Z axis than along the X axis.
[0231] According to the realizations, for the first and / or second rear dividing region, along a greater length extension along the X axis of the most staggered region, a tangent to the lateral surface in the XZ plane forms an angle of more than 45 degrees and less than 80 degrees with the X axis towards the Z axis.
[0232] According to the realizations, for the first and / or second rear dividing region, along a greater length extension along the X axis of the flatter region, a tangent to the dividing lateral surface in the XZ plane forms an angle less than 5 degrees with the X axis towards the Z axis.
[0233] According to the realizations, for the first and / or second rear dividing region, a pair of first and / or second secondary rear contact surfaces, essentially planar extends from the dividing lateral surfaces towards the YZ plane, the first / second secondary rear contact surfaces being symmetrical and turning towards the plane covered by the Z and Y axes, so as to form an angle (eta, theta) with the plane covered by the X and Y axes that is less than 35 degrees .
[0234] According to the embodiments, the first / second secondary rear contact surfaces, essentially planar, are substantially parallel to the respective first / second rear contact surfaces.
[0235] According to the realizations, the rear part extends along a part of the y axis, where, for each point y along the x axis, the first and / or second outer wall shows a contour formed by the points (x , z), the contour being symmetrical on the Z axis and having a WI width along the X axis, the contour being defined by the following: in peripheral parts in abs (x) greater than or equal to 0.9 x WI / 2, a first maximum abs (z) is defined at a pair of points (x1, z1),
[0236] for abs (x) less than abs (x1), abs (z) decreases until a minimum abs (z) is defined in (x2, z2),
[0237] and for abs (x) less than abs (x2), z increases until a maximum abs (z) is defined in (x3, z3), where abs (z3)> abs (z1)> abs (z2 ), and abs (z3) -abs (z1)> 0.03 x WI, preferably abs (z3) -abs (z1) <0.6 x WI.
[0238] Advantageously, abs (z3) -abs (z1)> 0.1 x WI. Preferably, abs (z3) -abs (z1) <0.3 x WI.
[0239] According to the achievements, at least one between (x1, abs (z1)); (x2, abs (z2)) and (x3, abs (z3)) may differ between the first outer wall and the second outer wall.
[0240] According to the realizations, on the front, the first and / or second outer wall comprises a pair of first and / or second essentially planar front contact surfaces, which are symmetrical and face towards the plane covered by the Z and Y axes, in order to form an angle (delta, epsilon) with the plane covered by the X and Y axes being less than 35 degrees.
[0241] According to the embodiments, the delta angle and / or the epsilon angle is less than 25 degrees, preferably 10 to 20 degrees, preferably 12 to 17 degrees, more preferred about 15 degrees, preferably, the delta angle is substantially equal to the beta angle, and the epsilon angle is substantially equal to the gamma angle.
[0242] According to the realizations, in the front part, there is at least one divided part in which at least one, preferably both of the pair of first and second front contact surfaces is separated by a first or second frontal dividing region, in which the first or second outer wall extends beyond the pair of first or second front contact surfaces in the Z direction away from the XY plane.
[0243] According to the realizations, at the front, there is at least one interconnected part, in which at least one, preferably both of the pairs of first or second front contact surfaces are connected by a first or second frontal connection region, where the first / second outer wall extends in the Z direction along or towards the XY plane.
[0244] According to the realizations, said connected part is located closer to the free end of the tip part than said divided part.
[0245] According to the realizations, the second outer wall in the staggered part forms a slope, approaching the plane covered by the X and Y axes while extending towards the free end, interconnecting said second rear contact surfaces and said second surfaces contact points.
[0246] According to the realizations, in the staggered part, the first and / or second outer wall merges with the first and / or second rear contact surfaces, the first and / or second rear dividing region, and with the first and / or second or second front contact surfaces, forming said slope (s) at least between the first and / or second rear contact surfaces and the first and / or second front contact surfaces.
[0247] According to the realizations, said inclination is curved, preferably forming an S shape.
[0248] According to the realizations, the first front and rear contact surfaces, which are connected by said inclination, are arranged so that, if they are interconnected by a straight line, that line would form an angle of more than 10 degrees preferably more than 20 degrees with the plane covered by the X and Y axes.
[0249] According to the realizations, in the staggered part, the first and / or second outer wall form a pair of first inclination surfaces, which are symmetrical over the plane covered by the Z and Y axes, extending between and merging them the first and / or second rear contact surfaces and the first and / or second corresponding front contact surfaces.
[0250] According to the realizations, in the staggered part, the first and / or second outer wall forms an intermediate dividing region, extending between the first or second inclined rear surfaces and, in addition, extending between and merging to the first or second rear dividing region and to the first or second front dividing region or connecting region.
[0251] According to the realizations, the first and / or second rear dividing region, and the corresponding intermediate dividing region, form a continuous dividing region, whose maximum extension in the Z direction away from the XY plane decreases from a maximum adjacent to the connecting end. from the tip part along the Y axis towards the free end of the tip part.
[0252] According to the embodiments, at least at the rear, the opposite side surfaces comprise lateral, rear, essentially planar, opposite contact surfaces, and at least at the front, the opposite side surfaces comprise lateral, front contact surfaces. , essentially planar, opposite, the lateral, rear contact surfaces and the lateral, frontal contact surfaces being located in different planes.
[0253] According to the realizations, all the lateral, front contact surfaces are located closer to the plane covered by the Z and Y axes than all the rear, lateral contact surfaces.
[0254] According to the embodiments, the opposite, frontal, lateral contact surfaces extend substantially from the free end of the tip part.
[0255] According to the realizations, the lateral, rear, opposite contact surfaces extend at least from the plane covered by the X and Z axes, in a direction towards the connector end of the tip part along the Y axis, by a distance r, preferably 2r, where r is the maximum radius of the hollow hole.
[0256] According to the embodiments, the lateral, rear, opposite contact surfaces extend at least from the plane covered by the X and Z axes, in a direction towards the free end of the tip part along the Y axis, at least for a distance r, where r is the maximum radius of the hollow hole.
[0257] According to the embodiments, the opposite side surfaces define lateral, inclined, opposite surfaces that interconnect the lateral, rear, opposite contact surfaces and the lateral, frontal contact surfaces.
[0258] According to the embodiments, the inclined side surfaces comprise curved surfaces.
[0259] According to the realizations, the pair of side, front surfaces and the pair of side, rear surfaces form an angle with the YZ plane that is less than 5 degrees, preferably less than 2 degrees.
[0260] According to the realizations, the lateral, rear contact surfaces extend for a distance in the direction of the Z axis corresponding to at least 3 r, where r is the maximum radius of the hollow holes.
[0261] According to the embodiments, the free end of the tip part comprises an outer end wall.
[0262] According to the realizations, the alpha angle is between 0.5 and 5 degrees, more preferred, between 1 and 3 degrees.
[0263] In a second variation, the objective of the invention is achieved by an adapter for attaching a tooth to the edge of a bucket of an operational machine, such as an excavator or loader, the adapter comprising a connector part for disposal to a bucket. , and a tip part for disposition in a corresponding cavity of a tooth, the tip part having a width in a horizontal direction (H), intended to extend along the edge of the bucket, and having a length that extends in a longitudinal direction (L) of a connecting end adjacent the connecting part of the adapter, to a free end, and having an outer wall, the outer wall comprising a first outer wall and a second outer wall, externally opposite, and externally opposite side walls , interconnecting said first and second outer walls, the tip part delimiting a hollow orifice that extends between said opposite side walls, to rec eber a pin that extends through the tip part for affixing the tooth to the adapter, a first X axis being defined, extending through the center of the hollow hole, a second Y axis extending along the tip part of the connector end of the tip part towards the free end of the tip part, and a third Z axis being orthogonal to said first and second axes X, Y, the three axes X, Y, Z, thereby forming a system of orthogonal axes, which are in an origin, with this, each point of the external wall (can be defined by Cartesian coordinates (x, y, z), in which the tip part defined a rear part that extends along the Y axis, the part rear end being at least partially located between the plane covered by the X and Z axes and the connecting end of the tip part, in said rear part, for each point y along the x axis, the first outer wall and the second outer wall, each, show an outline formed by the points (x, z), the contour being symmetrical on the Z axis and having a maximum WI width along the X axis, the contour being defined by the following: on the peripheral parts in abs (x) greater than or equal to 0.9 x WI / 2, a first maximum abs (z) is defined at a pair of points (x1, z1), for abs (x) less than abs (x1), abs (z) decreases until a minimum abs (z) is defined in (x2, z2), and for abs (x) less than abs (x2), abs (z) increases until a maximum abs (z) is defined in (x3, z3), where abs (z3)> abs (z1)> abs (z2), and abs (z3) -abs (z1)> 0.03 x WI, preferably abs (z3) -abs (z1) <0.6 x WI.
[0264] Advantageously, abs (z3) -abs (z1)> 0.1 x WI. Preferably, abs (z3) -abs (z1) <0.3 x WI.
[0265] The purpose of the invention is also achieved by a tooth having a cavity designed to fit an adapter, as described above.
[0266] At the end of the tooth, the open end of the cavity is bounded by the internal wall, and surrounded by an external wall of the tooth, which may be forming a border of the tooth wall.
[0267] The tip part of the adapter extends a coupling part, in which the coupling part forms a ring that surrounds the base of the tip part. The shape of the rim can advantageously correspond to the tooth wall edge of the tooth, so that when the tooth and adapter are assembled, the rim will face the said tooth wall edge, and the outer wall of the tooth and the coupling part of the adapter will form an outer surface assembled having, in general, a smooth appearance.
[0268] The rim and edge of the tooth wall can advantageously be designed to fit strictly with each other, in order to prevent debris from entering between the tip part and the inner wall of the tooth cavity.
[0269] When reference is made to the XY plane or the YX plane, it refers to the plane covered by the X and Y axes; and similar definitions apply to other planes that refer to the three orthogonal axes X, Y, Z. BRIEF DESCRIPTION OF THE DRAWINGS
[0270] The various aspects of the invention, including its particular aspects and advantages, will be readily understood from the following detailed description and the accompanying drawings, in which:
[0271] Figure 1 illustrates an embodiment of a tooth, an adapter and an attachment pin;
[0272] Figure 2a is a vertical top view of the tooth and adapter of Figure 1 when assembled;
[0273] Figure 2b is a horizontal view of the tooth and adapter of Figure 1, when assembled;
[0274] Figure 2c is a cross-sectional view of the tooth and adapter of Figure 1 when assembled;
[0275] Figures 3 and 4 are seen in perspective of the tooth in Figure 1;
[0276] Figures 5 and 5 'are seen in cross section, if the tooth of Figure 1, obtained along the Z and Y axes;
[0277] Figures 6a, 6 ', 6' 'and Figures 6b to 6d are cross sections of the tooth of Figure 1, obtained along the sections, as depicted in Figure 5' ';
[0278] Figure 7 is a cross-sectional view of the tooth in Figure 1, taken along the X and Y axes;
[0279] Figure 8 is a perspective view of the adapter in Figure 1;
[0280] Figures 9-, and 9 'are side views of the adapter of Figure 1;
[0281] Figures 10a to 10d are cross sections of the adapter of Figure 1, obtained along the sections illustrated in Figure 9 '' -;
[0282] Figures 11 and 12 are seen in perspective of a second embodiment of a tooth;
[0283] Figure 13 is a top view of the tooth in Figure 11;
[0284] Figures 14 a-c are cross sections of the tooth of Figure 11, obtained along the sections illustrated in Figure 13;
[0285] Figure 15 is a perspective view of a second embodiment of the adapter, intended for use with the tooth of Figure 11;
[0286] Figure 16 is a top view of the adapter in Figure 15;
[0287] Figures 17a to 17c are cross sections of the adapter of Figure 15, obtained along the sections depicted in Figure 16; and
[0288] Figure 18 is a cross section of the assembled tooth and adapter of Figure 2c, obtained along the X and Z axes;
[0289] Figure 19 is a perspective view of a tooth and an adapter in a three-part system; and
[0290] Figure 20 illustrates other views of the three-part system in Figure 19. DETAILED DESCRIPTION OF THE INVENTION
[0291] The present invention will now be described more fully with reference to the accompanying drawings, in which example embodiments are presented. However, this invention should not be construed as limited to the achievements set forth herein. Revealed aspects of example achievements can be combined, as readily understood by a person skilled in the art to which this invention belongs. Similar numbers refer to similar elements throughout the document. Well-known functions or restrictions will not necessarily be described in detail for brevity and / or clarity.
[0292] When several drawings illustrate the same realization, it should be understood that the reference number that indicates an aspect in a drawing can be mentioned throughout the description, even if the number is not repeated in each drawing of the realization.
[0293] Below, aspects of the tooth and adapter proposed here, as well as their functions of achieved benefits, will be described in general. For a better understanding, reference will also be made to the achievements described in the attached drawings. However, it should be understood that the aspects and / or advantages are not limited to the portrayed achievements, but can be applied to several projects, according to the technician's understanding on the subject.
[0294] The disclosure refers, in a general way, in a first aspect, to a tooth for affixing to the edge of a bucket of an operational machine by means of an adapter. The external design of this tooth can be selected for its desired purpose, such as excavation, digging, etc. In general, this tooth, however, will extend between a coupling part for coupling the tooth to the edge of a bucket, usually by means of an adapter, and a tip part for penetrating the material to be worked.
[0295] In general, the tooth will extend in a longitudinal direction from said coupling part to the tip of the tooth. In addition, the tooth will have an extension in one direction along the edge of the bucket, hereinafter referred to as a “horizontal” direction. Finally, the tooth will have an extension along a direction perpendicular to the longitudinal and horizontal direction, that is, a "thickness". This direction is referred to here as "vertical direction". In general, the thickness along said vertical direction is the largest in the coupling part of the tooth, and decreases towards the tip of the tooth.
[0296] Aligned with the aforementioned, the tooth is having an outer surface comprising two external functional surfaces, externally opposed, namely, a first functional surface and a second functional surface. The functional surfaces have a width in a horizontal direction, designed to extend along the edge of a bucket, when disposed on it. The functional surfaces have a length that extends between an end of the tooth attachment and an end of said tooth. The functional surfaces will extend like the tooth along said length, while converging in a vertical direction and the first and second opposing functional surfaces are connected at said tip of the tooth.
[0297] When in use, the functional surfaces are intended to be directed towards the front / rear of the bucket for carrying out functional operations and, therefore, can be seen as forming extensions of the internal and external surface of the bucket, respectively, said extensions protruding from the edge of the bucket.
[0298] The outer surface of the tooth can also define opposite external side walls, which essentially extend only along the vertical and longitudinal directions, and interconnecting the first and second functional surfaces.
[0299] In general, the first external functional surface may be the functional surface intended to continue on the inner side of the bucket, and the second external functional surface may be the surface intended to continue on the external side of the bucket.
[0300] The tooth comprises a cavity for receiving a part of said adapter, the cavity extending between said first and second external functional surfaces opposite an open end, at said end of affixing the tooth, to a lower end. Said cavity is designed to affix the tooth to an adapter, as will be described below.
[0301] With this, the tooth comprises a cavity for receiving a part of said adapter, the cavity extending between said first and second external functional surfaces opposite an open end, on said end of affixing the tooth, to a lower end ; the cavity being delimited by an internal wall.
[0302] The internal wall comprises first and second internal walls facing internally, which are the internal surfaces associated with said first external functional surface and said second external functional surface, respectively, and opposite side walls interconnecting said first and second internal walls.
