wear member for ground coupling equipment

专利摘要:
WEAR RESISTANT MEMBER FOR EARTH COUPLING EQUIPMENT AND LOCK FOR FIXING IT. The present invention relates to wear resistant members (10) for wear resistant assemblies which include a latch (12) configured to secure the wear resistant member to a base, wherein the latch has two engagement positions, viz. : (a) a first position which secures the latch to the wear resistant member, and (b) a second position which secures the wear resistant member to the base. The latches are also configured to be disengaged and removed from the wear resistant member in two stages, a first retraction of the engagement mechanism, followed by a rotation of the latch itself with the removal of the wear resistant member.
公开号:BR112014012274B1
申请号:R112014012274-1
申请日:2012-11-16
公开日:2021-05-18
发明作者:Christopher A. Johnston；Donald M. Conklin；Michael B. Roska；William D. Rossi；Kevin S. Stangeland
申请人:Esco Group Llc；
IPC主号:

专利说明:

Related Patent Application Data
[001] The present patent application claims priority benefits based on U.S. Provisional Patent Application no. 61/563,448, filed November 23, 2011 and entitled "Wear Resistant Assembly," and in U.S. Provisional Patent Application no. 61/720,928, filed October 31, 2012 and entitled "Wear Resistant Assembly". Each such priority request is incorporated herein by reference in its entirety. Description field
[002] The present invention pertains to wear-resistant assemblies for ground coupling equipment, and to wear-resistant members, bases and latches of wear-resistant assemblies. Description Background
[003] Digging equipment, such as digging buckets, mill holders and the like, are used for demolition, mining, earthmoving, and other similarly inhospitable applications. To protect the equipment from wear and/or to enhance the operation of the equipment, wear resistant parts can be attached to the excavating equipment. Such wear-resistant parts can include tips, adapters, skirts, sliders, and more.
[004] Such wear-resistant parts are normally subjected to inhospitable conditions, heavy loads and extreme abrasion. Consequently, wear-resistant parts wear out over time and must be replaced, often in the field and under less than ideal conditions. It is common for a lock to be used to releasably secure a wear member to a base. To do this, the lock must therefore fulfill several seemingly contradictory requirements. The lock must secure the wear member to the base with sufficient strength and stability to prevent failure during operation. At the same time, the lock must facilitate the release and replacement of the wear member by field personnel under field conditions.
[005] Examples of wear resistant parts and their retaining devices are set forth in U.S. Patent Nos. US5709043, US6735890, US6871426, US6986216, US6993861, US7121022, US7367144, and US7882649; and in U.S. Patent Publication no. US20110107624. The presentations of these and all other publications mentioned herein are incorporated by reference in their entirety for all purposes. Description Summary
[006] Aspects of the present invention relate to wear resistant members for wear resistant assemblies for ground coupling equipment. Aspects of the present invention also include a wear member and a latch combined as a single integral component, that is, the wear member includes a wearable body and a latch joined together. Aspects of the present invention also relate to latches, wear resistant members (e.g., spikes, adapters, skirts, etc.) and bases individually.
[007] The locks according to at least some examples of the present invention will have two coupling positions with respect to the wear member: a first coupling position, or transport position, which fixes the lock to the wear member, and a second coupling position, or installed position, which can secure the wear member to a base. A wear member with certain modalities of the lock held in the transport position refers to "ready to install". Such wear member can be installed on a base with the lock still in the transport position. No movement of the lock in transport position is required to start the installation procedure. In addition, the lock does not need to be removed from the wear member to install the wear member to a base or to remove the wear member from a base.
[008] The latches according to examples of the present invention are also configured to be released and removed from the wear member in two stages, including a first stage with the retraction of the engagement mechanism (e.g., at least partially in the latch body ), followed by a second stage with rotation of the lock itself away from the wear member to allow removal of a wear member from a base.
[009] Wear resistant members for ground coupling equipment (e.g., excavating equipment) according to some examples of the present invention include a mounting portion for engaging a base of the equipment (for mounting the wear member on the apparatus), wherein the portion of the assembly having a first leg and a second leg opposite the first leg spaced apart to receive the base. The first leg of this example structure includes a first rail and a second rail that extends back towards a trailing edge of the first leg, each of the first and second rails having an outer side surface to be supported against. to the complementary surfaces on the base. The first and second rails can converge axially in one direction towards the trailing edge. Such wear-resistant members may also include a hole for receiving a latch through one of its legs (eg, between the rails), a latch access recess that extends from the hole to one side of the leg, and, optionally, a latch attached to the hole. Optionally, the latch access recess can extend over one of the rails.
[0010] Wear resistant members (e.g., skirts, tips, adapters, sliders, etc.) in accordance with some aspects of the present invention include a portion of the mount for attaching a base of the equipment to mount the wear member to the equipment . The mounting portion of this exemplary structure has an inner surface that faces the base and an outer surface, and the mounting end defines a latch that receives the area including a hole that extends through the mounting end of the outer surface. to the inner surface. This hole has a back wall with a bracket that projects inward towards the hole for a latch to engage and swing inward to engage the base and to secure the wear member to the equipment and swing out to release the base and allow for release of the wear member from the equipment. The bracket may be located adjacent to the inner surface of the wear member and spaced from its outer surface, and the bracket may extend partially or completely along the rear wall of the hole (the bracket may also extend along the rear wall of the hole by a greater distance than it extends into the hole or away from the back wall). The hole front wall (located opposite the rear wall) of this exemplary structure has an outer portion that extends from the outer surface and an inner portion that forms a pocket (e.g., a cutout) recessed forward in the wear member with respect to the outer portion and extending to the inner surface to receive a latch portion of the latch to retain the latch in the inwardly swinging position. Such wear resistant members may also include a lock coupled with the wear member and, optionally, this wear member and the lock in combination can be mounted to a base of the equipment to provide a wear resistant assembly.
[0011] Wear-resistant members in accordance with at least some examples of the present invention will include a latch access recess on its outer surface that extends away from the latch mounting hole generally in a direction between the front walls and rear of the hole (for example, sideways of the hole). For some wear resistant members the lock access hole and recess may be provided in a side wall of the wear member, and for other wear resistant members the lock access hole and recess may be provided in a wall upper or leg of the wear member.
[0012] Wear resistant members in accordance with still other aspects of the present invention may include a mounting portion for attaching a base of the equipment (to mount the wear member to the equipment), wherein the mounting portion has an inner surface. which faces the base and an opposite outer surface, a hole extending through the mounting portion of the outer surface to the inner surface, and a latch mounted integrally in the hole for movement between a locked position where the latch is positioned to contact the base to secure the wear member to the equipment and to a release position where the lock is positioned to release the base. This exemplary lock has a lock body, a rotary drive member, and a lock member movable between a first position for engaging the wear member for alternatively locking in the locked and released positions, and a second position retracted from the first position. . If desired, at least in some exemplary structures according to the present invention the latch member can engage the wear member even in the second (retracted) position, in particular when the parts are relatively new and/or unworn, by example, so that the latch does not protrude from the wear member. Optionally, such latches may also include a resilient member or other structure to urge the latch member into the first position.
[0013] Additional aspects of the present invention relate to latches for securing a wear member to the equipment (for example, for attaching wear resistant members of the types described above). Such latches may include: a latch body including a front support surface for contacting a base on the equipment and a rear opening recess for receiving supplemental support in a bore of the wear member; an actuating member movably coupled to the latch body; a lock member movably coupled with the drive member and the lock body such that movement of the drive member relative to the lock body moves the lock member between an engaged position wherein a portion of the lock member latch extends outwardly (eg, from one side of the latch body) in a direction to contact the wear member and a disengaged position where the latch member is retracted relative to the engaged position; and, optionally, a pusher member to urge the latch member into the engaged position.
[0014] Latches in accordance with still other aspects of the present invention may include: a latch body having a support surface at one end for contacting the base to secure the wear member to the equipment, and a recess at an opposite end for receiving a support on the wear member around which the latch body will rotate between a locked position in which the support surface contacts the base and a release position in which the support surface will release the base; a lock member movably coupled to the lock body to move between a first position in which the lock member contacts the wear member and a second position in which the lock member is retracted relative to the first position to decouple the wear member; an actuating member rotatably coupled to the latch body and movably coupled to the latch member such that initial rotation of the actuating member moves the latch member relative to the latch body and further rotation of the latch member actuation moves the lock body over the bracket on the wear member; and, optionally, a pusher member, such as a resilient member, to urge the locking member into the first position.