[0303] Opposite side walls delimit opposite hollow holes to receive a pin that extends through the cavity, for attaching the tooth to the adapter.
[0304] With this, the opposite hollow holes can allow the insertion of a pin, generally, along the horizontal direction through the cavity. With this, it is expected that the pin will generally extend along the edge of the bucket. This pin will allow the tooth to be securely attached to an adapter.
[0305] In a second aspect, the disclosure refers, in general, to an adapter for attaching a tooth to the edge of a bucket of an operational machine, such as an excavator or loader. The adapter comprises a connector part for disposal in a bucket, and a tip part for disposal in a corresponding cavity of a tooth.
[0306] The connector part can have any desired shape that allows its attachment to the edge of a bucket. Conventionally, this display can be done, for example, by welding. For example, the connector part may have a fork-like appearance, defining two forked leg parts between which the bucket edge can be arranged. Adapters can be attached to the blade in different ways, such as welded, be part of the blade as a molten tip or be attached mechanically. For example, in mining, three-part systems are used, shown in figures 19 and 20, where the tip part of the adapter forms part of the bucket blade, which is the tip part of a molten tip. Therefore, it is possible that the connector part forms part of the bucket blade, this solution being known as a molten tip.
[0307] Using the directions, as defined above, the connector part, in general, will allow the disposal of the bucket edge along a "horizontal" direction.
[0308] The tip part of the adapter extends from the connector part along a longitudinal direction from a connector end (towards the connector part) to a free end. The tip part defines an external wall, which is designed so that the tip part fits into the cavity of a corresponding tooth and allows coupling between the tooth and the adapter.
[0309] To allow the tip part of the adapter to be attached to the tooth coupling part, the tip part is provided with a hollow hole that extends along a horizontal direction, corresponding to the hollow holes of the tooth. Likewise, a pin can be inserted by mounting the tooth coupling part and the tip part of the adapter.
[0310] To fix the tooth to the adapter, the tooth cavity is placed over the tip part and a fixation pin is fixed in the passage formed by the hollow holes in the tooth and the hollow hole in the adapter.
[0311] Turning now to the exemplary embodiments, the aspects mentioned above are explained with reference to a first embodiment of a tooth illustrated in Figures 3 to 7, and the corresponding first embodiment of an adapter illustrated in Figures 8 to 10 .
[0312] Figure 1 illustrates the first realization of tooth 1, and the first realization of adapter 2 for affixing tooth 1 to the edge of a bucket of an operational machine, and an affixing pin 3 for affixing the tooth to the adapter. Figures 2a, 2b, and 2c illustrate the tooth and the adapter when interconnected.
[0313] The tooth 1 has an outer surface comprising two external functional surfaces, externally opposed, namely, a first functional surface 12 and a second functional surface 14, the functional surfaces 12, 14 having a width in a horizontal direction H, intended to extend along said edge of a bucket, and having a length L that extends between a display end and a tip 16 of said tooth, the functional surfaces 12, 14 extending along said length L, while converges in a vertical direction V, so that the first and second opposing functional surfaces 12, 14 are connected at said tip 16 of the tooth.
[0314] The first and second functional surfaces 12, 14 form the largest external surface area of the tooth and, in use, will be directed towards the front / rear of the bucket for carrying out the functional operations.
[0315] The outer surface of tooth 1 still defines opposite external side walls 17, which essentially extends only along the vertical and longitudinal directions, and which interconnect the first and second external walls 12, 14.
[0316] For coupling tooth 1 to an adapter 2, which, in the illustrated embodiment, in turn, must be attached to a bucket of an operational machine, tooth 1 comprises cavity 103 extending from a tooth attachment end , opposite the tip 16 of the tooth.
[0317] With this, as illustrated, for example, in Figure 3, the tooth comprises a cavity 103 to receive a part of said adapter, the cavity 103 extending between said first and second opposite external functional surfaces 12, 14 of a open end 104, at said end of affixing the tooth, to a lower end 105. The cavity 103 is bounded by an inner wall 102.
[0318] Tooth 1, in addition, defines opposite hollow holes 109 in the outer wall of tooth 1. The opposite hollow holes 109 form a passage to receive a pin that extends through the coupling part of the tooth, that passage extends, in general, in the horizontal direction H by the tooth.
[0319] Adapter 2 is intended for attaching a tooth to the edge of an operating machine bucket, such as an excavator or loader. For this purpose, the adapter 2 comprises a connector part 22 for disposal to a bucket, and a tip part 203 for disposal in a corresponding cavity 103 of a tooth 1.
[0320] The connector part 22 can have any desired shape that allows its attachment to the edge of a bucket. In the embodiment described in Figures 1 to 2c, and Figures 8 to 10, the connecting part forms a fork structure 23, having two legs vertically separated between which the edge of a bucket can be positioned. With this, the edge of the bucket will be arranged so that it generally extends along the horizontal direction H.
[0321] As seen, for example, in Figure 8, and 10a to 10d, the tip part 203 extends along the longitudinal direction L of a connector end 204 to a free end 205, and has an outer wall 202.
[0322] The outer wall 202 comprises a first outer wall 206 and a second opposite outer wall 207, The first and second outer walls 206, 207 extending in the horizontal direction H, which, when arranged in a bucket, extend along from its edge.
[0323] Furthermore, the outer wall 202 comprises opposite side walls 208, which interconnect said first and second inner walls 206, 207.
[0324] A hollow orifice 209 is extending through the tip part 203, along the horizontal direction H.
[0325] To attach the tooth 1 to the adapter 2, the tip part 203 is inserted into the cavity 103 and a fixation pin 3 is fixed in the passage formed by the hollow hole 109 of tooth 1 and the hollow hole 209 of the adapter.
[0326] When tooth 1 is attached to an adapter 2 arranged on the edge of the bucket, the tooth and adapter arrangement is ready for use.
[0327] As mentioned above, tooth 1 is designed so that the first outer wall 12 and the second outer wall 14 are the largest “functional surfaces” of the tooth and, thus, are effective in carrying out the functional operation of the excavation, digging etc.
[0328] Likewise, in use, relatively large forces will appear, generally coming from the vertical direction V and being applied to the first external wall 12 or the second external wall 14, and adjacent to the tip 16 of the tooth.
[0329] Also, longitudinal forces can be applied in a generally longitudinal direction L, to each extreme end of the tooth tip 16, and horizontal forces can be applied, acting mainly on the external lateral surfaces 17.
[0330] Naturally, the division of forces to the vertical, longitudinal and horizontal forces is a simplification of the real forces appearing when the tooth and the adapter are used. However, when designing a coupling between a tooth and an adapter, these simplified notions are independently useful, and will be used below to explain the behavior of the tooth and adapter described here.
[0331] It will be understood here, that the terms "vertical", "horizontal", and "longitudinal" are defined in relation to the tooth and the adapter only.
[0332] “Horizontal” means a direction parallel to the direction along which the edge of a bucket to which the adapter must be attached extends.
[0333] By “longitudinal” it is understood a direction of extension of the tooth and the adapter of a display end or connector end, respectively located towards the bucket, and extending towards the tip of the tooth or the free end of the part edge, perpendicular to the horizontal direction.
[0334] “Vertical” means a direction perpendicular to both the horizontal and the longitudinal direction.
[0335] Although the directions mentioned above are described with reference to the realization of the drawings, it is subject that its description is not limited to these realizations, but can be easily applied to other realizations of the tooth and adapters.
[0336] It will be understood that as forces directed vertically, horizontally or longitudinally are applied to the tip of the tooth, when in use, these forces will be transmitted to the part of the adapter through the contact created between the tooth and the adapter in the tooth cavity and the tip portion of the adapter.
[0337] The description of the first aspect of the invention, namely, a tooth, will be continued when describing the cavity, said cavity being delimited by an internal wall.
[0338] The internal wall comprises first and second internal walls facing internally, which are the internal surfaces associated with said first external functional surface and said second external functional surface, respectively.
[0339] Likewise, the first and second inner walls, mainly, will be involved in the transfer of vertical forces applied to the first and second external functional surfaces.
[0340] In addition to the first and second inner walls, the inner wall comprises opposite side walls, which interconnect said first and second inner walls.
[0341] In addition, the opposite side walls delimit the opposite hollow holes to receive a pin that extends through the cavity to affix the tooth to the adapter part.
[0342] It follows from the aforementioned that the hollow holes can therefore be arranged so that a pin extending through the holes extends in a direction substantially parallel to the edge of a bucket in which the tooth must be arranged (that is, the horizontal direction H).
[0343] For the purpose of enabling additional definition of tooth aspects, a first X axis can be defined by extending through the centers of the opposite hollow holes.
[0344] A second Y axis can be defined by extending along the cavity of the open end of the cavity towards the lower end of the cavity, and a third Z axis can be defined, which is orthogonal to said first and second axes X, Y .
[0345] The three axes X, Y, Z are, thus, forming a system of orthogonal axes, which are in an origin, with which each point of the inner wall can be defined by the Cartesian coordinates (x, y, z ).
[0346] From the definitions above, it follows that the X axis, which extends through the hollow holes, will be substantially parallel to the horizontal direction H, discussed above.
[0347] However, although the Z axis generally extends to have a component along the vertical direction V, the Z axis does not need to be parallel to the vertical direction V.
[0348] Similarly, although the Y axis generally extends to have a component along the longitudinal direction L, the Y axis does not need to be parallel to the longitudinal direction L.
[0349] This is due to the cavity of the tooth not having to be perfectly aligned with the overall external shape of the tooth. On the contrary, there is room for variation, for example, in the shape of the part of the tooth that extends longitudinally beyond the cavity. In all horizontal, vertical and longitudinal directions, as discussed here, they should be seen as general directions in space, and are used only for general explanations, which is why more precise definitions are not necessary. In contrast, the X, Y and Z axes are specifically defined and the achievements will be described in detail with reference to them.
[0350] To exemplify the aspects mentioned above, now, reference will be made to the first exemplary realization of a tooth and, in particular, Figures 3 to 5.
[0351] Figures 3 to 5 illustrate an embodiment of a tooth having a cavity 103, the cavity being delimited by an inner wall 102.
[0352] The inner wall 102 comprises first and second inner walls facing internally opposite 106, 107, which are the inner surfaces associated with said first functional surface 12 and said second functional surface 14, respectively.
[0353] Furthermore, the inner wall 102 comprises side walls opposite internally 108, interconnecting said first and second inner walls 106, 107. The opposite side walls 108 are, in general, the internal surfaces associated with the outer side walls.
[0354] Opposite side walls 108 delimit opposite hollow holes 109 to receive a pin 3 that extends through the cavity 103 for attaching tooth 1 to the adapter 2. The pin 3, when disposed through the hollow holes 109, thereby extending it will be in a direction substantially parallel to the edge of the bucket in which the tooth must be disposed, namely, the horizontal direction H, as mentioned above.
[0355] The definition of the three axes X, Y and Z can be made in reference to the embodiment described in Figures 3 to 5, as follows: The first X axis is defined by extending through the centers of the opposite hollow holes 109, the second axis Y is extending along the cavity 103 of the open end 104 of the cavity towards the lower end 105 of the cavity, and the third Z axis is orthogonal to said first and second axes X, Y.
[0356] In the figures, it is seen how the three axes X, Y, Z, with this, are forming an orthogonal axis system, which are in an origin, in which each point of the inner wall 102 can be defined by Cartesian coordinates X Y Z.
[0357] The cavity defines a rear part that extends along the Y axis, the rear part being at least partially located between the plane covered by the X axis and Z axis and the open end of the cavity, and a front part that extends along the Y axis, the front part being located between the plane covered by the X and Z axes and the lower end of the cavity; and a staggered part, which interconnects the rear and the front.
[0358] With this, the contact surfaces are provided at the rear and at the front of the cavity, in the first and second internal walls internally opposite. When in use, the first and second contact surfaces at the rear and front of the tooth will be in contact with corresponding surfaces of the adapter and, thus, will be efficient in transferring forces applied to the tooth to the adapter.
[0359] When the tooth is in use, attached to a bucket by means of the adapter, vertical loads applied to the first or second external surface of the tooth, and at the tip of the tooth, will often appear and, in addition, they will be relatively large forces. Likewise, it is desired that the coupling is well adapted to withstand these vertical loads.
[0360] Vertical loads will generally be transferred from the first or second external functional surface, adjacent to the tip of the tooth, to the first and second contact surfaces of the first and second internal walls of the cavity. The first and second contact surfaces will work in pairs. If a vertical force is acting towards the second outer wall of the tooth tip, the first rear contact surfaces and second front contact surfaces will form a pair that transmits the load to the tip portion of the adapter.
[0361] Similarly, if a vertical force is acting towards the first outer wall of the tip of the tooth, the second rear contact surfaces, and the first front contact surfaces, will form a pair that transmits the load to the tip part. adapter.
[0362] In order for contact surfaces to efficiently transfer vertical loads, it is generally desired that the contact surfaces should be as close as possible to being parallel to each other, and to the Y axis (as seen in any parallel plane to the plane covered by the Y and Z axes). However, in order to allow adjustment and removal of the tooth to / from the adapter, a slight deviation from the parallel surfaces is necessary. The deviation could be up to 5 degrees, preferably no more than 2 degrees.
[0363] Therefore, all said first and second rear and front contact surfaces are to form an angle (alpha) less than 5 degrees with the Y axis, as seen in any plane parallel to the plane covered by the Z and Y axes. Preferably , the alpha angle can be less than 2 degrees.
[0364] At least the first and second rear contact surfaces must form the same angle (alpha) less than 5 degrees with the Y axis. This defines the Y axis in the bisector between the first and second rear contact surfaces.
[0365] The rear part extends along the Y axis, and is at least partially located between the plane covered by the X and Z axes and the open end of the cavity. As will be described below, the first and second pairs of rear contact surfaces, with the corresponding rear dividing regions, are extending in the rear region and, therefore, the rear contact surfaces will be extending at least partially beyond the plane covered by the X and Z axes, which is behind the centers of the holes for the display pin. The first and second front contact surfaces are, on the contrary, arranged on the front, which is located in front of the centers of the holes for the attachment pin. Due to this arrangement, and when the front and rear contact surfaces are working in pairs, a distribution of force is allowed, which reduces the tension in the area of the tooth adjacent to the holes for the fixation pin. This will reduce the risk of the tooth being broken or damaged in the area adjacent to the holes for the attachment pin and, thus, will allow the use of less material.
[0366] Likewise, the display pin arrangement is protected from excessive load. This, in turn, requires that the function of the pin is maintained during the use of the tooth, resulting in the stable function of the display and possibilities maintained for the removal of the tooth from the adapter.
[0367] The first front contact surface is located closer to the plane covered by the X and Y axes than the first rear contact surfaces.
[0368] The arrangement with the first and / or second rear contact surfaces and the corresponding first and / or second front surfaces extending in different planes, with the frontal contact surface located closer to the plane covered by the X and Y axes than the rear contact surface contributes to controlled force distribution, protecting the pin area of the connection. In addition, the arrangement provides the cavity that becomes narrower in the direction towards the tip of the tooth, thereby following the general requirement for a tooth having an outer surface that tapers towards the tip.
[0369] The cavity defines a staggered part, which interconnects the rear and the front. In the staggered part, the first and / or second inner wall forms a slope that interconnects the first and / or second rear contact surface and the first frontal contact surface.
[0370] The slope should advantageously be curved. Preferably, the slope can be S-shaped.
[0371] It will be understood that in order to be a “slope”, the slope must deviate from the plane of the first rear contact surface, and approach the plane covered by the X and Y axes, in order to interconnect with the first frontal contact surface .
[0372] Advantageously, the inclination could interconnect a front and rear contact surface arranged so that, if they are interconnected by a straight line, that line would form an angle greater than 10 degrees, preferably greater than 20 degrees with the plane covered by the X and Y axes.
[0373] To exemplify the aspects mentioned above, reference will now be made to the drawings' realizations and, again, in particular, to Figures 3 to 5.
[0374] The illustrated tooth comprises a cavity 103. The first wall 106 comprises a pair of essentially planar rear rear contact surfaces 130a, b, and the second wall 107 comprises a pair of essentially opposite planar rear contact surfaces 140a, B. Thereby, the cavity defines a rear part BP in which both the first and the second inner wall 106, 107 comprise a pair of first / second rear contact surfaces.
[0375] Also, in the front part FP located between the plane covered by the X and Z axes and the lower end 105 of the cavity 103, the first wall 106 and the second wall 107, each one, comprise a pair of front contact surfaces essentially planar 110a, b, 120a, b, which are symmetrical over the plane covered by the Z and Y axes. Thus, the cavity 103 defines a front part in which each of the first and second inner walls 106, 107 comprises a pair first / second essentially planar front contact surfaces 110a, b; 120a, b. These surfaces will be described in more detail later in this order.
[0376] As can be seen in the figures, an essentially planar contact surface can be a part of a larger part of the contour formed by the inner wall, such as a ledge or platform.
[0377] To determine whether an essentially planar contact surface can be defined, it can be controlled whether there is a portion of the portion that meets the requirement to be considered "essentially planar" - that is, that coincides with an imaginary planar square having the dimensions DxD where any deviations from that square are less than 0.2 D. An area that meets these conditions can be a contact surface provided with other conditions defined here that are met.
[0378] In carrying out Figures 1 to 10, the pair of first rear contact surfaces 130a, b, and the pair of first front contact surfaces 110 a, b are all found in a structure of the first inner wall 106 forming a shoulder extending along the side walls 108 and the lower wall 105. As a result, the shoulder is approximately U-shaped. The first rear contact surfaces 130a, b are essentially flat parts of the shoulder at the rear of the cavity. The first front contact surfaces 110a, b are essentially flat parts of the shoulder at the front of the cavity.
[0379] Between the first rear contact surfaces 130a, b, and the first front contact surfaces 110a, b, a stepped portion SP is defined. In the staggered part, the first inner wall 106 is sloping so as to connect the first rear contact surfaces 130a, b with the first front contact surface 110.
[0380] In the illustrated embodiment, in the staggered part, it is seen as the shoulder that forms the contact surfaces approaches the plane covered by the X and Y axes.
[0381] With this, each of the pair of first rear contact surfaces 130a, b is located in a different plane than the first corresponding front contact surface 110a, b, and all first front contact surfaces 110a, b are located closer to the plane covered by the X and Y axes than all the first rear contact surfaces 130, a, b. The first rear contact surfaces 130a, b and the first contact surfaces 110a, b are interconnected by means of the stepped part.
[0382] The first stepped distance D1 along the Z axis is bridged by the first inner wall 106 along the stepped portion SP, between the first rear contact surfaces 130a, b and the first front contact surfaces 110a, b.
[0383] In the illustrated embodiment, the second rear contact surfaces 140a, b and the second front contact surfaces 120a, b extend in the same planes. However, alternative embodiments are possible in which the second rear contact surfaces 140a, b, and the second front contact surfaces 120a, b are arranged in a similar relationship to that of the first rear contact surfaces 130a, b and the first front contact surfaces. 110a, b. Thus, there may be a second stepped distance D2 along the Z axis which is bridged by the second inner wall 107 along the stepped part SP, between the second rear contact surfaces and the second front contact surfaces. The relationship between the first stepped distance D1 and the second stepped distance D2 will be relevant to the degree of symmetry of the cavity.
[0384] If the first stepped distance D1 is different from the second stepped distance D2, the first and second front and rear contact surfaces are arranged asymmetrically. Such achievements could be particularly advantageous for certain applications, such as loader applications.
[0385] These asymmetric arrangements can be defined by 0 <= D2 <= 0.80 D1.
[0386] According to the achievements, 0 <= D2 <= 0.50 D1.
[0387] However, and as illustrated in the figures, the second essentially planar rear contact surfaces 140a, b, and the second front contact surfaces 120a, b, can also be arranged at essentially the same distance from the covered plane. along the X and Y axes, so that D2 is zero or close to zero. Indeed, advantageously, the second essentially planar rear contact surfaces 140 a, b, and the second front contact surfaces 120a, b, can be arranged in the same planes.
[0388] In this case, on the inclined part of the cavity, the second inner wall 107 can advantageously form a pair of planar surfaces, interconnecting the second rear contact surfaces and the second front contact surfaces.
[0389] In the embodiment illustrated in Figures 1-10, the first front and rear contact surfaces 130a, b 110 a, b are found in a structure of the first inner wall 106 forming a shoulder extending along the side walls 108 and the lower wall 105. As can be seen in the figures, this shoulder is essentially planar when viewed in a cross section along a YZ plane.
[0390] Similarly, the second front and rear contact surfaces 140a, b, 120 a, b are found in a structure of the second inner wall 107 forming a shoulder extending along the side walls 108 and the bottom wall 105 .
[0391] Advantageously, the planar surface of the second inner wall 107 on the inclined part may have an alpha angle in relation to the XY plane which is similar to the alpha angle of the second front and rear contact surfaces.
[0392] All first and second rear and front contact surfaces 110, 120, 130, 140 form an alpha angle less than 2 degrees with the Y axis.
[0393] In the illustrated embodiment, all the first and second rear and front contact surfaces also form the same alpha angle less than 2 degrees with the Y axis.
[0394] The first rear contact surfaces 130a, b; and the second front contact surfaces 120 a, b will work together to transmit the vertical loads applied to the second outer wall adjacent the tip of the tooth, and the second rear contact surfaces 140 and the first front contact surfaces 110 will work together to transmit the vertical loads applied to the first external wall of the tooth tip.
[0395] Continuing, now, the general description of the first aspect of the invention, at the rear, the first internal wall will comprise a pair of first essentially planar rear contact surfaces, which are symmetrical over and which turn in opposition to the plane covered by the Z and Y axes, in order to form a beta angle with the plane covered by the X and Y axes that is less than 35 degrees. In addition, the pair of first rear contact surfaces is separated by a first rear dividing region, in which the first inner wall extends beyond the pair of first contact surfaces in the Z direction away from the XY plane.
[0396] Similarly, at the rear, the second inner wall will comprise a pair of second essentially planar rear contact surfaces, which are symmetrical over and turn away from the plane covered by the Z and Y axes, in order to form a gamma angle with the plane covered by the X and Y axes that is less than 35 degrees, the pair of second rear contact surfaces being separated by a second rear dividing region where the second inner wall extends beyond the pair of second contact surfaces in the Z direction away from the XY plane.
[0397] Turning to the exemplary realizations of Figures 1-10, at the rear, the pair of first essentially planar rear contact surfaces 130a, b are symmetrical about and face the opposite of the plane covered by the Z and Y axes, of in order to form a beta angle with the plane covered by the X and Y axes that is less than 35 degrees, and the pair of first rear contact surfaces 130a, b is separated by a first rear divider region 132 where the first inner wall 106 is extends beyond the pair of first contact surfaces 130a, b in the Z direction away from the XY plane.
[0398] Likewise, the pair of second essentially planar rear contact surfaces 140a, b, are symmetrical about each other and turn against the plane covered by the Z and Y axes, in order to form a gamma angle with the plane covered by the X and Y axes that are less than 35 degrees, the pair of second rear contact surfaces 140a, b being separated by a second rear divider region 142 where the second inner wall 107 extends beyond the pair of second contact surfaces 140a, b in the Z direction away from the XY plane.
[0399] The aspects mentioned above, applied to the back of the cavity, can express several advantages to the proposed tooth including those mentioned above.
[0400] With reference to the realization illustrated in Figures 1-10, the proposed rear part BP allows an advantageous distribution of force in the coupling between the tooth and the adapter.
[0401] When tooth 1 is connected to adapter 2, contact between the tooth and the adapter must occur between the pairs of first and second rear contact surfaces 130 a, b; 140a, b, but not in the first and second rear dividing regions 132, 142, which separate the respective pairs of contact surfaces 130a, b; 140a, b. The first and second rear dividing regions 132, 142 of the inner wall 102 of the cavity 103 are thus parts of the inner wall 102 that are not intended to be in contact with the adapter 2.
[0402] Likewise, along the rear BP, in each of the first inner wall 106 and the second inner wall 107, the contact between tooth 1 and adapter 2 must occur through two contact surfaces 130a, b ; 140 a, b that are spaced along the X axis. This means that the loads that are to be distributed on the BP rear are distributed between two separate planar contact surfaces, which operate in parallel. This, per se, will decrease the charge concentration that appears in the tooth material. In particular, the separation of the rear contact surfaces by means of a rear dividing region 132, 142 will inhibit concentrations of force that appear in the tooth material in the center of the tooth, along the plane covered by the Z and Y axes. Prevention of concentrations of force creates less risk of the tooth cracking or breaking. Likewise, the thickness of the tooth wall (between the first / second inner wall 106, 107 and the corresponding external functional surface 12, 14) can be reduced, which allows the use of a smaller amount of material.
[0403] In addition, each pair of first and second rear contact surfaces 130a, b; 140 a, b are symmetrical about and turn away from the plane covered by the ZY axes, in order to form a beta angle with the plane covered by the X and Y axes that is less than 35 degrees.
[0404] When the rear contact surface pairs 130a, b; 140a, b are active, distributing loads to the corresponding rear contact surfaces 230a, b; 240 a, b of the tip part of the adapter 2, the directions of the forces involved, with this they will have a component that acts towards the plane covered by the Z and Y axes. This, in turn, means that when loads are applied to the contact surfaces 130a, b; 140 a, b, its effect will be that the tooth 1 is additionally fixed to the adapter 2. This contributes to a secure coupling.
[0405] Also, the arrangement of the inclined rear contact surface pairs 130a, b; 140 a, b, separated by the rear dividing region 132,142, which extends beyond the inclined rear contact surfaces, in a direction away from the plane covered by the X and Y axes, allows the contour of the inner walls 106,107 and, consequently, also the external walls 12, 14 of the tooth are optimized in relation to wear.
[0406] As mentioned briefly above, when the tooth is in use, the first and second outer walls 12, 14 will be subject to wear, gradually removing material from said outer walls 12,14. In general, wear will start at the tip of the tooth 16 and gradually shorten the tooth. If wear reaches contact surfaces 130a, b, 140a, b between tooth 1 and adapter 2, the connection between tooth and adapter will be compromised, and the tooth must be replaced before wear reaches surfaces contact.
[0407] In general, when subject to wear, the external wall of the tooth will be changed, following a wear curve, since the material will be gradually removed from the first and second functional surfaces of the tooth. As a result, the first and / or second functional surface can assume a curved external shape. This curve can be described, when viewed in a transverse direction along an XZ plane, as a symmetrical curve having an apex on the Z axis and sloping towards the lateral walls of the tooth.
[0408] In the tooth illustrated in the drawings, if an external functional surface 12, 14 is subject to wear and gradually conforms to this curve, it will be understood that the contact surfaces 130a, b; 140 a, b will be protected due to the rear divider region 132, 142 extending beyond the surfaces. In other words, the contact surfaces 130a, b; 140a, b will be the last parts of the inner walls 106, 107 of the cavity 103 to be affected by wear. This ensures that tooth 1 will remain stably attached to the adapter even when considerable wear has occurred.
[0409] Furthermore, advantageously, the rear dividing region 132,142 and the outermost parts (towards the side surfaces 108) of the rear contact surfaces 130a, b, 140a, b can be positioned along a curve approximately corresponding to a wear curve. With this, it can be guaranteed that when wear occurs, the contact surfaces are the last surfaces to be affected by it. Also, the arrangement will make optimal use of the material on the tooth, since the tooth will work most satisfactorily until most of the material on the outer wall is effectively worn. With this, the tooth material will be used efficiently, since a large part of the material used for the tooth will, in fact, be available for wear and tear. When the tooth is finally worn out and needs to be replaced, a relatively small proportion of the initial amount of tooth material remains.
[0410] Also, the rear dividing region 132, 142 which extends beyond the rear contact surfaces 130a, b; 140a, b on the first and second inner walls of the cavity allows the corresponding rear dividing region of the tip portion 232, 242 of the adapter 2 to extend beyond the rear contact surfaces 230a, b; 240a, b of adapter 2. With this, the rear dividing region 232, 242 of the tip part will add material to the tip part, so that sufficient strength of the tip part can be guaranteed.
[0411] It will be understood that the above explanations apply to the first contact surfaces 130a, b and the first rear dividing region 132 and to the second contact surfaces 140a, b and the second rear dividing region 142.
[0412] An alternative way of describing the desired geometry for the cavity is to consider the contour of the cavity at the rear, as will be done below with reference to Figure 6 ’’. Likewise, a tooth having a defined cavity, as described above, in which, at the rear, the first wall has a contour formed by points x, z, the contour being symmetrical about the Z axis and having a maximum width WI.
[0413] The outline being defined by the following:
[0414] in peripheral parts in abs (x) greater than or equal to 0.9 x WI / 2, a first maximum abs (z) is defined in a pair of points (x1, z1),
[0415] for abs (x) less than abs (x1), abs (z) decreases until a minimum abs (z) is defined in (x2, z2), and for abs (x) less than abs (x2), abs (z) increases until a maximum abs (z) is defined in (x3, z3).
[0416] The same applies to the second wall (107), facing the first wall (106), at the rear of the cavity. The appearances of the first wall and the second wall can be varied in order to be adapted to different applications.
[0417] In the illustrated embodiment, as seen in Figure 6 ’’, at least one of the pairs (x1, abs (z1)); (x2, abs (z2)) and (x3, abs (z3)) differ between the first inner wall and the second inner wall. This means that the rear is asymmetrical on the XY plane, which can be desired for certain applications.
[0418] According to other achievements, the pairs (x1, abs (z1)); (x2, abs (z2)), and (x3, abs (z3)) of the first inner wall can be equal in pairs (x1, abs (z1)); (x2, abs (z2)), and (x3, abs (z3)) of the second inner wall. This can correspond to a rear part being symmetrical on the XY plane, which can be desired for certain applications.
[0419] The description mentioned above captures a contour comprising the inclined surfaces to provide a locking effect, as described above, and being adapted to conform to a wear curve, resulting in favorable coupling behavior after considerable wear, as also described above.
[0420] Advantageously, abs (z3) - abs (z1)> 0.03 x WI. This establishes a relationship between the width of the first or second wall, and the height of the rear dividing region, which is advantageous in terms of the distribution of strength and resistance.
[0421] Advantageously, abs (z3) -abs (z1) <0.6 x WI.
[0422] It will be understood that, with the above description, between (x1, z1) and (x2, z2), the outline, in general, follows a straight line abs (z) = kx abs (x) + K, where k and K are constant. The straight lines correspond to the essentially planar rear contact surfaces.
[0423] The constant k = tan (beta or gamma), where beta or gamma are aligned to what was described above.