[0015] In the locks of the various types described above, the drive member can rotate in the lock body on a first axis, and the lock member can be pivotable about a second axis between the engaged and disengaged positions. These two axes may be parallel and not aligned in some modes, and they may be non-parallel in other modes. When they are not parallel, the first axis may diverge from the second axis at an angle of 0° to 45° as measured in a plane to which both axes are projected (and in some examples, at an angle of 5° to 35 °). The drive member may have a tool interface and a cam to couple the lock member and the translational movement of the drive member to the lock member to move the lock member between the engaged and disengaged positions.
[0016] The advantages of the latches and wear resistant assemblies of the present invention will be more readily understood after taking into consideration the drawings and the Detailed Description. Brief Description of Drawings
[0017] Fig. 1 is a perspective view of a wear resistant assembly having a wear member and a latch according to an embodiment of the present invention.
[0018] Fig. 2 is a perspective view of the latch of Fig. 1.
[0019] Figs. 3A-3C show the latch of Fig. 1 in perspective, plan, and side elevation views, respectively.
[0020] Fig. 4 is an exploded view of the latch of Fig. 1.
Figs. 5A and 5B are right side and plan perspective views of a lock body for the lock of Fig. 1, where the lock body is semi-transparent.
[0022] Figs. 6A-6C are side elevation, right side perspective, and top perspective views, respectively, of a drive member for the latch of Fig. 1.
[0023] Figs. 7A-7C are left side perspective, right side perspective, and plan views, respectively, of a latch member for the latch of Fig. 1.
[0024] Figs. 8A and 8B are perspective views of the left and right sides of the latch of Fig. 1, respectively, where selected latch components are semi-transparent.
[0025] Fig. 9 is a perspective view of an alternative embodiment of a combined drive member and locking member according to the invention.
[0026] Fig. 10 is a cross-sectional view of the latch and wear member of Fig. 1, in combination with a base, but showing the latch on initial insertion of the latch into the wear member.
[0027] Fig. 11 is a top plan view of the latch of Fig. 10, both after removal of the wear member and before insertion of the latch into the wear member while in an engaged configuration.
[0028] Fig. 11A is a plan view showing a latch according to the alternative embodiment of Fig. 9, with a different cam configuration than that shown in Fig. 11, with both cam configurations of Figs. . 11 and 11A shown in dashed lines.
[0029] Fig. 12 is a partial cross-sectional view of the latch and wear member of Fig. 10, in combination with a base, wherein the latch is in a transport position, with the cross-sectional view taken along the plane indicated by line 12-12 in Fig. 1.
[0030] Fig. 13 is a partial plan view of the latch and wear member of Figs. 10 and 12, in an installed configuration, to completely retain the latch and corresponding wear member in place on the base.
[0031] Fig. 14 is a cross-sectional view of the latch and wear member of Fig. 13.
[0032] Fig. 15 is a partial plan view of the latch and wear member of Fig. 11 in an disengaged configuration, with the retraction of an engagement mechanism, but with the latch in a position that retains the wear member. wear on the base.
[0033] Fig. 16 is a cross-sectional view of the latch and wear member of Fig. 15 along a plane slightly higher than that shown in Fig. 12.
[0034] Fig. 17 is a perspective view of the wear resistant assembly of Fig. 1 adjacent to a base in accordance with an embodiment of the present invention.
[0035] Fig. 18 is a perspective view of the wear member and lock of Fig. 1, showing the lock in the transport position.
[0036] Fig. 19 is a right side elevation view of the wear member and latch of Fig. 1, showing the latch in the installed position.
[0037] Fig. 20 is a perspective view of the wear member and latch of Fig. 1, showing the latch in the installed position.
[0038] Fig. 21 is a perspective view of the wear resistant assembly of Fig. 1, including the wear member and latch of Fig. 2, coupled to a base according to another embodiment of the present invention.
[0039] Fig. 22 is a partial perspective view of the latch of Fig. 1 in the engaged configuration, and in the installed position, in association with the base of Fig. 10.
[0040] Fig. 23 is a partial plan view of the latch and base of Fig. 21 in combination with the wear member of Fig. 10 shown in broken lines.
[0041] Fig. 24 is a partial plan view of the latch of Fig. 22 in the engaged configuration, and in the installed position, in association with the base of Fig. 10.
[0042] Fig. 25 is a partial perspective view of a horizontal section of the latch and wear member of Fig. 1.
Figs. 26A and 26B are perspective views of another exemplary latch in accordance with the present invention in a locked configuration and an unlocked configuration, respectively. Fig. 26C is a top view and Fig. 26D is a side elevation view of this exemplary latch. Fig. 26E illustrates the interaction between the drive member and the latch member of this exemplary latch. Fig. 26F is a bottom view of the actuating member of this exemplary latch. Fig. 26G is an exploded view of this exemplary latch. Fig. 26H is a front elevation view of this exemplary latch.
[0044] Fig. 27 is a perspective view showing the latch of Figs. 26A to 26H mounted on a tip and a base.
[0045] Fig. 28A is a perspective view of a skirt-type wear member coupled with a base using a latch of the type shown in Figs. 26A to 26H. Fig. 28B is a cross-sectional view taken along lines 28B-28B of Fig. 28A. Figs. 28C to 28E show top, cross-sectional and bottom views, respectively, of this exemplary skirt and its latch recess area.
[0046] Fig. 29A is a perspective view of another skirt-type wear member coupled with a base member using a latch of the type shown in Figs. 26A to 26H. Fig. 29B is a cross-sectional view taken along lines 29B-29B of Fig. 29A. Figs. 29C and 29D show top and bottom views, respectively, of this exemplary skirt and its latch recess area and boss engagement area. Figs. 29E and 29F illustrate the coupling of this skirt with another piece of wear resistant assembly. Detailed Description of the Invention
[0047] The present invention relates to a wear resistant assembly for ground coupling equipment. This patent application includes examples of the invention in the form of an excavating tooth and a skirt. However, the invention is not limited to these examples. For example, aspects of the invention can be used with respect to other types of wear resistant parts such as intermediate adapters and sliders. Although the patent application describes wear resistant assemblies in relation to digging buckets, aspects of the invention can be used to attach wear resistant members to other ground coupling equipment such as dredge cutter heads, chutes , truck bodies, etc. The terms "top" and "bottom" are generally considered to be interchangeable, as the tines can typically take on various orientations when attached to earthmoving equipment. The "front" and "back" of wear resistant parts are considered in the context of the principal direction of movement of the earth material relative to the wear resistant part. For example, with respect to a tip of a tooth system, the front is the narrowed edge of the tip, because the main movement of the ground material relative to the tip is from that narrowed edge "backward" to the cavity receiving the based on a common digging operation.
[0048] An exemplary wear resistant assembly 10 in accordance with an embodiment of the present invention is shown in Fig. 1. The wear resistant assembly 10 includes a wear member 12 and a latch 14 associated with the wear member 12. Such as will be discussed in more detail below, latch 14 may be physically coupled to wear member 12, and when so coupled may nest within a recess 16 of the latch which has a shape that is defined by wear member 12 and which is complementary to the shape of the latch 14. This nesting of the latch 14 within the recess 16 of the latch tends to protect the latch against wear.
[0049] In one embodiment of the invention, a wear resistant assembly 10 composed of the wear member 12 and the latch 14 combined can be sold, transported, stored and/or installed as a single unit. In this embodiment, wear member 12 has a working portion 12A in the form of a tapered leading edge 12B for penetrating the earth during excavation, and a mounting portion 12C with a rear opening cavity for receiving a base. Mounting portion 12C has a latch receiving area 16 structured to receive and cooperate with a latch that is adapted to releasably secure the wear member to the base.
[0050] An engagement mechanism holds latch 14 in place within wear member 12 and preferably prevents latch 14 from disengaging from wear member 12 and/or being lost or misplaced during transportation, storage and installation of the wear member 12. In another embodiment of the invention, the use of a single integral wear resistant and locking member also reduces the number of parts to be contained in an inventory. The engagement mechanism holds the latch 14 in place within the wear member 12, allowing transport and storage of the wear member 12, and also to allow the wear member 12 to be installed on a suitable base, preferably without moving. or remove latch 14 first. For example, in some embodiments latch 14 is preferably secured to wear member 12 in a first position so that latch 14 does not obstruct installation of wear member 12 on a base. In other embodiments, or in certain situations where the latch 14 has moved during transport within a recess 16 of the latch, the engagement mechanism allows the latch 14 to move relative to the wear member 12 without falling out of the wear member 12. In these embodiments and situations, latch 14 preferably moves easily relative to wear member 12 during installation on a base.
[0051] When wear member 12 with latch 14 in place is put into operation, latch 14 is installed completely immediately by an additional rotation of a portion of latch 14, as discussed in more detail below, to install completely and retain the latch when 14 and the corresponding wear member 12 in place on the excavating equipment, not shown.