[0424] The minimum points z (in (x2, z2)) will be defined at the junctions between the essentially planar rear contact surfaces and the rear dividing region.
[0425] It will be understood that the description above of the aspects and advantages made in relation to a tooth will also apply to the adapter to which the tooth must be attached. In general, all aspects described in relation to the tooth have a corresponding counterpart in the adapter.
[0426] Referring to the realization of the drawings, there is an adapter 2 for attaching a tooth to the edge of a bucket of an operational machine, such as an excavator or loader, adapter 2 comprising a connector part 22 for disposal to a bucket , and a tip part 203 for disposition in a corresponding cavity of a tooth 1.
[0427] The tip part 203 having a width in a horizontal direction H, which, when the adapter arranged in a bucket, extends along its edge, and having a length
[0428] extending in a longitudinal direction L from a connector end 204 at the connector part 22 to a free end 205, and having an outer wall 202.
[0429] The outer wall 202 comprising a first outer wall 206 and an externally opposite bottom outer wall 207, and externally opposed side walls 208, interconnecting said top and bottom inner walls 206, 207,
[0430] the tip part 203 comprising a hollow hole 209 extending between said opposite side walls 208, to receive a pin extending through the tip part 203 for fixing the tooth 1 to the adapter 2,
[0431] a first X axis being defined, extending through the center of the hollow hole 209,
[0432] a second Y axis extending along the tip part 203 of the connecting end 204 of the tip part towards the free end 205 of the tip part, and
[0433] a third Z axis being orthogonal to said first and second axes X, Y,
[0434] the three axes X, Y, Z, thus forming a system of orthogonal axes, which are in an origin, with which each point of the inner wall 102 can be defined by Cartesian coordinates (x, y, z ), where the tip part 203 defines a rear part which extends along the Y axis and which is at least partially located between the plane covered by the X and Z axes and the connector end 204 of the tip part, a front part which extends along the Y axis, the front part being located between the plane covered by the X and Z axes and the free end 205 of the tip part; a staggered part, interconnecting the rear and the front; at the rear, the first and second outer walls 206, 207,
[0435] each, comprise a pair of essentially planar rear contact surfaces 230a, b; 240a, b,
[0436] each pair of rear contact surfaces being symmetrical over and facing towards the plane covered by the Z and Y axes, so as to form a beta angle, gamma with the plane covered by the X and Y axes which is less than 35 degrees,
[0437] each pair of rear contact surfaces 230a, b; 240 a, b being separated by a rear dividing region 232, 242, which extends beyond the pair of first contact surfaces 230a, b in the Z direction away from the XY plane.
[0438] At the front, the first and second outer walls 206, 207, each, comprise a pair of essentially planar front contact surfaces, which are symmetrical over the plane covered by the Z and Y axes,
[0439] all contact surfaces forming an alpha angle less than 5 degrees with the Y axis, as seen in an XZ plane,
[0440] the first and / or second front contact surfaces (210a, b ,; 220a, b) being located closer to the plane covered by the X and Y axes than the corresponding rear contact surfaces (230a, b; 240a, b), and
[0441] the first and / or second outer wall (206, 207) of the staggered part forming a slope in which at least a part of the outer wall approaches the XY plane towards the lower wall, interconnecting said first and / or second rear contact surfaces and The corresponding first and / or second front contact surface.
[0442] The realization of an adapter, illustrated in Figures 7 to 10, is, in addition, an adapter, in which, at the rear, for each point y along the x-axis, the first and / or second outer wall ( 206, 207) presents a contour formed by the points (x, z), the contour being symmetrical on the Z axis and having a WI width along the X axis, the contour being defined by the following: in peripheral parts in abs (x) greater than or equal to 0.9 x WI / 2, a first maximum abs (z) is defined in a pair of points (x1, z1), for abs (x) less than abs (x1), abs (z) decreases until a minimum abs (z) is defined in (x2, z2), and for abs (x) less than abs (x2), abs (z) increases to a maximum, abs (z) is defined in (x3, z3 ), where abs (z3)> abs (z1)> abs (z2), and the first rear contact surfaces extend between the points (x1, z1) and (x2, z2), while the first rear dividing region is extends between the points (x2, z2) (x2 negative) and (x2, z2) (x2 positive), including the maximum abs (z) (x 3), z3), where abs (z3) -abs (z1)> 0.03 x WI.
[0443] In the illustrated embodiment, abs (z3) -abs (z1) <0.6 x WI.
[0444] Advantageously, the beta and gamma angles are less than 35 degrees and greater than 5 degrees.
[0445] The beta and gamma angles can, for certain applications, be substantially the same.
[0446] However, for other applications, the beta and gamma angles can be advantageously different.
[0447] In general, the respective inclination angles of the first and second rear contact surfaces must be selected, in order to achieve the desired clamping effect, while still allowing the distribution of the vertical forces to which the tooth is subjected during the use. In addition, the shape of the wear curve, as explained above, is taken into account.
[0448] For this purpose, and in particular for applications where the first outer surface 12 of the tooth will be subjected to more load and more wear than the second outer surface 14, the gamma angle may be less than the beta angle.
[0449] The pairs of first and / or second rear contact surfaces preferably extend substantially from the opposite side walls. This will allow for the greatest possible separation of the pair of contact surfaces, and will move the load transfer between the tooth and the adapter away from the plane covered by the Z and Y axes.
[0450] In general, sharp corners and edges should be avoided when forming the tooth cavity and the adapter tip, since any sharp parts will be prone to creating load concentrations and therefore it is risky to become a part weak coupling.
[0451] Likewise, and as illustrated by the realization of the Figures, although it is desired that the pair of substantially flat rear contact surfaces 130a, b; 140a, b must extend substantially from the opposite side walls 108, it is understood that a smoothly curved corner region between each side wall 108 and rear surface 130a, b; 140a, b can be provided.
[0452] Advantageously, at least the first rear contact surfaces can extend from the plane covered by the Z and X axes and a distance along the Y axis and towards the open end of the tooth corresponding to at least the largest radius r opposite holes. preferably at least 2r.
[0453] In addition, the first rear contact surfaces can extend towards the front of the plane covered by the Z and X axes, for example, approximately the distance r.
[0454] Each of the pair of first and / or second rear contact surfaces can extend at least a distance along the X axis of 0.2 x W, where W is an extension of the first / second inner wall along of the X axis, as seen in a cross section parallel to the plane covered by the X and Z axes.
[0455] In particular for loader applications, and according to the illustrated embodiment, where large vertical loads are likely to appear on the first external functional surface of the tooth and, therefore, transmitted to the second rear contact surfaces 140a, b, it is appropriate that , throughout a greater extent of the rear region, an extension along the X axis of the first rear contact surfaces 130a, b is less than the extension along the X axis of the second rear contact surfaces 140a, b opposite.
[0456] With the expression “a greater extent” we must understand here at least 50%, preferably at least 70%, more preferred at least 80%.
[0457] This provides relatively broad rear second contact surfaces, which are used to balance the vertical load applied to the first outer surface adjacent to the tip of the tooth.
[0458] Also, the first relatively narrow rear contact surfaces allow the provision of a relatively large first rear dividing region. With this, the tip part of the adapter can be provided with a relatively wide rear dividing region, adding material to the adapter and acting as a bar that improves the power of the tip part on its first side.
[0459] The aspects mentioned above of the contact surfaces of the tooth, apply equally to the contact surfaces of the adapter.
[0460] In making an adapter illustrated in the drawings, in particular, in Figures 8-10, in which the angle (beta, gamma) is less than 25 degrees, preferably 10 to 20 degrees, preferably 12 to 17 degrees, more preferred, about 15 degrees.
[0461] The gamma angle of the second outer wall 207 may be less than the beta angle of the first outer wall 206, preferably gamma is 5 to 15 degrees and beta is 10 to 20 degrees.
[0462] The pairs of first and / or second rear contact surfaces 230a, b; 240 a, b extend substantially from the opposite side walls 208, and, preferably, substantially to the respective rear dividing region 232, 242.
[0463] The rear part, comprising the first and second rear contact surfaces 230a, b; 240a, b extends at least from the plane covered by the Z and X axes, and a distance along the Y axis, in a direction towards the connecting end 204, corresponding to at least the largest radius r of the opposite hollow hole 209.
[0464] The rear part, comprising the first and second rear contact surfaces 230a, b; 240a, b, also extends in front of the plane covered by the Z and X axes and a distance along the Y axis, in a direction towards the free end 205, corresponding to at least the largest radius r of the hollow hole 209.
[0465] Each of the pair of first and / or second rear contact surfaces 230a, b; 240a, b extends at least a distance along the X axis of 0.2 x WI, where WI is an extension of the first / second outer wall 206, 207 along the X axis.
[0466] Throughout a larger extension of the rear, the extension along the X axis of the first rear contact surfaces 230a, b is less than the extension along the X axis of the second opposite rear contact surfaces 240a, b.
[0467] Returning to the tooth again, the first and second rear contact surfaces are each separated by a first and second rear dividing regions, respectively. The first and / or second rear dividing region may comprise a pair of dividing lateral surfaces, which are symmetrical about, and face towards the ZY plane.
[0468] Advantageously, the first and / or second rear dividing region extends substantially from the first and / or second rear contact surfaces, respectively.
[0469] As explained earlier, sharp corners and edges should be avoided, which is why the dividing side surfaces can be joined to the rear contact surfaces through a smoothly curved joint region.
[0470] An extension of the first / second rear dividing region in the Z direction away from the XY plane can therefore be determined by an extension of the respective pair of dividing lateral surfaces in said direction.
[0471] In the embodiment illustrated in Figures 1-10, the first and second rear dividing regions 132, 142, each comprise a pair of dividing lateral surfaces 134, 144, which are symmetrical about and face towards the ZY plane. The dividing side surface pairs 134, 144 extend substantially from the first and / or second rear contact surfaces 130a, b, 140 a, b, respectively.
[0472] The rear dividing region and, thus, the dividing lateral surfaces may form part of a larger portion of the contour formed by the inner wall, like a ridge.
[0473] In the embodiment illustrated in Figures 1-10, a first ridge is formed in the first wall 106, which extends along the Y axis essentially from the open end 104 of the cavity. Between the first rear contact surfaces 130a, b, the ridge forms the first rear dividing region 132 comprising the pair of first dividing lateral surfaces 134.
[0474] The ridge extends beyond the first rear contact surfaces 130a, b along the Y axis, and to a staggered part, which will be described later in this application.
[0475] Similarly, in the embodiment illustrated in the Figures, a second ridge is formed on the second wall 107, which extends along the Y axis essentially from the open end 104 of the cavity. Between the second rear contact surfaces 140a, b, the ridge forms the second rear divider region 142 comprising the pair of second divider side surfaces 144.
[0476] For asymmetric applications, such as, for example, for loading machines, and as shown in the illustrated embodiment, for a greater extension of the first rear and front parts, the maximum extension of the first rear dividing region in the Z direction away from the XY plane is greater than the maximum extension of the second rear dividing region in the Z direction away from the XY plane.
[0477] As explained above, this configuration is favorable for applications in which, during use, the largest and most frequent vertical forces will be applied to the first external surface of the tooth.
[0478] Advantageously, the extension of the first and / or second rear dividing region in the Z direction away from the XY plane decreases from a maximum adjacent to the open end of the cavity along the Y axis towards the lower end of the cavity.
[0479] With an extension of the rear dividing region in the Z direction decreasing towards the lower end of the cavity, it is possible to project a tooth having an outer surface that narrows towards its tip, as is desired to ensure sufficient penetration of the tooth, when in use. Furthermore, it will be understood that the advantages with the rear dividing region that separates the first and second rear contact surfaces are more pronounced in the first and the second rear part of the tooth cavity.
[0480] The dividing side surfaces of the cavity are generally not intended to be in contact with the tip portion of the adapter. Likewise, some variation in the shape of the dividing side surfaces can be tolerated, as long as the tooth fits on the tip part of the intended adapter.
[0481] However, in general, it is desired that the dividing lateral surfaces form part curved or slightly curved, avoiding, again, sharp edges and corners.
[0482] Preferably, each of the pair of dividing side surfaces may comprise a more staggered region in which a tangent to the lateral surface in the XZ plane forms an angle greater than 45 degrees with the X axis, followed by a flatter region, in which a tangent to the lateral surface in the XZ plane forms an angle less than 45 degrees with the X axis.
[0483] As a result, the rear dividing region will increase in distance from the contact surfaces, along the Z axis, with a rapid rate of increase adjacent to the contact surfaces, and slower or not at all in a region adjacent to the Z axis .
[0484] As a result, the most staggered region of each of the pair of dividing side surfaces has a greater extent along the Z axis than along the X axis. Since this surface is not intended to hold any applied vertical loads substantially parallel to the Z axis, this configuration is adequate.
[0485] However, in order to provide sufficient strength, while avoiding load concentrations on the tooth and / or adapter, it is desirable that the most staggered region of each of the pair of dividing side surfaces, over a greater length extension along the X axis of the most staggered region, a tangent to the lateral surface in the XZ plane forms an angle greater than 45 degrees, less than 80 degrees with the X axis towards the Z axis.
[0486] In the flatter region of each of the pair of dividing side surfaces, over a greater length of their length along the X axis, a tangent to the dividing side surface in the XZ plane can form an angle less than 5 degrees with the X axis towards the Z axis.
[0487] With this, the flatter region can, at least along a part of it, be essentially parallel to the X axis.
[0488] In the illustrated embodiments, with particular reference to Figure 6 '', each of the pairs of side surfaces 134, 144 of both the first rear partition 132 and the second rear partition 142 comprises a more staggered region 134 ', 144', where, a tangent to the lateral surface in the XZ plane forms an angle greater than 45 degrees with the X axis, followed by a flatter region 134 ', 144' '' where a tangent to the lateral surface in the XZ plane forms a smaller angle than 45 degrees with the X axis.
[0489] As a result, the most staggered region of each of the pair of dividing side surfaces 134 ’, 144’ has a greater extent along the Z axis than along the X axis.
[0490] In addition, along a greater length extension along the X axis of the most staggered region 134 ', a tangent to the lateral surface in the XZ plane forms an angle greater than 45 degrees, and less than 80 degrees with the X axis towards the Z axis.
[0491] In the flatter region 134 '', 144 '' of each of the pair of dividing side surfaces, over a greater extension of their length along the X axis, a tangent to the dividing side surface in the XZ plane can form an angle less than 5 degrees with the X axis towards the Z axis.
[0492] With this, the flatter region is, at least along its longest extension, essentially parallel to the X axis.
[0493] The aspects described above referring to the dividing region of a tooth apply equally to a dividing region of a tip part of an adapter. However, the aspects are naturally inverted, so that the crest that forms a dividing region, described above, corresponds to a protruding edge formed by the tip part.
[0494] The embodiment of an adapter, illustrated in Figures 8 to 10, is an adapter in which the first and / or second rear dividing region 232, 242 comprises a pair of dividing side surfaces 234, 244, which are symmetrical about and which turn contrary to the ZY plane.
[0495] The pair of dividing side surfaces 234, 244 of the first and / or second rear dividing region 232, 242 extends substantially from the first and / or second rear contact surfaces 230a, b, 240a, b, respectively.
[0496] The extent of the first and / or second rear dividing region 232, 242 in the Z direction distant from the XY plane is determined by an extension of the corresponding pair of dividing lateral surfaces 234, 244 in said direction.
[0497] Along most of the rear of the tip part, the extension of the first rear dividing region 232 in the Z direction away from the XY plane is greater than the extension of the second rear dividing region 242 in the Z direction away from the XY plane.
[0498] The extension of the first and / or second rear dividing region 232, 242 in the Z direction away from the XY plane has a maximum adjacent to the connecting end 204 of the tip part and decreases along the Y axis, towards the free end the tip part 205.
[0499] For the first and / or second dividing region, each of the pair of dividing side surfaces 234, 244 comprises a more staggered region 234 ', 244' in which a tangent to the lateral surface in the XZ plane forms an angle greater than 45 degrees with the X axis, followed by a flatter region 234 ', 244' '' where a tangent to the side surface in the XZ plane forms an angle less than 45 degrees with the X axis.
[0500] Said most staggered region 234 ', 244' of each of the pair of dividing side surfaces 234, 244 has a greater extent along the Z axis than along the X axis.
[0501] For the first and / or second rear dividing region, along a greater length extension along the X axis most staggered region 234 ', 234', a tangent to the lateral surface in the XZ plane forms an angle greater than 45 degrees and less than 80 degrees with the X axis towards the Z axis.
[0502] For the first and / or second rear dividing region, along a greater length extension along the X axis of the flatter region 234 '', 244 '', a tangent to the dividing lateral surface in the XZ plane forms a angle less than 5 degrees with the X axis towards the Z axis.
[0503] When the tooth and the adapter are assembled, contact is intended to occur between the contact surfaces of the tooth and the adapter, respectively, but not in the rear dividing region. Therefore, the relative sizes of the aspects must be adjusted, so that a gap is obtained between the dividing regions of the tooth and the adapter, when the contact surfaces of the tooth and the adapter are in contact.
[0504] In the first and second front parts, the essentially planar contact surfaces can advantageously be advantageous in a similar way to the arrangement in the first rear parts.
[0505] Likewise, at the front, the first inner wall can comprise a pair of first essentially planar front contact surfaces, which are symmetrical over and turn away from the plane covered by the Z and Y axes, in order to form a delta angle with the plane covered by the X and Y axes that is less than 35 degrees.
[0506] In addition, at the front, the second inner wall can comprise a pair of second essentially planar front contact surfaces, which are symmetrical over and turn away from the plane covered by the Z and Y axes, in order to form an angle epsilon with the plane covered by the X and Y axes that is less than 35 degrees.
[0507] Advantageously, the delta angle and / or the epsilon angle are 10 to 20 degrees, preferably 12 to 17 degrees, more preferably about 15 degrees.
[0508] Preferably, the delta angle is substantially equal to the beta angle, and the epsilon angle is substantially equal to the gamma angle. As a result, the first front and rear contact surfaces will extend in parallel with each other, and the second front and rear contact surfaces will extend in parallel with each other.
[0509] In the embodiment shown in Figures 1 to 7, the front part FP, the first inner wall 106 comprises a pair of first essentially planar front contact surfaces 110a, b, which are symmetrical over and turn away from the plane covered by the Z and Y axes, forming a delta angle with the plane covered by the X and Y axes that is less than 35 degrees.
[0510] Similarly, in the front part FP, the second inner wall 107 comprises a pair of second essentially planar front contact surfaces 120a, b, which are symmetrical over and turn away from the plane covered by the Z and Y axes, so as to form an epsilon angle with the plane covered by the X and Y axes that is less than 35 degrees.
[0511] Advantageously, the delta angle and / or the epsilon angle are less than 25 degrees, preferably 10 to 20 degrees, preferably 12 to 17 degrees, more preferably about 15 degrees.
[0512] As mentioned above, the first front and rear contact surfaces can be arranged in parallel planes, the planes being in a transformed relationship, so that the first front contact surfaces are located closer to the plane covered by the Y and Y axes X, than the first rear contact surfaces.
[0513] For loader applications or other asymmetric applications, the second front and rear contact surfaces can, however, be arranged not only in parallel planes, but in the same plane.
[0514] At the front, the pair of first and / or second front contact surfaces can be separated by a first / second front dividing region in which the first / second inner wall extends beyond the pair of first / second contact surfaces frontal in the Z direction away from the XY plane, at least along a divided part of an extension of the first / second frontal contact surfaces along the Y axis.
[0515] It will be understood that a separation of the contact surfaces by a frontal dividing region in the front parts of the cavity will provide essentially the same advantages as in the rear parts of the cavity. However, due to the distribution of force, the advantages of providing a dividing region at the front of the cavity are not as pronounced as at the back. In addition, since the need for penetration of the tooth requires that its external shape narrows towards its tip, the provision of a frontal dividing region must therefore be balanced with the available space.
[0516] Therefore, although the pair of frontal contact surfaces can advantageously be separated by a frontal dividing region, this is not necessary to achieve some of the advantages mentioned here earlier.
[0517] Alternatively or in addition to the one mentioned above, at the front and / or at the front, the pair of first / second front contact surfaces can be connected by a first / second front connection region, where the first / second inner wall extends in the Z direction towards the XY plane, at least along the connected part of an extension of the first / second front contact surfaces along the Y axis.
[0518] With this, a connection region is directed to the XY plane, which, on the contrary, is the dividing region that is directed away from the XY plane. The connecting region, however, should not have an extension along the Z axis being comparable to that of the dividing regions. Alternatively, the connection region should form a light curved connection between the pair of front contact surfaces.
[0519] In the embodiment illustrated in Figures 1 to 10, the pair of first and second front contact surfaces 110a, b; 120 a, b extends along the Y axis of the lower end 105 of the cavity. In a first connected part, extending from said lower end, the respective pairs of first / second front contact surfaces 110a, b; 120 a, b are connected by a first / second front connection region 113, 123 respectively. In the front connection regions 113, 123, the first / second inner wall 106, 107 interconnects the pair of first / second contact surfaces, and extends towards the XY plane.
[0520] The pairs of first and second frontal contact surfaces may, in other embodiments, also extend beyond the connected part, farther from the lower end of the cavity along the Y axis. Here, the connected part can be followed by a divided part, in which the pair of first / second front contact surfaces is separated by a first / second frontal dividing region, respectively. In the first / second front dividing regions, the first / second inner wall extends beyond the pair of first / second front contact surfaces in the Z direction away from the XY plane.
[0521] In the illustrated embodiment, the connected part comprising the first / second front contact surfaces 110, 120 and the connection region 113, 123 between them form part of the structure that forms a shoulder, as previously described, and which forms a structure continuous with the first / second rear contact surfaces in the exemplified embodiment.
[0522] In general, any connected part of this should be located closer to the lower end of the cavity than a divided part, if present.
[0523] In the illustrated embodiment, an end part of the cavity, towards the lower end, can form a shape of approximately four sides, which can be seen in Figure 6d, comprising the opposite side walls, the pair of first contact surfaces 110a, b with its connected region 113, and the pair of second contact surfaces 120a, b with its connected region 123.
[0524] In the illustrated embodiment, the first and second front contact surfaces 110a, b, 120 a, b extend substantially from the lower end 105 of cavity 103.
[0525] However, the realizations can be predicted, in that the length of the connected part of the first internal wall does not need to be similar to the length of the connected part of the second internal wall.
[0526] In the embodiment illustrated in the drawings, the pair of second front contact surfaces 120 is located essentially on the same planes as the pair of second rear contact surfaces 140.
[0527] As can be seen in Figure 5, the second planar rear contact surfaces 140 extend almost to the open end 104, the ledge on which the contact surfaces are formed deviating from the respective planes only in the outermost region adjacent to the end open 104.
[0528] The second front contact surfaces 120 can be described as extending from the plane covered by the X and Z axes, and forward to the lower end 105.
[0529] Thus, the rear and front parts comprise second rear contact surfaces and second continuous front contact surfaces 140, 120 which also extend through the staggered part. In this case, it may not be possible to precisely define the boundary between the second rear contact surfaces 140 and the second front contact surfaces 120. However, this will not be necessary to define its presence in the tooth.
[0530] These surfaces that are defined here as “contact surfaces” do not need contact to, in fact, occur on all surfaces under practical circumstances, when tooth 1 is arranged on a part of the corresponding adapter 2. In fact, the most likely surfaces for actual contact to occur are the second rear contact surfaces 140 and the first front contact surfaces 110, at least when considering a downward vertical load being applied to the tip of the tooth 1.
[0531] The first and / or second front contact surfaces 110, 120 can extend further back into the cavity, where they can be separated by a frontal dividing region that extends beyond the contact surfaces in the Z direction away from the covered plane along the X and Y axes.
[0532] The aspects mentioned above, described in connection with a tooth, are naturally also applicable to the tip part of an adapter. With reference to the realization of the drawings, Figures 8-10 illustrate an embodiment in which, at the front, the first and / or second inner wall 206,207 comprises a pair of first and / or second essentially planar front contact surfaces 210a, b, 220a, b, which are symmetrical about and turn towards the plane covered by the Z and Y axes, so as to form a delta angle with the plane covered by the X and Y axes that is less than 35 degrees.
[0533] In the front FP region, the second inner wall 207 comprises a pair of second essentially planar front contact surfaces 220a, b, which are symmetrical over and turn away from the plane covered by the Z and Y axes, so forming an epsilon angle with the plane covered by the X and Y axes that is less than 35 degrees.
[0534] The delta angle and / or the epsilon angle can be less than 25 degrees, preferably 10 to 20 degrees, preferably 12 to 17 degrees, more preferred about 15 degrees, preferably, the delta angle is substantially equal to the beta angle , and the epsilon angle is substantially the same as the gamma angle.
[0535] At the front, there is a divided part in which at least one, preferably both, of the pairs of first and second front contact surfaces 210a, b; 220a, b is separated by a first or second front dividing region 212, 222 where the first or second outer wall 206,207 extends beyond the pair of first or second front contact surfaces 210a, b; 220a, b in the Z direction away from the XY plane.
[0536] At the front, there is an interconnected part in which at least one, preferably both of the pairs of first or second front contact surfaces 210a, b; 220a, b are connected by a first or second front connection region 213, 223, where the first / second outer wall 206,207 extends in the Z direction along or towards the XY plane.
[0537] The connected part is located closer to the free end 205 of the tip part than said divided part.
[0538] Returning, again, to the description of the tooth, the staggered part of the cavity extends between the rear part and the front part of the cavity. In terms of definition, the rear part of the cavity is a part along the length of the Y axis within which the first and second inner walls have a pair of first / second rear contact surfaces, separated by a rear dividing region and according to described above. The front part of the cavity is a part along the length of the Y axis within which both the first and second inner walls have a pair of first or second front contact surfaces, arranged symmetrically on the Z and Y axes.
[0539] The staggered part of the cavity interconnects the rear and the front. One or more of the essentially planar contact surfaces can optionally extend from the rear or front to the stepped part of the cavity.
[0540] However, the staggered part must interconnect at least the first rear contact surfaces and the first front contact surfaces that are located in different planes. For this purpose, the stepped part comprises an inclination.
[0541] In the staggered part, the first inner wall can advantageously merge with the first rear contact surfaces, the first rear dividing region, and the first front contact surfaces.
[0542] Advantageously, the staggered part comprises an inclination that forms an S shape, so as to merge with said surfaces.
[0543] For this purpose, the staggered part may form a pair of first inclination surfaces, which are symmetrical over and turn away from the plane covered by the Z and Y axes, extending between and merging with the first contact surfaces rear and first front contact surfaces.
[0544] Also, the staggered part may form an intermediate dividing region, extending between the first intermediate rear surfaces and, furthermore, extending between and merging with the first rear dividing region and the first frontal dividing region.
[0545] Although the intermediate dividing region can advantageously have an inclined or staggered shape, in order to follow a general contour that narrows the tooth, this is not necessary. The front contact surfaces must be closer to the plane covered by the X and Y axes than the rear contact surfaces, which means that the surfaces that interconnect these contact surfaces must be inclined - that is, the first mentioned inclination surfaces above. However, since the purpose of the intermediate dividing region in the staggered part of the tooth is to make room for a dividing region that protrudes corresponding to the adapter, which in turn provides resistance to the adapter, the dividing region could be arranged with other shapes in the staggered region. Likewise, the dividing region in the stepped part of the cavity is referred to as an “intermediate” dividing region rather than an “inclined” dividing region - since there is, in fact, no requirement for that particular region to be inclined .
[0546] The first rear dividing region, the intermediate dividing region, and any first frontal dividing region can thus form a continuous dividing area, the maximum extent of which, in the Z direction distant from the XY plane, decreases from a maximum adjacent to the open end of the cavity along the Y axis, towards the lower end of the cavity.
[0547] In the embodiment illustrated in Figures 1-10, the first inner wall 106 of the cavity 103 forms this inclination between the first rear contact surfaces 130a, b and the first front contact surfaces 110a, b.
[0548] The first inner wall 106 of the staggered part merges with the first rear contact surfaces 130a, b, the first rear dividing region 132, and the first front contact surfaces 110a, b. For this purpose, the staggered part forms a pair of first intermediate rear surfaces 150a, b, which are symmetrical over and turn in opposition to the plane covered by the Z and Y axes, which extends between and merges with the first rear contact surfaces 130a, b and the first front contact surfaces 110 a, b.
[0549] Also, the staggered part forms an intermediate dividing region 152, which extends between the first intermediate rear surfaces 150a, b and, furthermore, extending between and merging with the first rear dividing region 132 and the first frontal dividing region 112.
[0550] Likewise, the first rear contact surfaces 130a, b, the first rear surfaces 150a, b, of the staggered part, and the first front contact surfaces 110, together, form a shoulder, as previously described. The shoulder having a generally U-shape and extending along the side walls 108 and the lower wall 105 of the cavity 103.
[0551] The first rear dividing region 132 and, the intermediate dividing region 152 and the frontal dividing region 112, form a continuous dividing area. An extension of the continuous dividing area in the Z direction away from the XY plane decreases from a maximum adjacent to the open end 104 of the cavity along the Y axis, towards the lower end of the cavity 105, where the continuous dividing area merges with the first ones. front contact surfaces 110 and the connection surface.
[0552] Likewise, the continuous dividing area is equal to the ridge, as described above, extending on the first inner wall 106, in a direction along the Y axis. The ridge is surrounded by the ledge, as described above.
[0553] The aspects mentioned above apply, in a similar way, to the tip part of an adapter. With reference to the drawings, Figures 7 to 10, an adapter is described in which, in the staggered part, the first internal wall merges with the first rear contact surfaces 230a, b, the first rear dividing region 232, and the first surfaces of front contact 210a, b, forming said slope 230a, b at least between the first rear contact surfaces and the first front contact surfaces 210a, b.
[0554] The second outer wall 207 in the staggered part forms a slope 260a, b which approximates the plane covered by the X and Y axes, while extending towards the free end 205, interconnecting said second rear contact surfaces 240a, be said second front contact surface 220a, b.
[0555] In the staggered part, the first and / or second outer wall 206, 207 merges with the first and / or second rear contact surfaces 230a, b, 240a, b, the first and / or second rear dividing region 232, 242 , and the first and / or second frontal contact surface (s) 210a, b, 230a, b, forming the said slope (s) 250a, b, 260a, b by less between the first and / or second rear contact surfaces 230a, b; 240a, b and the first and / or second front contact surfaces 210a, b; 220a, b.