[0052] An exemplary latch 14 is shown in Fig. 2, in Figs. 3A-3C and also in the exploded view in Fig. 4. As can be appreciated from seeing Fig. 4, the latch 14 includes a latch body 18, a drive member 20, a latch member 22, and a body. resilient 24. The resilient body 24 urges the lock member 22 relative to the lock body 18, which tends to hold the lock member 22 in an engaged position.
[0053] In a preferred construction, the lock body 18, which is preferably of unitary construction, provides a support and housing for the drive member 20, a lock member 22, and a resilient body 24 which, when considered in combination, comprise a locking mechanism 26 of the lock 14. The body 18 of the lock is shown in Figs. 5A and 5B, where certain internal structures of the latch body 18 are shown in broken lines.
[0054] As shown in Fig. 4 and Figs. 6A-6C, drive member 20 is received within a corresponding recess 18R in latch body 18. Drive member 20 is generally cylindrical in shape, and configured to rotate in place. An upper surface of drive member 20 may incorporate a tool interface 28 for engaging with an appropriate tool 30 so that drive member 20 can be rotated clockwise or counterclockwise. Typically, tool 30 includes an extended handle, that is, a handle that is of the proper length so that a user can apply sufficient torque to drive member 20 to rotate drive member 20.
[0055] For example, the drive member 20 is shown with a tool interface 28 in the form of a hexagonal socket. The drive member 20, therefore, can be rotated using a tool 30 that incorporates a hex key, as shown in Fig. 1. However, any similarly effective interface can be used to facilitate rotation of the drive member, such as such as a tool interface that has a hex head designed with a tool that incorporates an open-ended hex key or socket, or a hole that opens on one side of the drive member, to receive a rod or a prema, among others. A pair of holes 21 for receiving a tool for turning the drive member 20 on the side of the drive member 20 is shown as dashed lines in Fig. 2. Similarly, other types of tools can be used, such as an impact wrench or other types of rotating devices.
[0056] The head of the drive member 20 preferably includes a tab 32. A visual benefit of the tab 32 is to indicate to a user whether the drive member 20, and therefore the locking mechanism, is in the engaged position, in the disengaged position, or in some intermediate position. When in the orientation shown in Figs. 3A-3C, tab 32 will be on the left or clockwise side of recess 16 of the lock when the lock mechanism is engaged, and tab 32 will be on the right or counterclockwise side of recess 16 of the locks when the lock mechanism is disengaged. Tab 32 also serves to limit the extent of rotation allowed for drive member 20, as tab 32 prevents drive member 20 from being rotated past the point where tab 32 contacts a left detent 34 or a retainer 35 defined by the body 18 of the latch. When the lock mechanism is in an engaged configuration, the actuation member 20 is rotated clockwise (as viewed from above) until the tab 32 is supported against (or immediately adjacent to) the left detent 34. In this position, the locking member 22 is supported against (or immediately adjacent to) the left detent 44.
[0057] Applying an additional torque to the drive member 20, when the tab 32 has come into contact with the left retainer 34 or the right retainer 35 (or through other parts of the lock), transfers that torque to the body 18 of the hangs. This transferred torque can create a rotation of the lock body 18 relative to the wear member 12. For example, the clockwise movement of a tool 30 will rotate the drive member 20 clockwise, and then pivot the body 18 of the lock clockwise to move lock 14 to an installed position. Counterclockwise movement of a tool 30 will rotate drive member 20 counterclockwise, and then rotate lock body 18 counterclockwise so that lock 14 is removed in two stages. As described in more detail below, these two phases include: (1) the rotation of the drive member 20 about a drive rotation axis (axis A) to cause a first retraction of the engagement mechanism while the engagement mechanism hitch rotates around an axis of rotation of the hitch (axis B), followed (2) by a rotation of the latch 14 itself generally around an axis of rotation of the interlock (axis C) - although the movement of the body 18 of the lock is preferably not strictly a pivot movement.
[0058] Two-stage lock disengagement is believed to be particularly useful when the engagement mechanism has been contaminated with boulders and fines (for example, dirt and other debris that penetrate the lock 14 and the lock recess 16 during the use of the equipment). In particular, a substantial portion (i.e., the initial portion) of rotation in a counterclockwise rotation only results in the retraction of the engagement mechanism, so that a substantial leverage is created on very little movement of the mechanism. of coupling. It is believed that this tends to release or break up fines that may have compacted and solidified within the coupling mechanism during use in extreme conditions. Once the first phase of rotation is completed, with the initial breakage or loosening of any fines, an additional rotation results in the movement of the entire lock.
[0059] The underside of the drive member 20 includes a cam 36, which protrudes downward from the underside of the drive member, and travels from a drive rotation axis A of the drive member 20 ( see Figs 2 and 4). Bounce action of cam 36 is provided by displacement of cam 36 relative to axis of rotation A of drive member 20. Displaced cam 36 can be useful in removing any boulders or fines accumulated from the locking mechanism while the member is moving. drive 20 is rotated. Other embodiments, not shown, may include a cam recessed to or projecting from other surfaces of the drive member.
The cam 36 preferably includes a planar underside 37. The cam 36 may also include a flange 38 that protrudes horizontally from the lower edge of the cam 36. Although the shape and surface formation of the cam may vary, the cam 36 is preferably (mostly) circular in cross section, as is flange 38. Where displacement of cam 36 must otherwise result in the projection of flange 38 beyond the circumference of the cylinder of drive member 20, that portion of the flange 38 is truncated to substantially align with and match the curvature of drive member 20, resulting in cam edge surface 42. Cam 36 may also be roughly D-shaped or hemi-cylindrical in shape (eg, with a flattened edge) in some constructions.
[0061] When the tab 32 of the drive member 20 is moved between the limits defined by the left detent 34 and the right detent 35, the cam 36 of the drive member acts on the locking member 22 to pivot the locking member about of the engagement rotation axis B between an engaged configuration and an disengaged configuration.
[0062] In the engaged configuration shown in Fig. 2, with the tab 32 against the detent 34, the latch member 22 is forced by the resilient body 24 against a wall 44 of the left latch detent in the latch body 18, best shown in Fig. 4. Latch 22 can be stopped by coupling with cam 36 and not by wall 44 of the retainer. A wall 46 of the left latch detent is also shown in Fig. 4, but this need not function as a detent as movement may be caused by contact of tab 32 against detent 35 or by full compression of resilient body 24 By rotating the drive member 20 counterclockwise, the cam 36 forces the lock member 22 against the resilient body 24, and thereby rotates the lock member 22 about the engagement shaft B, which is displaced. of the drive rotation axis A. Continued rotation of the drive member 20 will continue to rotate the locking member 22 about the engagement axis B, with an accompanying compression of the resilient body 24, until the drive member flap 32 20 contact detent 35 (see Fig. 4).
[0063] In a preferred construction, hitch 22 tapers to a tapered rounded end 22A (Figs. 7A-7C) which fits into a complementary notch 18N (Fig. 5B) to form a fulcrum or pivot bracket. The lock member 22 may optionally include a vertically oriented through hole through which a pin may pass which serves to anchor the lock member 22 to lock the body 18. Where such a pin is present, the pin is preferably coincident with the axis. of rotation of the hitch B and serves as a pivot point for the locking member 22. Other structures may also be used to ensure and facilitate the rotation of the locking member 22 about the axis of rotation of the hitch B.
[0064] As shown in Figs. 7A-7C, the locking member 22 includes a planar surface 47 that faces the lower cam face 37 of the cam 36. The planar surface 47 is bounded on one side by a side wall 48 (optionally a vertical wall), at that sidewall 48 is configured to be pushed by cam 36. Latch 14 may incorporate one or more elements to help retain drive member 20. Drive member 20 should be swivelable, but drive member 20 should not be removable, separate from latch 14. For example, cam 36 may include a flange 38, and sidewall 48 may include a top shelf 49 defining a horizontal channel 50 along sidewall 48. Horizontal channel 50 may be configured to mate with flange 38 of cam 36 so that drive member 20 is retained in latch 14 and prevented from moving in the vertical direction (i.e., on account of the bias of resilient body 24). Other methods of retention for the various elements can be used, but are not shown, such as a cylinder pin or a spring pin forced through one or more holes in the locking member 22 that can interface with a portion of the body 18 or a cylinder lock pin that runs through the lock body 18 that can interface with a groove in the drive member 20.
[0065] Figs. 8A and 8B show drive member 20, lock member 22, and resilient body 24 mounted within lock body 18. Referring collectively to Figs. 6B, 7A, 8A and 8B, bottom face 37 of cam 36 is adjacent planar surface 47, and flange 38 of cam 36 engages horizontal channel 50, if present.