[0556] The slope is curved, forming an S-shape.
[0557] The first front and rear contact surfaces 210a, b, 230a, b; 220a, b; 240 a, b, being connected by said slope 250a, b; 260a, b, are arranged so that, if they were interconnected by a straight line, that line would form an angle of more than 10 degrees, preferably more than 20 degrees with the plane covered by the X and Y axes.
[0558] The staggered part, the first and / or second inner wall 106, 107 form a pair of first sloping surfaces 250a, b; 260 a, b, which are symmetrical over the plane covered by the Z and Y axes, extending between and merging with the first and / or second rear contact surfaces 230a, b; 240 a, b and the first and / or second corresponding front contact surfaces 210 a, b, 220 a, b.
[0559] In the staggered part, the first and / or second outer surface 206, 207 forms an intermediate dividing region 252, 262, which extends between the first or second inclined rear surfaces 250a, b, and, furthermore, extending between and merging with the first or second rear dividing region 232, 242 and the first or second front dividing region 212,222.
[0560] The first and / or second rear dividing region 232, 242, and the corresponding intermediate dividing region 252, 262, form a continuous dividing region, whose maximum extension in the Z direction away from the XY plane decreases from a maximum adjacent to the end connector 204 of the tip part along the Y axis towards the free end of the tip part 205.
[0561] As discussed above, the dividing regions contribute to several advantages with the wear connection. The separation of the contact surfaces contributes to a more uniform force distribution in the wall surrounding the tooth cavity. Likewise, less material is needed to form a sufficiently strong tooth, and a tooth having a relatively thin wall around the cavity can be formed.
[0562] When considering the dividing regions of the tip part of the adapter, the opposite is true. In the partitioning region (s) of the adapter, more material is added, contributing to the strength of the adapter. Likewise, the arrangement with the contact surfaces and the dividing region (s) contributes to an advantageous distribution between tooth and cavity walls and part of the volume adapter available for the connection between tooth and adapter.
[0563] Advantageously, the dividing regions (rear, intermediate and frontal (if any)) can form a continuous dividing region that extends along the tooth. In the illustrated embodiment, this continuous dividing region forms a structure, namely, a ridge.
[0564] The continuous dividing region can advantageously be formed in order to follow the general narrowing space of the tooth, which means that the height of the continuous dividing region (Z direction) may preferentially decrease towards the lower end of the cavity.
[0565] Advantageously, a first and / or second continuous dividing region can extend along the entire rear, and forward, to the plane covered by the X and Z axes, at least at a distance r in front of the plane covered by the X and Z axes, where r is the radius of the hollow hole 109, preferably 1.5 r.
[0566] With this, the continuous dividing region will extend through the hollow holes of tooth 1 (or adapter 2) and, for adapter 2, will contribute to the resistance of adapter 2 through the region of hollow hole 209.
[0567] Advantageously, the height (z-direction) of the continuous dividing region can decrease smoothly, preferably following a radius R.
[0568] As the continuous dividing region decreases in size and width along the Z axis, it is the most staggered region of the dividing lateral surfaces that decreases in height and width (Z and X). The flatter region of the dividing lateral surfaces remains essentially constant, interconnecting the most staggered regions, until eventually merging with the frontal contact surface.
[0569] As discussed above, the first and second internal walls of the cavity will be effective in transferring vertical loads applied to the tip of the tooth, when in action. However, the tip of the tooth can also be subjected to horizontal loads.
[0570] These horizontal loads will generally be transferred to the adapter part via the opposite side surfaces of the cavity, and the opposite side surfaces of the adapter. Again, as for the first / second inner walls, the side surfaces will work in pairs, including a front side surface that extends through the first and second front parts, and a rear side surface extending through the first and second rear parts, said surfaces lateral, front and rear being located on opposite sides of the plane covered by the Z and Y axes.
[0571] As for the first / second contact surfaces, when considering the load distribution, it is preferred that the side, front and side, rear surfaces are parallel to the plane covered by the Z and Y axes. However, to allow the mounting of the tooth and the adapter part, a slight deviation from this should be allowed.
[0572] By definition, all rear contact surfaces (lateral, first or second) must have an extension at the rear of the cavity. However, the rear contact surfaces do not need to be confined to the rear of the cavity, but they can continue their extension along the plane covered by the X and Z axes. In this case, the rear contact surface will have a part of the area that extends behind the plane covered by the X and Z axes, and a part of the area that extends in front of the plane covered by the X and Z axes.
[0573] Now returning to the embodiment depicted in Figures 1 to 10, on the rear BP, the opposite side surfaces 108 comprise lateral, rear, essentially planar, opposite contact surfaces 170a, b. At the front, the opposite side surfaces 108 comprise lateral, front, essentially planar, opposite contact surfaces 180a, b.
[0574] Opposite side, rear contact surfaces 170a, b extend from the plane covered by the X and Z axes, in a direction towards the open end 105 of the cavity along the Y axis, by a distance r, where r is the maximum radius of the hollow holes 109.
[0575] In addition, the rear, side contact surfaces 170a, b extend a distance in the direction of the Z axis corresponding to at least 3 r, where r is the maximum radius of the hollow holes 109.
[0576] The extension of the rear, side contact surfaces 170a, b along the Y axis could, but does not necessarily correspond to the extension of the BP rear along the Y axis.
[0577] Instead, as seen in the drawings, the rear side contact surfaces 170a, b can extend in front of the XZ plane on the inclined part SP.
[0578] The rear side contact surfaces 170a, b and the front side contact surfaces 180a, b are located in different planes, so that all the front side contact surfaces 180a, b are located closest to the plane covered by the Z axes. and Y than all the rear side contact surfaces 170a, b.
[0579] The lateral, front, opposite contact surfaces 180a, b can extend substantially from the lower end 105 of the cavity.
[0580] In the illustrated embodiment, between the opposite rear side contact surfaces 170a, b, and the front side contact surfaces 180 a, b, intermediate side surfaces 190 a, b are defined. The opposite intermediate side surfaces 190a, b, are curved. In other words, the slope of the side walls does not need to be confined to the defined “staggered part” of the cavity.
[0581] The pair of side, front surfaces and the pair of side, rear surfaces form an angle with the YZ plane that is less than 2 degrees.
[0582] The aspects mentioned above, referring to the lateral surfaces of the tooth are equally applicable to the adapter. With reference to the drawings, an adapter is described according to any one of the preceding claims, wherein, at least at the rear, the opposite side surfaces 208 comprise lateral, rear, essentially planar, opposite contact surfaces 270a, b, and at least on the front, the opposite side surfaces 208 comprise lateral, front, essentially planar, opposite contact surfaces 280a, b.
[0583] The side, rear contact surfaces 270a, b and the side, front contact surfaces 280a, b are located in different planes. Opposite side surfaces 208 further define sloping, opposite side surfaces 290a, b that interconnect opposite rear side contact surfaces 270a, b and front side contact surfaces 280a, b.
[0584] When the tooth and the adapter are interconnected, the respective side, front and rear contact surfaces 170a, b, 270a, b, 190a, b, 290a, b are intended to come into contact. However, there is no contact in any of the lateral, intermediate, inclined regions 180a, b, 280a, b. In the same way, the tooth and the adapter can be designed in relation to each other, so that when the respective side, front and rear surfaces are in contact with each other, there is no contact along the inclined side regions.
[0585] Having discussed the vertical forces and transverse forces that can affect the tip of the tooth, when in functional condition, longitudinal forces will be mentioned shortly. Longitudinal forces can act on the tip of the tooth and, in general, along its longitudinal direction. These forces are mainly assumed by a contact surface in the form of an inner lower wall of the cavity.
[0586] As shown in Figure 2c, the inner lower wall 105 of the cavity will thereby come into contact with the tip portion 205 of the adapter, and forces can be transmitted between their surfaces.
[0587] With reference to the drawings, Figures 7 to 10, an embodiment of an adapter is revealed, in which, at least at the rear, the opposite side surfaces 208 comprise lateral, rear, essentially planar contact surfaces, opposite 270 to , b, and at least in the front, the opposite side surfaces 208 comprise lateral, front, essentially planar, opposite contact surfaces 280a, b.
[0588] The side, rear contact surfaces 270a, b and the side, front contact surfaces 280a, b are located in different planes. All front side contact surfaces 280a, b are located closer to the plane covered by the Z and Y axes than all rear side contact surfaces 270a, b. Opposite side surfaces 208 define sloping, opposite side surfaces 290a, b that interconnect opposite rear side contact surfaces 270a, b and front side contact surfaces 280a, b. The inclined side surfaces 290a, b comprise curved surfaces.
[0589] The opposite, frontal, opposite contact surfaces 280a, b extend substantially from the free end 205 of the tip portion.
[0590] The opposite side, rear contact surfaces 270a, b extend at least from the plane covered by the X and Z axes, in a direction towards the connector end 205 of the tip part along the Y axis, at least for one distance r, where r is the maximum radius of the hollow hole 209.
[0591] Opposite side, rear contact surfaces 270a, b extend at least from the plane covered by the X and Z axes, in a direction towards the free end 205 of the tip part along the Y axis, at least by one distance r, where r is the maximum radius of the hollow holes 209.
[0592] The pair of side, front surfaces 280 and the pair of side, rear surfaces 270 form an angle with the YZ plane that is less than 5 degrees, preferably less than 2 degrees.
[0593] The rear, side contact surfaces 270a, b extend a distance in the direction of the Z axis corresponding to at least 3 r, where r is the maximum radius of the hollow hole 209.
[0594] The free end 205 of the tip part comprises an inner lower wall.
[0595] The coupling between the tooth 1 and the adapter 2 can advantageously be designed so that a smooth outer surface of the coupling is formed. This is illustrated for the first realizations of the tooth and adapter in Figures 2a-2c.
[0596] At the attachment end of tooth 1, the open end 104 of the cavity is bounded by the inner wall 102, and surrounded by an outer wall of the tooth, forming a tooth wall edge. The tip part of the adapter 2 extends from a coupling part, with the coupling part forming a ring that surrounds the base of the tip part. The shape of the rim corresponds to the tooth wall edge of the tooth, so that, when the tooth and the adapter are mounted, the rim will return to said tooth wall edge, and the outer wall of the tooth and the coupling part of the adapter will form an assembled outer surface which, in general, has a smooth appearance.
[0597] The rim and edge of the tooth wall can advantageously be designed to fit strictly with each other, in order to prevent debris from entering between the tip part and the inner wall of the tooth cavity.
[0598] A second realization of a tooth will now be described with reference to Figures 11-14. A second corresponding embodiment of an adapter is exemplified in Figures 15 to 17. Several aspects of the embodiments of Figures 11 to 17 are similar to those described in connection with the embodiments of Figures 1 to 10. These similar aspects were generally provided with numbers of similar reference points.
[0599] In the following description of the achievements of Figures 11 to 17, focus will be placed on aspects not previously described with reference to the achievements of Figures 1 to 10. Figures 11 to 17 illustrate realizations in which D1 is approximately equal to D2. However, the characteristics described are equally and similarly applicable to an embodiment in which 0 <= D2 <= 0.80 D1.
[0600] In the second illustrated embodiment of a tooth, the cavity comprises, in at least one of the first and second rear dividing regions, a pair of first / second secondary, essentially planar rear contact surfaces, extending from the dividing lateral surfaces towards the YZ plane, the first / second secondary rear contact surfaces that are symmetrical over and turn away from the plane covered by the Z and Y axes, so as to form an angle (eta, theta) with the plane covered by the axes X and Y which is less than 35 degrees.
[0601] In an initial state, when the tooth and the tip part of the adapter are interconnected, the rear dividing regions of the tooth and the tip part must not be in contact with each other. Likewise, the height of the dividing regions of the tooth cavity is slightly greater, and the width of the dividing regions of the tooth cavity is slightly wider than that of the corresponding dividing regions of the tip part. On the contrary, contact between the tooth and the tip part is ensured by means of the first / second front and rear contact surfaces.
[0602] However, during use, and under certain loading conditions, the adapter tooth and / or tip may become subject to internal wear and / or deformation, affecting the contact surfaces. In this case, a wear situation can be created in which the secondary contact surfaces of the dividing regions can come into contact with each other. Likewise, secondary contact surfaces can be effective in taking control of the distribution of some of the loads from which the tooth and adapter is affected.
[0603] In making a tooth described in Figures 11 to 14, in the first and second rear dividing regions 132,142, there is a pair of first / second secondary, essentially planar rear contact surfaces 136a, b; 146a, b, extending from the dividing side surfaces towards the YZ plane. The first secondary rear contact surfaces 136a, b are symmetrical about and turn away from the plane covered by the Z and Y axes, so as to form an eta angle with the plane covered by the X and Y axes which is less than 35 degrees. The second secondary rear contact surfaces 146a, b are symmetrical about and turn away from the plane covered by the Z and Y axes, so as to form a theta angle with the plane covered by the X and Y axes which is less than 35 degrees.
[0604] The first and second secondary rear contact surfaces, essentially planar 136a, b; 146a, b are substantially parallel to the respective first and second rear contact surfaces 130a, b; 140 a, b.
[0605] In the illustrated embodiment, the secondary contact surface pairs 136a, b; 146 a, b extend along the Y axis, substantially following the entire dividing region, extending so that it can traverse the rear, angled part and / or the front part.
[0606] Aspects related to secondary contact surfaces apply, similarly, to the tip part of the adapter. Referring to the drawings, Figures 15 to 17, an embodiment of an adapter is described in which a pair of first / second secondary, essentially planar rear contact surfaces 236a, b; 246a, b, extends from the dividing side surfaces towards the YZ plane, the first / second secondary rear contact surfaces 236a, b; 246a, b that are symmetrical about and turn away from the plane covered by the Z and Y axes, so as to form an eta, theta angle with the plane covered by the X and Y axes that is less than 35 degrees.
[0607] The first / second secondary rear contact surfaces, essentially planar 236a, b; 246a, b are substantially parallel to the respective first / second rear contact surfaces 230a, b; 240 a, b.
[0608] Several alternative achievements can be designed according to the above. The size and shape of the various aspects described can be varied to suit different applications, and different requirements of the tooth and adapter.
[0609] The adapter described here, is described as forming a unitary structure, to be attached directly to the bucket, and to which the tooth is directly attached. In general, it is preferred that the adapter is, in fact, a unitary structure. However, other realizations can be envisaged, in which the adapter is a multi-piece structure, for example, comprising a first piece interconnected to a second piece, in which the first piece must be attached to the bucket and the second piece must be coupled to the teeth.
[0610] The tooth is preferably formed as a unitary structure.
[0611] Example achievements described above can be combined, as understood by a person skilled in the art. Although the invention has been described with reference to the example embodiments, many different changes, modifications and the like will become apparent to those skilled in the art.
[0612] Therefore, it should be understood that the aforementioned is illustrative of several example embodiments and that this invention is defined only by the appended claims.
[0613] Although the above disclosure is made of an adapter and a tooth of a type that is generally asymmetric, that is, where 0 <= D2 <= 0.80 D1, it should be understood that the aspects and advantages described here can also be obtained by an adapter and a tooth of a type that is generally symmetrical, that is, where 0.80 D1 <D2 <= 1. Thus, the relationship between D1 and D2 can be varied to suit different intended applications of the coupling.
[0614] As used herein, the term "comprising" or "comprises" is open-ended, and includes one or more declared aspects, elements, steps, components or functions, but does not prevent the presence or addition of one or more other aspects , elements, steps, components, functions or groups of these.