[0066] In an alternative embodiment, shown in Fig. 9, a drive member 51 may include the cam 52 which shares an axis of rotation of the drive member 51, where the cam 52 has a substantially hemicylindrical cross section. The locking mechanism is configured so that the resulting smooth vertical cam face 52f of cam 52 (see Fig. 11A) contacts a vertical wall 53 of a locking member 54. As in the preceding embodiment, rotation of the drive member 51 results in the cam 54 forcing the locking member 52 against a resilient body (e.g., body 24).
[0067] Turning attention to Figs. 7A-7C, lock member 22 includes a mating surface 55 and a tooth 56, with lock member 22 configured so that when lock member 22 contacts or is adjacent to wall 44 of the retainer. of left engagement, both engagement surface 55 and engagement tooth 56 extend outwardly (e.g. from one side of latch body 18) in a direction to contact a wear member, as shown in Figs. 2 and 3A. However, with the rotation of the drive member 20 about 75 degrees in a counterclockwise direction about the drive rotation axis A (when using an appropriate tool 30), the eccentric rotation of the offset cam 36 results in the cam 36 forcing engagement member 22 inwardly against resilient body 24, thereby compressing resilient body 24 and simultaneously retracting engagement surface 55 and engagement tooth 56 inwardly toward latch body 18 (at least sufficiently retracted from its external extension to allow the desired operations).
[0068] The resilient body 24 is typically flexing sufficiently to allow the latch member 22 to be compressed against the resilient body when the drive member 20 is rotated in the disengaged configuration. However, resilient body 24 can be selected to have more or less degrees of resilience, such that even when drive member 20 remains in the engaged configuration, when latch body 18 is forced into position. in the lock recess 16 the lock member 22 is compressed against the resilient body 24. In this way, the lock body 18 can be forced into position in the lock recess 16 of the wear member 12 lock while the lock 14 remains engaged, for example, by pivoting latch 14 into position with tool 30.
[0069] For example, when a new wear member 12 is ready for transport, a new latch 14 can be placed in the recess 16 of the latch, as shown in Fig. 10. A tool 30 of the type shown in Fig. 1 is then placed on the tool interface 28, and rotated clockwise as indicated in Fig. 11 by an arcuate arrow. This forces latch 14 into a first position after the release position, as shown in Fig. 12. Latch 22 retracts against resilient body 24 when latch 14 is moved from the uninstalled condition (and through the installation position shown in Fig. 10) to the first installed position or home position. The latch 14 will then be securely retained within the wear member 12 in that position for transport and/or storage. More specifically, resilient body 24 exerts sufficient force on latch member 22 such that when latch 14 is in the first position, it is difficult to move latch 14 relative to wear member 12; that is, latch 22 is pressed against corner surface 65 of bracket 64 to resist inward movement of latch 14, and tooth 56 presses against curve 71 of recess to resist outward movement of latch 14. 14 is typically not moved without the use of an appropriate tool or other significant external force.
[0070] Furthermore, the presence of the latch 14 in the first position does not interfere with the installation of the wear member 12 on a suitable base. It should be noted that such base 58 is shown in Fig. 10. However, base 58 is not required in order to place or hold latch 14 in the first position, and is shown in Fig. 10 for reference purposes elsewhere. of this description.
[0071] Latch 14 is configured to secure a wear member 12 to a base 58 when latch 14 is pivoted from the first position or release position of Fig. 12 to the second position or locked position, as shown in Figs. 13 and 14. The base 58 may be an integral part of a piece of excavating equipment (or other ground coupling equipment), or the base 58 may be attached to such equipment (e.g., an adapter), such as such as by soldering or another mechanical fastening. A suitable base 58 is generally formed to accept wear member 12 securely, and includes an opening or notch 60 that is sized and adapted to receive at least a portion of the latch body 18 when the latch is moved to the second. locked position or position (eg when the lock body is fully inserted into the lock recess 16).
[0072] The latch 14 preferably includes a coupling structure or anchor element 62 that is configured to cooperate with a complementary support element 64 formed in the proximal wall of the recess 16 of the latch. Anchor 62 and bracket 64 are configured so that latch 14 can be seated by the interaction of anchor 62 with complementary bracket 64, and latch 14 then can be swung into recess 16 of the latch generally about the axis of locking rotation C (shown in Fig. 2) in order to move the lock body 18 into the base notch 60, as best shown in Fig. 14. Anchor 62 and bracket 64 are preferably configured to facilitate a rotation of latch 14 about axis C. For example, in one embodiment of the invention as shown, anchor 62 corresponds to a notch that interacts with a bracket 64 that corresponds to a vertical ridge formed in the proximal wall of recess 16 of the latch. (See Figures 10 and 12). Although not preferable, the notch can be formed on the wear member and on the ridge on the lock.
[0073] When correctly positioned, a front or distal face 66 of the latch body 18 opposes a complementary resistant surface 68 of the opening 60, and a force that should otherwise force the wear member 12 outward and remove the even the base 58 results in a contact between the distal face 66 and the resistant surface 68, effectively locking the wear member 12 in place on the base 58. At the same time, the latch body 18 is retained in the latch recess 16 by the contact. between the mating surface 55 and the shoulder 70 of the latch recess 16, as shown in Fig. 14. The geometry of the latch 14 and the latch recess 16, and more specifically the latch body 18 and latch member 22 with respect to bracket 64 and shoulder 70, it is such that latch 14 tends to self-connect. The only way for latch 14 to move past both bracket 64 and shoulder 70 is for latch member 22 to be rotated counterclockwise so latch 14 can pivot out of recess 16. Any pivoting latch 14 prior to counterclockwise rotation of the lock member 22 tends to pull the lock member 22 further away from the disengaged position, rather than pushing the lock member 22 into an disengaged position. This makes latch 14 a particularly reliable latch, even when subjected to extreme stresses under load.
[0074] In a particular embodiment of the invention, the geometries of the latch 14 and the wear member 12 are selected so that if a force is applied to the latch 14 it must otherwise force the latch out of the wear member 12 (e.g., movement of wear member 12 under load, presence of fines, etc.), the conformation of support 64 forces latch 14 forward into the latch recess, in turn enhancing the coupling between the surface. of coupling 55 and shoulder 70. That is, the presence of bracket 64 functions to contain latch 14 in the installed position. Any forward movement of latch 14 (i.e., with notch 62 being pulled from bracket 64) is counteracted by distal face 66 abutting resistant surface 68. Any outward movement of latch 14 is countered by latch member 22, which it is in an over-center position to resist decoupling (see Fig. 16). The notch 62 and support 64 also cooperate to resist twisting of the latch 14. In the transport position, the latch 14 is also urged against outward movement by the ridge 64 which is received in the notch 62, the latch tooth 56 abuts. to the curve 71 of the recess, and the front wall 57 of the latch member 22 is pressed against the front wall 59 of the recess 16 of the latch. The twist of the latch 14 in this position is counteracted by the ridge 64 in the notch 62, and by the close proximity of the marginal walls of the recess 16 of the latch and the latch 14. In both positions, the cooperative structures create a situation where the latch 14 is compelled at both the proximal and distal ends by wear member 12 through element 64 and shoulder 70, and any movement of latch 14 that should decrease interaction with one of element 64 and shoulder 70 necessarily enhances interaction with the other .
[0075] Although latch 14 securely retains wear member 12 in position, even after extensive use, latch 14 can be removed immediately despite the presence of sand, boulders or other fines within the latch mechanism or compacted around the lock to facilitate removal and replacement of the wear member 12. Removal of the lock 14 is done by the first movable tool 30 counterclockwise through about 75 degrees, as shown in dashed lines in Fig. 15. During this first phase of movement, drive member 20 is rotated until tab 32 contacts right detent 35. Such rotation causes cam 36 to force locking member 22 against resilient body 24 and simultaneously retracts engagement surface 55 and latch tooth 56 inwardly toward latch body 18, as shown in Fig. 16, converting latch 14 from an engaged configuration to an disengaged configuration.
[0076] Although the mating surface 55 and the hitch 56 are no longer securing the latch 14 within the recess 16 of the latch, the latch 14 can still resist removal due to the presence of gravel or other fines that may have accumulated in and around latch 14. However, with the application of additional force to tool 30, the entire latch 14 can be pivoted back to the first position or release position within latch recess 16, as discussed above with respect to Fig. 12, by pivoting the lock body 18 counterclockwise about an approximate locking rotation axis C, generally defined by the interaction of the anchor element 62 with the support 64 (see Figs. 2 and 4 for the approximate location of the C-axis). This second phase of movement results in movement of the tool by about an additional 30 degrees, as shown in dashed lines in Fig. 10, for a total rotation of the tool 30, through the two phases, of about 105 degrees, along with a translation of tool 30. Latch 14 can alternatively be rotated further and simply removed from wear member 12, if desired (at least for wear resistant members with significant wear). Furthermore, depending on the strength of the resilient body 24, movement of the latch body 18 may occur before the detent 35 contacts the tab 32.