权利要求:
Claims (30)
[0001]
1. TOOTH (1) FOR ATTACHING TO THE EDGE OF A BUCKET OF AN OPERATING MACHINE, such as an excavator or loading machine, by means of an adapter, the tooth having an outer surface comprising two external functional surfaces, externally opposite, namely, a first functional surface (12) and a second functional surface (14), the functional surfaces (12, 14) having a width (W) in a horizontal direction (H) intended to extend along said rim of a trough and have a length (L) that extends between a clamping end and an edge (16) of said tooth, with the functional surfaces (12, 14) extending along said length (L), while converging in a vertical direction (V) to be connected at said edge (16) of the tooth, the tooth (1) further comprising a cavity (103) for receiving a part of said adapter, the cavity (103) extending up between those first and second opposite external functional surfaces (12, 14) from an open end (104) on said end of fixing the tooth to a lower end (105); the cavity (103) being bounded by an inner wall (102); said internal wall (102) comprising a first and a second internal wall facing internally (106, 107), which are the internal surfaces associated with said first external functional surface and said second external functional surface (12,14), respectively, and opposite side walls (108) that interconnect said first and second inner walls (106, 107), the opposite side walls (108) delimiting opposite through holes (109) to receive a pin that extends through the cavity (103) for fixing the tooth (1) to the adapter part, being defined a first geometric axis X that extends through the centers of the opposite through holes (109), a second geometric axis Y that extends along the cavity (103) of the open end (104) of the cavity towards the lower end (105) of the cavity, and a third geometric axis Z that is orthogonal to said first and second geometric axes X, Y, the three axes X, Y, Z thus forming a system of orthogonal geometric axes that are at an origin, whereby each point of the inner wall (102) can be defined by Cartesian coordinates (x, y, z), characterized in that the cavity defines: a rear part (BP) that extends along the geometric axis Y, the rear part being at least partially located between the plane covered by the geometric axes X and Z and the open end ( 104) of the cavity, a front part (FP) that extends along the geometric axis Y, the front part being located between the plane covered by the geometric axes X and Z and the lower end (105) of the cavity; and a staggered part (SP) that connects the rear and the front; at the rear, the first and second inner walls (106, 107) each comprise a pair of essentially flat rear contact surfaces (130a, b; 140a, b), with each pair of rear contact surfaces it is symmetrical and facing the opposite side in relation to the plane covered by the geometric axes Z and Y, so as to form an angle (beta, gamma) with the plane covered by the geometric axes X and Z, which is less than 35 degrees, being whereas each pair of rear contact surfaces (130a, b; 140a, b) is separated by a rear dividing region (132, 142), which extends beyond the pair of rear contact surfaces (130a, b) in the Z direction, far from the XY plane; at the front, the first and the second inner wall (106, 107) each comprise a pair of essentially flat front contact surfaces (110a, b, 120a, b) that are symmetrical in relation to the plane covered by the axes geometric Z and Y, with all contact surfaces forming an angle (alpha) less than 5 degrees with the geometric axis Y, as seen in any plane parallel to the plane covered by the geometric axes Z and Y, the first and / or the second front contact surface (110a, b; 120a, b) is located closer to the plane covered by the geometric axes X and Z than the corresponding rear contact surfaces (130a, b, 140a, b) and in the stepped part , the first and / or the second inner wall (106, 107) form a slope (150a, b and 160a, b), in which at least part of the inner wall approaches the XY plane towards the lower wall (105) that interconnects said first and / or second rear contact surfaces ( 130a, b, 140a, b) and the corresponding first and / or second front contact surface (110a, b; 120a, b), in which a first stepped distance (D1) along the geometric axis Z is bridged through the first inner wall (106) along the stepped part (SP), between the first rear contact surfaces (130 ) and the first front contact surfaces (110); and in which a second stepped distance (D2) along the geometric axis Z is bridged through the second inner wall (107) along the stepped part (SP), between the second rear contact surfaces (140) and the second front contact surfaces (120); where 0 <= D2 <= 0.80 D1.
[0002]
2. TOOTH according to claim 1, characterized in that each of the pair of the first and / or second rear contact surfaces (130a, b; 140a, b) extends at least over a distance along the geometric axis X 0.2 x WI, where WI is the extension of the first / second inner wall (106, 107) along the geometric axis X.
[0003]
TOOTH according to either of claims 1 or 2, characterized in that the first and / or the second rear dividing region (132, 142) comprises a pair of lateral dividing surfaces (134, 144) which are symmetrical and facing with respect to a and towards the ZY plane, where, preferably, the extension of the first and / or the second rear dividing region (132, 142), in the Z direction distant from the XY plane, is determined by the extension of the corresponding pair of dividing lateral surfaces ( 134, 144) in said direction.
[0004]
4. TOOTH according to claim 3, characterized in that along a majority of the rear part of the cavity, the extension of the first rear dividing region (132) in the Z direction away from the XY plane is greater than the extension of the second dividing region (142) in the Z direction away from the XY plane.
[0005]
TOOTH according to either of claims 3 or 4, characterized in that, for the first and / or the second rear dividing region (132, 142), each of the pair of dividing side surfaces (134, 144) comprises a more staggered region (134 ', 144'), where a tangent to the lateral surface in the XZ plane forms an angle of more than 45 degrees with the geometric axis X, followed by a smoother region (134 '', 144 '' '), where a tangent to the lateral surface in the XZ plane forms an angle of less than 45 degrees with the geometric axis X, where, preferably for the first and / or second rear dividing region, along a majority of the length of the most staggered region (134 ', 144'), along the X axis, a tangent to the lateral surface in the XZ plane forms an angle of more than 45 degrees and less than 80 degrees, with the X axis in the direction of the geometric axis Z.
[0006]
6. TOOTH, according to any one of claims 1 to 5, characterized in that, at the rear, the first and / or second inner wall (106, 107) exhibits a contour formed by the points (x, z), the contour being it is symmetrical in relation to the geometric axis Z and has a width WI along the geometric axis X, and the contour is defined by the following: in the peripheral parts in abs (x) greater than or equal to 0.9 x WI / 2, one first maximum abs (z) is defined in a pair of points (x1, z1), for abs (x) less than abs (x1): abs (z) decreases until a minimum abs (z) is defined in (x2, z2) , and for abs (x) less than abs (x2): abs (z) increases until a maximum abs (z) is defined in (x3, z3), where abs (z3)> abs (z1)> abs (z2 ), and the pair of the first and / or second rear contact surfaces (130a, b; 140a, b) extends between the points (x1, z1) and (x2, z2), where abs (z3) -abs (z1)> 0.03 x WI, where abs (z3) -abs (z1) <0.6 x W.
[0007]
TOOTH according to any one of claims 1 to 6, characterized in that on the front, the first and / or second inner wall (106, 107) comprise a pair of first and / or second essentially flat front contact surfaces ( 110a, b, 120a, b) which are symmetrical and facing the opposite side in relation to the plane covered by the geometric axes Z and Y, so as to form an angle (delta, epsilon) with the plane covered by the geometric axes X and Y , which is less than 35 degrees.
[0008]
TOOTH according to claim 7, characterized in that at the front there is at least one interconnected part, at least one, preferably both pairs of first or second front contact surfaces (110a, b; 120a, b ) are connected via a first or a second front connection region (113, 123), where the first / second inner wall (106,107) extends in the Z direction along or towards the plane covered by the geometric axes X and Y , preferably wherein said connected part is located closer to the lower end (105) of the cavity than said divided part.
[0009]
9. TOOTH according to any one of claims 1 to 8, characterized in that the second internal wall (107) of the stepped part forms a slope (160a, b) that approaches the plane covered by the geometric axes X and Y while extending in towards the lower wall (105) interconnecting said second rear contact surfaces (140a, b) and said second front contact surface (120a, b).
[0010]
10. A TOOTH according to claim 9, characterized in that said inclination (150a, b; 160a, b) is curved, which preferably forms an S-shape.
[0011]
11. TOOTH according to any one of claims 1 to 10, characterized in that said first and / or second front and rear contact surfaces (110a, b, 130a, b; 120a, b, 140a, b)) are connected to the said slope (150a, b, 160a, b), being arranged in such a way that if they are interconnected through a straight line, such a line would form from an angle of more than 10 degrees, preferably more than 20 degrees with the plane covered by the geometric axes X and Y.
[0012]
12. TOOTH according to any one of claims 9 to 11, characterized by the first and / or second rear dividing region (132,142) and the corresponding intermediate dividing region (152, 162) forming a continuous dividing region, the maximum extent of which in the direction Z distant from the XY plane decreases from a maximum adjacent to the open end (104) of the cavity along the geometric axis Y, towards the lower end of the cavity (105).
[0013]
13. A TOOTH according to any one of claims 1 to 12, characterized in that at least at the rear, the opposite side surfaces (108) comprise opposing rear side contact surfaces, essentially flat (170a, b) and at least at the front, the opposite side surfaces (108) comprise opposite front side contact surfaces, essentially flat (180a, b), the rear side contact surfaces (170a, b) and the front side contact surfaces (180a, b) b) are located in different planes, where preferably all the front lateral contact surfaces (180a, b) are located closer to the plane covered by the geometrical axes Z and Y in relation to all the rear lateral contact surfaces (170a, b ).
[0014]
14. A TOOTH according to claim 13, characterized in that the opposite side surfaces (108) define opposite inclined side surfaces (109) that interconnect the opposite rear side contact surfaces (170) and the front side contact surfaces (180).
[0015]
15. TEETH according to claim 6, characterized in that at least one of (x1, abs (z1)), (x2, abs (z2)) and (x3, abs (z3)) differ between the first inner wall ( 106) and the second inner wall (107).
[0016]
16. ADAPTER (2) FOR ATTACHING A BUCKET TO THE EDGE OF AN OPERATING MACHINE, such as an excavator or loader, the adapter (2) comprising a connecting part (22) for disposal to or in a trough and a part of the tip (203) for disposal in a corresponding cavity of a tooth (1), the part of the tip (203) having a width in a horizontal direction (H) designed to extend along the edge of the trough and having a length which extends in a longitudinal direction (L) from a connecting end (204) adjacent to the connecting part (22) of the adapter to a free end (205) and has an outer wall (202), the outer wall (202 of which ) comprises a first external wall (206) and a second external wall, externally opposite (207), and externally opposite side walls (208), which interconnect said first and second external walls (206, 207), the part of which tip (203) delimits a through hole (209) that extends between said opposite side walls (208), to receive a pin that extends through the tip part (203) for fixing the tooth (1) to the adapter (2), being defined a first geometric axis X that extends through the center of the through hole (209), with a second Y axis extending along the tip part (203) from the connecting end (204) of the tip part towards the free end ( 205) of the tip part, and a third geometric axis Z is orthogonal to said first and second geometric axes X, Y, the three geometric axes X, Y, Z thus forming a system of orthogonal geometric axes which are at an origin, by which each point of the outer wall (202) can be defined by Cartesian coordinates (x, y, z), characterized in that the tip part (203) defines: a rear part (BP) that extends along the Y geometric axis, the rear of which is at least partially located between the plane covered by the geometric axes X and Z and the connecting end (204) of the tip part, a front part (FP) that extends along the geometric axis Y, the front part being located between the plane covered by the geometric axes X and Z and the free end (205) of the tip part (203); and a staggered part (SP) that connects the rear (BP) and the front (FP); at the rear, the first and second outer walls (206, 207) each comprise a pair of essentially flat rear contact surfaces (230a, b; 240a, b), each pair of rear contact surfaces being symmetrical with respect to and facing towards the plane covered by the geometric axes Z and Y, so as to form an angle (beta, gamma) with the plane covered by the geometric axes X and Y, which is less than 35 degrees, with each pair rear contact surfaces (230a, b; 240a, b) is separated by a rear dividing region (232, 242) that extends beyond the pair of first contact surfaces (230a, b) in the Z direction away from the XY plane; at the front, the first and second outer walls (206, 207) each comprise a pair of essentially flat front contact surfaces (210a, b, 220a, b) that are symmetrical with respect to the plane covered by the geometrical axes Z and Y, with all contact surfaces forming an angle (alpha) less than 5 degrees with the geometric axis Y, as seen in any plane parallel to the plane covered by the geometric axes Z and Y, the first and / or second front contact surfaces (210a, b; 220a, b) are located closer to the plane covered by the geometric axes X and Y than the corresponding rear contact surfaces (230a, b, 240a, b) and in the staggered part, a the first and / or second outer wall (206, 207) forms a slope (250a, b), in which at least part of the outer wall approaches the XY plane towards the lower wall (205), which interconnects said first and / or second rear contact surfaces s (230a, b, 240a, b) and the corresponding first and / or second front contact surface (210a, b; 220a, b), in which a first stepped distance (D1) along the geometric axis Z is bridged through the first outer wall (206) along the stepped part (SP), between the first rear contact surfaces and the first front contact surfaces; and where a second stepped distance (D2) along the geometric axis Z is bridged through the second outer wall (207) along the stepped part (SP), between the second rear contact surfaces and the second contact surface forward; where 0 <= D2 <= 0.80 D1.
[0017]
17. ADAPTER according to claim 16, characterized in that each of the pair of first and / or second rear contact surfaces (230a, b; 240a, b) extends at least over a distance along the geometric axis X 0.2 x WI, where WI is the extension of the first / second outer wall (206, 207) along the X geometric axis.
[0018]
18. ADAPTER, according to any one of claims 16 to 17, characterized in that the first and / or second rear dividing region (232, 242) comprise a pair of lateral dividing surfaces (234, 244) that are symmetrical and facing the opposite side in relation to the ZY plane, where the extent of the first and / or second rear dividing region (232, 242) in the Z direction distant from the XY plane is determined by the extent of the corresponding pair of dividing lateral surfaces (234, 244) in the that direction.
[0019]
19. ADAPTER, according to claim 18, characterized in that through a majority of the rear part of the tip part, the extension of the first rear dividing region (232) in the Z direction distant from the XY plane is greater than the extension of the second region rear divider (242) in the Z direction away from the XY plane.
[0020]
20. ADAPTER according to any one of claims 18 to 19, characterized in that, for the first and / or second rear partition region, each of the pair of lateral partition surfaces (234, 244) comprises a more staggered region ( 234 ', 244'), where a tangent to the lateral surface in the XZ plane forms an angle of more than 45 degrees with the geometric axis X, followed by a smoother region (234 ', 244' ''), in which a tangent to the lateral surface in the XZ plane forms an angle of less than 45 degrees with the geometric axis X, where preferably for the first and / or second rear dividing region, over a majority of the length of the most staggered region (234 ', 234 '), along the geometric axis X, a tangent to the lateral surface in the XZ plane forms an angle of more than 45 degrees and less than 80 degrees, with the geometric axis X towards the geometric axis Z.
[0021]
21. ADAPTER, according to any one of claims 16 to 20, characterized in that, at the rear, the first and / or second external wall (206, 207) exhibits a contour formed by the points (x, z), the contour being is symmetrical in relation to the geometric axis Z and has a width WI along the geometric axis X, and the contour is defined by the following: in peripheral parts in abs (x) greater than or equal to 0.9 x WI / 2, one first maximum abs (z) is defined at a pair of points (x1, z1), for abs (x) less than abs (x1): abs (z) decreases to a minimum, abs (z) is defined at a pair of points ( x2, z2), and for abs (x) less than abs (x2): abs (z) increases to a maximum, abs (z) is defined in a pair of points (x3, z3), where abs (z3)> abs (z1)> abs (z2), and the pair of the first and / or second rear contact surface (130a, b; 140a, b) extends between the points (x1, z1) and (x2, z2), where abs (z3) -abs (z1)> 0.03 x WI, preferably where abs (z3) -abs (z1) <0.6 x WI.
[0022]
22. ADAPTER according to any one of claims 16 to 21, characterized in that at the front, the first and / or second outer wall (206.207) comprises a pair of first and / or second essentially flat front contact surfaces (210a, b, 220a, b) that are symmetrical in relation to and facing towards the plane covered by the geometric axes Z and Y, so as to form an angle (delta) with the plane covered by the geometric axes X and Y, which is less than 35 degrees.
[0023]
23. ADAPTER according to any one of claims 16 to 22, characterized in that at the front there is at least one interconnected part, at least one, preferably both pairs of the first or second front contact surfaces (210a, b; 220a, b) are connected via a first or a second front connection region (213, 223), in which the first / second outer wall (206,207) extends in the Z direction along or towards the XY plane, preferably, wherein said connected part is located closer to the free end (205) of the tip part than said divided part.
[0024]
24. ADAPTER according to any one of claims 16 to 23, characterized in that in the staggered part, the first and / or second outer wall (206, 207) merges with the first and / or second rear contact surface (230a , b, 240a, b), the first and / or second rear dividing region (232,242) and with the first and / or second front contact surfaces (210a, b, 230a, b)), which forms the (s) said inclination (s) (250a, b, 260a, b) at least between the first and / or second rear contact surfaces (230a, b; 240a, b) and the first and / or second front contact surfaces (210a, b, 220a, b).
[0025]
25. ADAPTER, according to claim 24, characterized in that said inclination is curved, which preferably forms an S-shape.
[0026]
26. ADAPTER according to any one of claims 16 to 25, characterized in that said first front and rear contact surfaces (210ab, 230ab; 220ab; 240 a, b) are connected via said inclination (250a, b; 260a , b) are arranged in such a way that if they are interconnected through a straight line, such a line would form an angle of more than 10 degrees, preferably more than 20 degrees with the plane covered by the geometric axes X and Y.
[0027]
27. ADAPTER according to any one of claims 24 to 26, characterized by the first and / or second rear dividing region (232), 142) and the corresponding intermediate dividing region (252,262) forming a continuous dividing region whose maximum extension in the direction Z away from the XY plane decreases from a maximum adjacent to the connecting end (204) of the tip part along the geometric axis Y, towards the free end of the tip part (205).
[0028]
28. ADAPTER according to any one of claims 16 to 27, characterized in that at least at the rear, the opposite side surfaces (208) comprise rear, opposite and essentially flat side contact surfaces (270a, b) and at least at at the front, the opposite side surfaces (208) comprise front, opposite and essentially flat side contact surfaces (280a, b), the rear side contact surfaces (270a, b) and the front side contact surfaces (280a, b) b) are located in different planes, preferably where all the front lateral contact surfaces (280a, b) are located closer to the plane covered by the geometrical axes Z and Y than all the rear lateral contact surfaces (270a, b ).
[0029]
29. ADAPTER according to any one of claims 27 to 28, characterized in that the opposing side surfaces (208) define opposed inclined side surfaces (290a, b) that interconnect the opposing rear side contact surfaces (270a, b) and the surfaces contact points (280a, b).
[0030]
30. ADAPTER (2) according to claim 21, characterized in that at least one of (x1, abs (z1)), (x2, abs (z2)) and (x3, abs (z3)) differ between the first outer wall (206) and the second outer wall (207).