[0077] Returning attention to Fig. 4, it should be noted that the locking rotation axis C is substantially displaced from both the drive rotation axis A and the clutch rotation axis B. In addition, the precise position of the lock rotation axis C may differ during lock installation versus lock removal, depending on the particular configuration of anchor element 62, bracket 64, or both. Rotation axis C can also move dynamically during installation and/or removal operations. In the illustrated example, latch 14 is initially placed at an angle against wear member 12 with anchor 62 partially placed on bracket 64. While the front portion of latch 14 is swung to wear member 12, the inner wall that defines the anchor notch 62 tends to slide along the inwardly facing surface of the bracket 64. When the latch 14 is removed, the outer wall defining the anchor notch 62 is forced into the corner 65 of the latch recess 16 to act as a a fulcrum for swinging the latch 14 outwards. Using a different rotation axis for installation and removal facilitates lock removal when impacted fines are present.
[0078] In an alternative embodiment shown in Fig. 11A, an analogous latch may be employed that incorporates the drive member 51 and the latch member 54 of Fig. 9.
[0079] As discussed previously, the locking member 22 can be compressed by compressing the resilient body 24, even when the drive member 20 is in the engaged position. While the latch is pivoted to the first position, the latch tooth 56 is compressed and slides into the latch recess while the mating surface 55 remains on the outside of the latch recess 16 as shown in Fig. 12. With the latch 14 in the first position, the latch 14 is secured to the wear member 12, as the contact between the latch tooth 56 and the detent 71 of the recess prevents the latch 14 from coming out of the recess 16 of the latch. That is, the latch 14 is prevented from pivoting further into the latch recess 16 by the mating surface 55 against the face 59 of the wear member 12, and yet it is also prevented from rotating completely out of the latch recess 16 through tooth 56. The first latch position 14 is therefore well suited for transporting the wear member with the integral latch, or else for installing the wear member with the integral latch.
[0080] Since the resilient body 24 of the latch 14 allows movement and return of the latch member 22, the latch 14 can be forced into the first position while in an engaged configuration by pivoting the engaged latch 14 to the first position with an appropriate tool 30 or, for example, by a carefully applied hammer blow or a pry bar movement. Similarly, the latch 14 can be forced from the first position to a second position with an appropriate tool 30, a carefully applied hammer blow or a pry bar movement. This can be particularly beneficial when a booster tool is not readily available, as it might be in the field.
[0081] In one embodiment of the invention, the wear resistant assembly 10, which is a wear member 12 and the lock 14 combined, can be sold and/or transported with the lock 14 fixed to the wear member in the first position or position of transport, which prevents the latch 14 from being lost or misplaced, and which is immediately installed entirely by an additional rotation of the latch 14 to compress the latch member 22 and force the coupling surface 55 beyond the proximal wall 70, and fully engages latch 14 in the second position or installed position. Latch 14 may be in the second position for transport and/or storage, but is preferably held in the first position so that no adjustment of latch 14 is required to place wear member 12 on base 58.
[0082] As discussed above to force the latch 14 into the first position or transport position, the latch 14 may be forced further into the installed position by an appropriate tool 30, or by other means. Although latch 14 is preferably combined with wear member 12 prior to transport, storage and installation of wear member 12, latch 14 may alternatively be kept separate and be installed only after wear member 12 has been removed. placed on a base.
[0083] As mentioned above, the wear member 12 and the latch 14 of the present invention can be advantageously carried together when the latch 14 is in the first position. In addition, the latch 14 design is fully integrated and does not require any special tools. To remove a wear member, the construction of the latch 14 allows a first rotary input to first retract the latch 22 about an axis of rotation to engage B, and a further rotational inlet transfers the momentum to a different axis of rotation ( for example, axis C) and facilitates the release and/or removal of latch 14. Engagement tooth 56 is configured so that it will engage the proximal wall of the latch recess and retain latch 14 in the first position or position of transport, provided the tooth 56 and the proximal wall exist and have not been frayed.
Figs. 12 and 18 show the wear resistant assembly 10 of Fig. 1 in the first position, where the engaged latch 14 is partially inserted into the latch recess so that it is retained by the front face 57 of the latch member 22 and the tooth 56 of the latch. locks, whereas Figs. 19 and 20 show latch 14 inserted into the latch recess of wear member 12 and engaged in the installed position. Fig. 21 shows the wear member 12 with the latch 14 in the installed position in an exemplary embodiment of a base, in the form of an adapter 72, to form a wear resistant assembly 73. The movement of the latch 14 (and in particular of the lock body 18) with respect to the wear member 12 can be facilitated, at least in some examples of the present invention, by the interaction of the surface 90 of the lock body 18 (Fig. 3C) with the surface 92 of the wear member 12 (Fig. 1) (for example, surface 92 of wear member 12 can support surface 90 of lock body 18 during sliding and rotational movement of lock body 18 with respect to wear member 12).
[0085] For purposes of illustration, Fig. 22 shows latch 14 in the second position or installed position in combination with base 58 and in the absence of wear member 12. In comparison, Fig. 23 shows latch 14 in second installed position or position in combination with base 58, with wear member 12 shown in broken lines. Fig. 24 shows latch 14 in the installed position in combination with base 58. Fig. 25 shows a cross-sectional view of the combination of latch 14 with wear member 12.
[0086] A single latch 14 is preferably used to secure the wear member to the base. However, a pair of latches (eg one on each side) can be used, which can be beneficial for larger components such as intermediate adapters.
Figs. 26A through 26H illustrate various views of another exemplary latch 114 in accordance with the present invention. Similar reference numbers are used in Figs. 26A to 26H as used in the preceding figures to refer to identical or similar elements, but in Figs. 26A to 26H, the "100 series" is used (for example, if an element with the reference number "XX" is used in Figs. 1-25, an identical or similar element can be shown in Figs. 26A to 26H by reference number "1XX"). Detailed description of these identical or similar elements may be omitted, abbreviated or shortened at least a little in order to avoid excessive repetition. The latch 114 of Figs. 26A to 26H operates in a similar manner to latch 14 of Figs. 1 to 25, including the "two-phase" rotary installation and removal element, but its structure is somewhat different, as will be described in more detail below.
[0088] Figs. 26A and 26B show perspective views of the latch 114 in the locked (Fig. 26A) and unlocked (Fig. 26B) conditions. Fig. 26C is a plan view and Fig. 26D is a side elevation view of latch 114. Fig. 26E shows actuating member 120 coupled with latch member 122 without latch body 118 present. Fig. 26F shows a bottom view of drive member 120, including a view of cam 136 and its flattened side surface 142. Fig. 26G is an exploded view of latch 114 showing the various component parts. Fig. 26H is a front elevation view of latch 114.
[0089] A difference between the latch 114 of Figs. 26A to 26H and latch 14 described above refer to the structure and arrangement of drive member 120. Figs. 2 and 4 show the drive rotation axis A, the engagement rotation axis B and the locking rotation axis C of the latch 14 as being parallel or substantially parallel (e.g., vertical in the illustrated orientations). This is not a requirement. On the other hand, in the latch 114 shown in Fig. 26D, the driver 120 is oriented at an angle with respect to the vertical (in the illustrated orientation) such that the drive rotation axis A is angled with respect to the rotation axis of clutch B and/or to the locking rotation axis C. Although this angle can take on a variety of different values, in some examples of the present invention the angle α between the drive axis A and the clutch axis B will be in a range from 0° to 45° as measured on a plane to which both axes are projected (eg as shown in Fig. 26D), and in some examples from 2° to 40°, from 5° to 35°, from 8° to 30°, or even from 10° to 30°. Similarly, in this illustrated example, the angle between drive shaft A and lock shaft C will be in a range of 0° to 45° as measured on a plane to which both axes are projected (eg such as shown in Fig. 26D), and in some examples 2° to 40°, 5° to 35°, 8° to 30°, or even 10° to 30°. In the example latch 14 of Figs. 1 to 25, the angle α between axes A and B and axes A and C was at or about 0°. For a specific example of an angle lock in accordance with this aspect of the invention, the lock 114 of Figs. 26A to 26H will have an angle α of about 15° (eg for use with the skirt of Figs. 28A to 28E), and in another exemplary structure the angle α is about 30° (eg. for the skirt of Figs 29A to 29F). As also shown in Fig. 26D, angle α is oriented such that axis A extends away from and out of latch 114 (and also in a direction away from a wear member 112 to which it is attached. (see Fig. 27)) while moving up from area 128 of the tool interface.
[0090] Fig. 26D shows a front view of latch 114 taken in perspective from a plane parallel to axes B and C and parallel with a plane of the flattened side surface 142 of cam 136 (described in more detail below). Fig. 26H shows a side view of latch 114 taken from a viewing point oriented 90° from the viewing point of Fig. 26D (ie, from the perspective of a plane parallel to axes B and C and perpendicular to the surface plane flattened side 142 of cam 136). From this orientation, drive axis A is oriented at an angle Y with respect to axes B and C (which are vertical in this view). Although this angle can take on a variety of different values, in some examples of the present invention the angle y between the drive axis A and the engagement axis B (and the locking axis C) will be in a range of 0° to 15 ° as measured on a plane to which both axes are projected (eg as shown in Fig. 26H), and in some examples from 0.5° to 12°, 1° to 10°, or even from 1.5° to 8°. In the example latch 14 of Figs. 1 to 25, the angle α between the A and B axes and the A and C axes of this viewing point is at or about 0°. For some specific examples of an angled latch in accordance with this aspect of the invention, latch 114 of Figs. 26A to 26H will have a Y angle of about 5°. As also shown in Fig. 26H, angle Y orients axis A so as to extend to axis C (and also in a direction to anchor element 162) and away from axis B as it moves up to from area 128 of the tool interface; that is, the shaft for the drive member is angled outward and backward. This y-angle characteristic of axis A helps to keep the passage of movement of cam 136 more direct and/or more level with respect to latch 122 during rotation of latch 114 about drive axis A as compared to the member of drive that has just been tilted out.
[0091] Other structure changes are provided in latch 114 compared to latch 14, for example, at least in part to accommodate the orientation of drive shaft A at a more pronounced angle relative to the other axes B and C. For example , as best shown in Figs. 26C and 26D, the upper surface of the lock body 118 includes an angled portion 118A in the area including the recess into which the actuating member 120 is inserted (the upper surface of the lock body 18 was flat or substantially smooth, for example, as shown in Figs 3A and 3C). This feature highlights some potential advantages of this exemplary locking structure 114. For example, due to the fact that drive shaft A extends outward and away from latch 114 and away from wear member 112 to which it is attached, drive tool shaft 130 will also extend outward and away from latch 114 and away from wear member 112 when it is coupled with tool interface 128. This angulation can provide more space for the operator when coupling tool 130 with latch 114 and more room to rotate tool 130 to secure or release the wear member 112 from the base 158.
[0092] Furthermore, the angulation feature allows some changes to be made in the recess 116 of the wear member lock 112. This can be seen, for example, in a comparison of Figs. 1 and 27. In the example of Fig. 1, tool 30 couples tool interface 28 in a substantially vertical direction (in the illustrated orientation). Therefore, in this arrangement, the inner rear wall 16B in the upper portion 16A of the latch recess 16 extends more vertically towards the wear member 12 (or even angled within the wear member 12) based on the orientation shown in Fig. 1 (and thereby extends further to the side edge of the wear member 12 in the side-by-side direction D). In other words, the inner rear wall 16B extends in a direction substantially parallel to a vertical plane that runs through a centerline of the wear member 12 (based on the orientation shown in Fig. 1), or even angled to inward to the centerline of the wear member 12. In some structures, to provide sufficient tool access, the inner back wall 16B may be angled to extend 10°-30° to the side (and to the line central) of the wear member 12.
[0093] With the angling of a portion of the upper surface 118A of the latch body 118, however, the latch recess 116 need not extend as deeply into the wear member 112 in the direction of from side to side D, such as shown by the position of the upper portion 116A of the latch recess 116 in Fig. 27. Therefore, in this exemplary structure, the inner back wall 116B at the upper portion 116A of the latch recess 116 extends in a non-vertical direction (based on the orientation shown in Fig. 27). In other words, the inner rear wall 116B extends in an outwardly angled direction with respect to a vertical plane that runs through a centerline of the wear member 112 (based on the orientation shown in Fig. 27) and/or in a direction away from this centerline. This angle can be within the ranges described for angle α above. This angulation of the tool 130 entry area of the lock recess 116 allows additional wear member material and thickness to be provided in the lock position, which can lead to longer wear member life and/or reduced failures.
[0094] The angulation characteristic of the drive member 120 also leads to changes in other parts of this exemplary latch structure 114. Actuator 120 includes tab 132 extending laterally from an upper surface thereof and a cam 136 extending downward from a lower surface thereof. Cam 136 includes a bottom face 137 and a flange 138. Although the bottom face 137 and the top surface of the flange 138 (which engages latch 122, as discussed below) may be parallel to each other, this is not a requirement. . For example, the upper surface of flange 138 may slope upward towards the top of actuator 122 while the upper surface extends from its outer side edge to its center, for example, at an angle of up to 5°, if desired. One side of bottom face 137 includes a flattened side edge 142 to produce a substantially hemi-circular shaped bottom face 137. As shown in Figs. 26D and 26E, the lower cam face 137 and the upper surface 138A of the flange 138 of this exemplary structure 120 may be parallel or substantially parallel to an upper surface 120A of the actuator (and perpendicular or substantially perpendicular to the drive axis A). Therefore, the lower face 137 and the upper surface 138A are oriented at a non-perpendicular angle with respect to the engagement axis B and the locking axis C.
[0095] The locking member 122 includes changes in various surfaces to accommodate the structural changes in the drive member 120. Like the locking member 22, the locking member 122 includes a detent 156 and other detents that operate from in an identical or similar manner to those of the locking member 22 described above. The coupling characteristics of the cam 136 of the locking member 122, however, differ somewhat from those of the locking member 22. For example, as shown in Figs. 26D, 26E and 26G, locking member 122 includes a base surface 147, a sidewall 148 (e.g., vertical or substantially vertical) extending from the base surface 147, and an upper shelf 149 extending over the sidewall. 148 to define a channel 150. The channel 150 extends from the base surface 147, along the wall 148, and terminates in the angled top wall 151. The angle of the top wall 151 of the channel 150 with respect to the top shelf 149 (angle β ) (and/or with respect to a plane perpendicular to axis B and/or C) may be within the ranges described for angle α above.
[0096] In use, with the actuator 120 in the locked position (for example, in Fig. 26A), the flattened side edge 142 of the cam 136 is received within the groove 150 defined in the locking member 122 (and, optionally, the edge planed side 142 may contact or be closely adjacent to wall 148 in groove 150). In this position, the actuator 120 is held in place with respect to the latch body 118 by: (a) contact between the upper surface 138A of the flange 138 and the underside of the upper wall 151 and/or (b) contact between the top 138A of the flange 138 and the ferrule or pendant area 118B of the body 118 of the latch. The lock mechanism 122 is also held in place with respect to the lock body 118 (and prevented from being laterally ejected therefrom) in this position by contact between the side edge 180 of the lock mechanism 122 and an overhanging portion 118C of the body 118 of the hangs. When actuator 120 is rotated to the unlocked position (for example, in Fig. 26B), the rounded portion 142A of the cam flange 138 rotates to the groove 150 (below the top wall 151) to push the member counterclockwise. of latch 122 (when viewed from above) and against resilient body 124. A notch 118D in the far right edge of pendant portion 118C is provided to allow initial insertion of latch member 122 into latch body 118 (i.e., to allow clearance to side edge 180 and top shelf 149).
[0097] Fig. 26G shows more details regarding the interior of the recess of the lock body 118 in which the lock member 122 and the resilient member 124 are received. More specifically, as shown in Fig. 26G, the inner recess of this exemplary structure includes a support member 182 for supporting the resilient member 124 (which may be formed of a rubber material, such as vulcanized rubber). Resilient member 124 can be formed separately and coupled with that support member 182, or it can be formed in place (e.g., by introducing a flowable polymer material into the recess after drive member 120 and locking member 122 are in place. into place within the recess and moved to the locked position (eg as shown in Fig. 26A) and then the polymer material is hardened in place). In either way, support member 182 helps to hold resilient member 124 within recess of latch body 118. Aperture 124A is shown in Fig. 26G to illustrate where support member 182 engages resilient member 124. More support members, at different locations, can be provided, if desired, without deviating from the invention. Alternatively, if desired, support member 182 can be omitted (and resilient member 124 can be held in place by a friction fit, by expanding behind the edges of the wall, etc.). As another option, if desired, resilient member 124 can be held in place, at least in part, by an adhesive.