类似技术:

---

公开号 | 公开日 | 专利标题

---

BR112016025243B1|2021-02-09|tooth for attachment to the edge of a bucket of an operational machine and adapter for attachment to the edge of a bucket of an operational machine

---

BR112016025268B1|2021-02-09|tooth for attachment to the edge of a bucket of an operational machine, and adapter for attachment of a tooth to the edge of a bucket of an operational machine

---

KR101297529B1|2013-08-14|Wear assembly for excavating machines

---

ES2867551T3|2021-10-20|Wear set

---

RU2652398C2|2018-04-26|Excavator wear assembly

---

RU2622958C1|2017-06-21|Male and female parts of wearing assembly of earthmoving machine bucket

---

BR112016000925B1|2022-02-01|FEMALE PART FOR A WEAR ARRANGEMENT OF AN EARTH MOUNTING MACHINE BUCKET, MALE PART FOR A WEAR ARRANGEMENT OF AN EARTH MOUNTING MACHINE BUCKET AND WEAR ARRANGEMENT

---

KR20000015016U|2000-07-25|Bucket Structure of Excavator

同族专利:

---

公开号 | 公开日

---

US20170067230A1|2017-03-09|

---

IL248583A|2019-03-31|

---

AU2014392256B2|2019-05-09|

---

MY181252A|2020-12-21|

---

EP3137691A1|2017-03-08|

---

BR112016025243A2|2017-08-15|

---

US10294637B2|2019-05-21|

---

ZA201608227B|2018-05-30|

---

RU2652043C1|2018-04-24|

---

ES2687369T3|2018-10-24|

---

AU2014392256A1|2016-12-08|

---

CN106795708B|2021-04-09|

---

AP2016009576A0|2016-11-30|

---

KR20160147866A|2016-12-23|

---

CN106795708A|2017-05-31|

---

NZ726601A|2019-05-31|

---

CA2945618A1|2015-11-05|

---

PT3137691T|2018-10-18|

---

PL3137691T3|2019-02-28|

---

JP6391810B2|2018-09-19|

---

UA116844C2|2018-05-10|

---

CA2945618C|2021-06-01|

---

WO2015165505A1|2015-11-05|

---

MX362678B|2018-10-08|

---

KR102204569B1|2021-01-19|

---

IL248583D0|2016-12-29|

---

EP3137691B1|2018-07-04|

---

JP2017514051A|2017-06-01|

---

MX2016014211A|2017-02-13|

---

PE20161422A1|2017-01-08|

---

CL2016002743A1|2017-01-27|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

---

US2689419A|1950-01-12|1954-09-21|American Brake Shoe Co|Excavating bucket adapter for replaceable tooth points|

---

US3675350A|1970-04-13|1972-07-11|Amsted Ind Inc|Dipper tooth assembly|

---

SU1838524A3|1989-08-04|1993-08-30|Esko Corp|Tooth-fastening unit of working tool of earth-moving machine|

---

DE59400217D1|1993-08-30|1996-05-23|Baz Service Ag|Excavator tooth|

---

US6735890B2|2001-07-06|2004-05-18|Esco Corporation|Wear assembly|

---

JP3827073B2|2001-11-09|2006-09-27|株式会社樋口製作所|Excavation and leveling equipment for buckets in excavator machines for civil engineering|

---

AT448366T|2003-12-05|2009-11-15|Metalogenia Sa|WEAR ASSEMBLY AND COMPONENTS THEREOF, DESIGNED FOR MOVING MATERIALS SUCH AS EARTH AND STONES|

---

MY149408A|2005-08-30|2013-08-30|Esco Corp|Wear assembly for excavating machines|

---

JOP20190303A1|2006-02-17|2017-06-16|Esco Group Llc|Wear assembly|

---

NZ602995A|2006-03-30|2014-01-31|Esco Corp|Wear assembly|

---

CA2551312A1|2006-06-28|2007-12-28|Amsco Cast Products Inc.|Tooth and adaptor assembly|

---

CN200955165Y|2006-09-26|2007-10-03|宁波浙东精密铸造有限公司|Fitting structure of bucket gear and gear seat|

---

KR20100097314A|2009-02-26|2010-09-03|강승호|Bucket for excavator|

---

US7980011B2|2009-03-23|2011-07-19|Black Cat Blades Ltd.|Fully stabilized excavator tooth attachment|

---

US8261472B2|2009-03-23|2012-09-11|Black Cat Blades Ltd.|Retrofitted excavator tooth attachment|

---

MX344454B|2009-03-23|2016-12-16|Black Cat Blades Ltd|Fully stabilized excavator tooth attachment.|

---

CN103781973B|2011-07-05|2017-10-24|麦塔洛吉尼亚股份有限公司|Holding system between holding meanss, female die member and male mold part and the female die member and male mold part for earthmoving machinery|

---

US8943716B2|2011-10-10|2015-02-03|Caterpillar Inc.|Implement tooth assembly with tip and adapter|

---

CN202370031U|2011-11-01|2012-08-08|三一重机有限公司|Bucket tooth of digging bucket and digging bucket|

---

FR2983880B1|2011-12-08|2014-11-21|Afe Metal|MECHANICAL SYSTEM COMPRISING A WEAR PIECE AND A SUPPORT, AND BUCKET COMPRISING AT LEAST ONE SUCH A MECHANICAL SYSTEM|

---

CN102864813B|2012-07-26|2016-12-07|宁波禾顺新材料有限公司|A kind of stable dipper teeth of digging machine, toothholder and assembly thereof|

---

US9534357B2|2013-01-25|2017-01-03|Cqms Pty Ltd|Excavator wear assembly|

---

AU2014392255B2|2014-04-28|2019-01-31|Metalogenia Research & Technologies S.L.|Tooth and adaptor for attachment of the tooth to a working machine|US10508418B2|2016-05-13|2019-12-17|Hensley Industries, Inc.|Stabilizing features in a wear member assembly|

---

SE542369C2|2016-05-23|2020-04-14|Combi Wear Parts Ab|WEAR SYSTEM|

---

USD803275S1|2016-12-15|2017-11-21|Caterpillar Inc.|Tip for a ground engaging machine implement|

---

USD806140S1|2016-12-15|2017-12-26|Caterpillar Inc.|Adapter for a ground engaging machine implement|

---

USD806759S1|2016-12-15|2018-01-02|Caterpillar Inc.|Tip for a ground engaging machine implement|

---

US10480162B2|2016-12-15|2019-11-19|Caterpillar Inc.|Implement ground engaging tip assembly having tip with tapered retention channel|

---

USD805112S1|2016-12-15|2017-12-12|Caterpillar Inc.|Tip for a ground engaging machine implement|

---

USD805562S1|2016-12-15|2017-12-19|Caterpillar Inc.|Adapter for a ground engaging machine implement|

---

USD806758S1|2016-12-15|2018-01-02|Caterpillar Inc.|Tip for a ground engaging machine implement|

---

USD806139S1|2016-12-15|2017-12-26|Caterpillar Inc.|Adapter for a ground engaging machine implement|

---

USD803274S1|2016-12-15|2017-11-21|Caterpillar Inc.|Tip for a ground engaging machine implement|

---

USD803900S1|2016-12-15|2017-11-28|Caterpillar Inc.|Tip for a ground engaging machine implement|

---

USD803898S1|2016-12-15|2017-11-28|Caterpillar Inc.|Tip for a ground engaging machine implement|

---

USD806141S1|2016-12-15|2017-12-26|Caterpillar Inc.|Adapter for a ground engaging machine implement|

---

USD803897S1|2016-12-15|2017-11-28|Caterpillar Inc.|Tip for a ground engaging machine implement|

---

USD803902S1|2016-12-15|2017-11-28|Caterpillar Inc.|Tip for a ground engaging machine implement|

---

USD803899S1|2016-12-15|2017-11-28|Caterpillar Inc.|Tip for a ground engaging machine implement|

---

USD803901S1|2016-12-15|2017-11-28|Caterpillar Inc.|Tip for a ground engaging machine implement|

---

US10494793B2|2016-12-15|2019-12-03|Caterpillar Inc.|Implement tip assembly having tip with support rib|

---

USD806142S1|2016-12-15|2017-12-26|Caterpillar Inc.|Adapter for a ground engaging machine implement|

---

USD840441S1|2016-12-15|2019-02-12|Caterpillar Inc.|Adapter for a ground engaging machine implement|

---

US10480161B2|2016-12-15|2019-11-19|Caterpillar Inc.|Implement tip assembly having tip with wear indicator|

---

KR101817064B1|2017-08-09|2018-01-10|성보공업주식회사|A bucket tooth of excavator|

---

USD832310S1|2017-08-30|2018-10-30|Caterpillar Inc.|Adapter for a ground engaging machine implement|

---

USD905765S1|2019-03-07|2020-12-22|Caterpillar Inc.|Adapter for a ground engaging machine implement|

---

USD888785S1|2019-03-07|2020-06-30|Caterpillar Inc.|Adapter for a ground engaging machine implement|

---

WO2022012819A1|2020-07-17|2022-01-20|Metalogenia Research & Technologies S.L.|Adapter and wear element with a pin arranged at a low stress point|

---

USD945499S1|2020-11-18|2022-03-08|Caterpillar Inc.|Adapter for a ground engaging machine implement|

---

USD945498S1|2020-11-18|2022-03-08|Caterpillar Inc.|Adapter for a ground engaging machine implement|

法律状态:
2020-05-05| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

---

2020-12-08| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

---

2021-02-09| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 29/04/2014, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

---

申请号 | 申请日 | 专利标题

---

EP14382156|2014-04-28|

---

ES14382156.9|2014-04-28|

---

PCT/EP2014/058702|WO2015165505A1|2014-04-28|2014-04-29|Tooth and adaptor for attachment of the tooth to a working machine|

---