[0098] This lock 114 can be mounted to a wear member 112 (eg, a point) and/or be locked to a base member 158 in the same manner as described above for the lock 14. More specifically, the lock 114 it can be mounted on a wear member 112 for transportation, storage and installation, and/or be coupled with a wear member 112 and a base member 158 in a locking manner. Figs. 26A to 26C show an anchor element 162 in the body 118 of the lock which can engage a support such as support 64 provided on a wear member 12 in the manner described above. Latch body 118 includes elements (e.g., support surface 166) for engaging with corresponding elements or for supporting surfaces on wear member 112 and/or base member 158 in the manner described above. Lock member 122 includes elements (e.g., dog tooth 156 and various support surfaces) for engaging with corresponding elements or for supporting surfaces on wear member 112 in the manner described above.
[0099] As described above, Fig. 27 illustrates the latch 114 of this example of the invention coupled with a point-type wear member 112. In use, movement of latch 114 (and in particular latch body 118) with respect to wear member 112 may be facilitated, at least in some examples of the present invention, by the interaction of surface 190 of latch body 118 (Figs. 26G and 26H) with surface 192 of wear member 112 (Fig. 27) (for example, surface 192 of wear member 112 can support surface 190 of latch body 118 during sliding and rotational movement of the lock body 118 with respect to wear member 112).
[00100] Lock 114 can also be used in other environments. Figs. 28A and 28B illustrate a latch 114 of the type described above used in coupling a skirt-like wear member 212 (also referred to herein as a "skirt") with a base 258 (such as a ferrule). Figs. 28C and 28D show wear member 212 and base 258 with latch 114 omitted to further illustrate various surfaces and features of latch recess 216 in wear member 212. Fig. 28E shows a bottom view of skirt 212, for show additional details of the underside of the upper leg 212A and the latch recess 216 provided therein. As shown in these figures, the latch recess 216 is provided on an extended portion 212C of the upper leg 212A which extends rearwardly (and over the base member 258) beyond an outer edge 212E of the lower leg 212B.
As shown in Figs. 28A, 28B and 28D, the leading edge of base 258 (such as a ferrule) may be equipped with a protrusion 260 for engaging a skirt 212 (e.g., typically secured to base member 258 by soldering, but may be welded on. other ways, if practical and desired). In this illustrated example, and as best shown in Figs. 28D and 28E, the underside of the extended portion 212C of the upper leg 212A includes a recessed channel 264 that slides over and around the protrusion 260. This channel 264 can decrease in lateral width from the back to front direction, as shown by tapered sidewalls 264A in Fig. 28E, but may also be parallel. If desired, at least the rearmost portion of recess 264 may be somewhat wider at its top than at its center and/or bottom (for example, with the side walls tapered in the vertical direction, with projecting rails defined by the side walls , etc.) to provide a dovetail element for engaging protrusion 260. Alternatively, recess 264 and protrusion 260 may have complementary T-shapes or other locking configurations. The spacing and/or close contact between side walls 264A and outer walls 260A of protrusion 260 can help protect latch 114 and prevent side-to-side movement of skirt 112 with respect to base member 158.
[00102] As best shown in Fig. 28B, in the locked configuration, the surface 166 of the latch 114 engages a corresponding front support surface 262 on the protrusion 260 of the base 258 to prevent the skirt 212 from moving away from the front edge 258A of the base 258. These same surfaces 166 and 262, together with the interaction between anchor element 162 of body 118 and latch holder 164 in rear wall 216R of latch recess 216 prevent horizontal movement of latch 114 with respect to skirt 212 and base 258. Anchor 162 may have a rounded recess and bracket 164 may have a rounded cross-sectional shape, for example, such as components 62 and 64 described in more detail. The interaction between the anchor 162 of the body 118 and the latch support 164 in the rear wall 216R of the latch recess 216 together with the interaction between the shoulder 170 of the latch 122 and the support surface 271 of the skirt 212 prevents the ejection of the latch 114 of the latch recess 216 in the vertical direction (with respect to the orientation shown in Fig. 28B).
[00103] The characteristics of the lock recess 216 will be described in more detail below. As shown in Figs. 28A and 28C, the side area of the extended portion 212C of the upper leg 212A includes a cut inlet door or recessed area to allow access to a tool (e.g., tool 30, 130) for rotating the latch actuating member 120 114. Because of the angled orientation of the drive shaft A with respect to the hitch shaft B and/or the locking shaft C as described above, the bottom surface 216A of this area of the inlet port may be angled slightly upwards and /or away from the upper main surface of the base member 258. These angulation characteristics can provide more room for the operation of the tool 130 (i.e., because the handle of the tool 130 will be raised slightly higher than the surface of the base member 258 in comparison to the position of the handle if the tool extends away from the driver 120 in a horizontal manner or in a direction substantially parallel to the upper surface of the base member 258). These angulation characteristics also allow a manufacturer to obtain a greater thickness of the 212M skirt material below the 216A bottom surface of the tool insertion port, which can help provide longer tool life and greater resistance to cracking or failure in the tool. latch entry door area.
The entry port area of this exemplary skirt 212 opens to a latch receiving opening 270, a portion of which extends completely through the extended portion 212C of the upper leg 212A. This latch receiving opening 270 allows a portion of latch 114 to extend through skirt 212 and into position to engage protrusion 260 (as shown in Fig. 28B).
[00105] As noted above, the support member 164 in the rear wall area 216R of the latch recess 216 may have a rounded cross-sectional shape, for example, such as component 64 described in more detail above. While needless to do so, in this illustrated exemplary structure, such support member 164 extends across the entire rear width of latch receiving opening 270 and projects forward from rear wall 216R. If desired, support 164 can be provided through only a portion of rear wall 216R in the side-to-side direction (e.g., a central portion, a portion displaced to one side or the other, etc.) or support 164 can be provided at multiple separate locations across the rear of the latch receiving opening 270. In addition, if desired, the rounded cross-sectional support (eg, as the element 164) can be provided in the body 118 and the groove of the latch receiving such an element (e.g. as groove 162) may be provided as part of the rear wall of latch receiving opening 270.
[00106] The front wall 216F of the latch recess 216 includes a rearwardly extending portion 216S that is flush with or contiguous with the upper surface of the leg 212A, but this rearwardly extending portion 216S is notched to provide the support surface 271 for snap onto shoulder 170 of latch 122 (for example, see Fig. 28B). This notched support surface 271 is also provided to engage the dog tooth 156 when the latch 114 is mounted on the skirt 212 in a first position, for example, as described above in conjunction with Fig. 12. The rearwardly extending portion 216S of the front wall 216F and the notched area that is related thereto may extend for any desired proportion of the width of the latch receiving opening 270, but in this illustrated example these elements extend over about 25% to 60% of the full width of the hole 270.
[00107] Although Figs. 28A to 28D illustrate a skirt 212 coupled to a base member 258 through a protrusion 260 welded (or otherwise attached), a separately formed protrusion may be omitted, if desired. For example, if desired, the upper surface of base member 258 may be formed to include surfaces for engaging with latch 114 (e.g., either built up in the upper surface or recessed into the upper surface of base member 258).
[00108] Figs. 29A to 29F illustrate another exemplary skirt-like wear member 312 with which a latch 114 of the type described above may be used to couple skirt 312 with a base member 358 (such as a ferrule). Figs. 29A and 29B show wear member 312 and base 358 with latch 114 engaged thereto, and Fig. 29C shows various features of recess 316 of skirt latch 312 in more detail. Fig. 29D is a perspective view from below showing features of the interior of skirt 312. Figs. 29E and 29F show coupling characteristics of this skirt 312 with a protrusion 360 mounted (eg, welded) on a base member (eg, a ferrule). As shown in these figures, the latch recess 316 is provided on an upper leg 312A of the skirt 312 (which also includes a lower leg 312B that extends rearwardly about the same distance as the upper leg 312A). The skirt 312 of this example is somewhat shorter and more compact in the front-to-back direction compared to the skirt 212 of Figs. 28A to 28E described above.
[00109] In this illustrated exemplary structure, the leading edge of the base 358 may be equipped with a protrusion 360 for engaging a skirt (e.g., fixed to the base member 358 by soldering (or cast as part of the base), but it may be attached in other ways if this is practical and desired, such as by mechanical connectors). In this illustrated example, and as best shown in Fig. 29B, protrusion 360 is preferably mounted on ramp portion 358C of base member 358. In this way, protrusion 360 has an angle in its front portion (which matches the angle of ramp portion 358C) such that a rear portion 360A of protrusion 360 is welded to the main upper surface 358S of base member 358 and a front portion 360B of protrusion 360 is welded to slanted ramp surface 358I on the front of the base member. 358 (protrusion 360 may also be welded to base member 358 along its sides and/or around its entire perimeter). This angled boss 360 provides secure engagement with base member 358 (e.g., partially secured by corner 358C) and allows skirt 312 to be mounted more forward on base member 358 (compared to boss 260 of Figs. 28A to 28D, which was mounted only on the horizontal main base surface of the base member 258 in the orientation shown in Fig. 28B). Protrusion 360 can be formed as two or more separate parts or portions.
[00110] As shown in Figs. 29B, 29D and 29F, the underside of the upper leg 312A of this exemplary skirt 312 includes a recessed channel 364 that slides over and partially around the protrusion 360. The outer edges of the recessed channel 364 are defined by side rails or walls 364R that come together or converge to the front underside of the upper leg 312A. These rails 364R define the outer edges of a "bowl" type recessed channel 364 to receive the front portion of boss 360. These rails 364R, however, do not generally lend themselves to being supported against opposing surfaces on boss 360 Also, the material of skirt 312 is thicker outside of these tracks 364R (for example, in areas 312S, to the sides of skirt 312). This thicker 312S material and 364R rails provide additional strength and improved durability, particularly until the end of life of the 312 skirt.
[00111] Furthermore, as shown in Figs. 29D to 29F, the underside of upper leg 312A includes two generally rearwardly extending rails 312R (which taper or converge together in a front-to-back direction in this illustrated exemplary structure). These 312R rails are positioned within the 364R rails and are located within and in contact with the 360S side walls of the opening 380 in the protrusion 360. The contacting or supporting force between these 312R and 360S components helps prevent side-to-side movement of skirt 312 on base member 358 during use. In addition, the combination of rails 312R and protrusion 360 (including their coupling within recessed area 364 between outer rails 364R) helps to achieve greater wear resistance of wear member 312 in the area of latch 114 and insulation of the locks 114 against non-controllable non-centerline loads. This total construction also helps protect the lock 114 from contact with dirt or other materials during use.
[00112] As best shown in Fig. 29B, in the locked configuration, the front surface 166 of the latch 114 engages with a corresponding front support surface 362 on the protrusion 360 to prevent the skirt 312 from moving away from the leading edge 358A of the base member. 358. These same surfaces 166 and 362, together with the interaction between anchor element 162 of latch body 118 and bracket 164 on rear wall 316R of latch recess 316 prevent horizontal movement of latch 114 with respect to skirt 312 and base member 358. Anchor 162 may have a rounded recess and bracket 164 may have a rounded cross-sectional shape, for example, such as components 62 and 64 described in more detail above. The interaction between the anchor element 162 of the shoulder 118 of the latch body and the support element 164 in the rear wall 316R of the latch recess 316 together with the interaction between the shoulder 170 of the latch 122 and the support surface 371 of the skirt 312 prevents the latch 114 from ejecting the latch recess 316 in the vertical direction (with respect to the orientation shown in Fig. 29B).
[00113] The characteristics of the lock recess 316 will be described in more detail below. As shown in Figs. 29A and 29C, the side area of upper leg 312A includes a cut entry door or recessed area to allow access to a tool (e.g., tool 30, 130) to rotate actuating member 120 of latch 114. of the angled orientation of the drive shaft A with respect to the hitch shaft B and/or the locking shaft C as described above, the lower surface 312A of that area of the inlet port may be angled slightly upwards and/or away from the upper main surface 358S of base member 358. These angulation characteristics can provide more room for the operation of tool 130 (i.e., due to the fact that the handle of tool 130 will be raised slightly higher than surface 358S of base member 358 at compared to the handle position if the tool extends away from the driver 120 in a horizontal manner or in a direction substantially parallel to the surface 358S). These angulation characteristics also allow a manufacturer to achieve greater thickness of skirt material below the 312A bottom surface of the tool insertion port, which can help provide longer tool life and greater resistance to cracking or failure in the area. of the latch input port.
The entry port area of this exemplary skirt 312 opens to a latch receiving opening 370, a portion of which extends completely through the upper leg 312A. Such latch receiving opening 370 allows a portion of latch 114 to extend through skirt 312 and into position to engage protrusion 360 (for example, as shown in Figs. 29B and 29D).
[00115] As noted above, the support element 164 in the rear area 316R of the recess wall 316 of the latch may have a rounded cross-sectional shape and the anchor 162 forms a partially rounded opening to receive the support 164 in a swivel manner. , for example, such as components 62 and 64 described in more detail above. While it need not be done so, in this illustrated exemplary structure such bracket 164 extends across the entire rear width of latch receiving opening 370 and projects forward of rear wall 316R. If desired, bracket 164 may be provided through only a portion of rear wall 316R in the side-by-side direction (e.g., a central portion, a portion displaced on one side or the other, etc.) or bracket 164 may be provided at multiple separate locations across the rear of the latch receiving opening 370. In addition, if desired, the complementary member of rounded cross-section (e.g., such as the support 164) may be provided in the body 118 and the groove of the latch receiving that element (e.g., such as groove 162) may be provided as part of the rear wall of latch receiving opening 370.
[00116] The front wall 316F of the latch recess 316 includes a rearwardly extending portion 316S that is flush with or contiguous with the upper surface of leg 312A, but this rearwardly extending portion 316S is notched to provide the support surface 371 for engage shoulder 170 of latch 122 (for example, see Fig. 29B). A notched support surface is also provided under the rearwardly extending portion 316S to engage with dog tooth 156 when latch 114 is mounted on skirt 312 in a first position, for example, as described above in conjunction with Fig. 12 The rearwardly extending portion 316S of the front wall 316F and the notched areas that are related thereto may extend for any desired proportion of the width of the latch receiving opening 370, but in this illustrated example these elements extend over about about 25% to 60% of the total width of hole 370.
[00117] Although Figs. 29A to 29F illustrate a skirt 312 coupled to a base member 358 via a welded (or otherwise attached) protrusion 360, a separately formed protrusion may be omitted if desired. For example, if desired, the upper surface of base member 358 may be formed to include a protrusion with surfaces for engaging latch 114 (e.g., built-up on the upper surface or recessed into the upper surface of base member 358).
[00118] As noted above and as is evident from Figs. 29A and 29B, in this overall structure of the exemplary wear resistant assembly, the wear member (i.e., skirt 312) is mounted further forward and on sloping surface 358I of base member 358, at least compared to skirt 212 of Figs. . 28A to 28E. This feature makes the wear member 312 somewhat more compact (eg shorter in the front-to-back direction as the extended portion 212C of the upper leg 212A is omitted) and therefore may become somewhat lighter. In addition, this feature makes skirt 312 somewhat easier to mount over and decouple from a base member compared to skirt 212 because skirt 312 does not need to be moved over the longer distances necessary to slide an extended portion 212C of its upper leg around and along an edge of a base limb.
[00119] The latch 114 according to the invention as described in conjunction with Figs. 29A to 29E also have advantages when coupled with a skirt (eg 212 or 312) in that latch 114 can typically be operated relatively easily, even in the field (e.g. also exhibiting the advantages of latch 14 described above ). As a few more specific examples, latch 114 can be accessed from the sides of skirts 212 and 312 as described above, but still rotated out of latch recesses 216, 316, from the top (because latch recesses 216, 316 remain open at their tops). This arrangement allows for improved access to and interactions with the latch, as well as improved removal of fines (eg from the latch recess area).
[00120] The locks of the present invention have an integrated locking mechanism that can be hammer free and can be installed and removed using standard tools. Lock operation is simple and straightforward, and requires only minimal human effort, even in the presence of fine other debris. In addition, correct installation of the latches is visually confirmed immediately, because the tab 32, 132 will be on the left or clockwise side of the latch recess 16, 116 when engaged, and the tab 32, 132 will be on the right or counterclockwise of latch recess 16, 116 when disengaged.
[00121] As should be appreciated by those skilled in the art, because of the environment in which they are used, locks in excavation equipment are exposed to very extreme and inhospitable conditions. Over time, the latches and recesses in which they are received can become overloaded with dirt, boulders, and other materials (here also called "fines"). These fines can become so agglomerated in all the lock spaces that it can be difficult to actuate the moving parts of the locks when it becomes necessary to do so. Wear resistant assemblies according to the examples of the invention described above, however, can still move relatively easily, even after prolonged use. The manner in which the engagement member 22, 122 and other parts of the latches 14, 114 cooperates with or moves away from the fine clusters during the unlocking and disengaging phases of movement helps to ensure that the latch 14, 114 can be operated even after prolonged exposure to the harsh environment.
[00122] It should be appreciated that, although the embodiments of the representative locking mechanism presented herein utilize three components, a greater or lesser number of components that are similarly suitable for forming a locking mechanism of the present invention can be readily envisioned. While multi-component lock mechanisms can make it easier to assemble the lock during manufacturing, fewer lock components can be used to simplify design and reduce lock complexity. For example, the individual drive member and the locking member can be replaced with a single locking component that serves as both the drive member and the locking member. As another example, other biasing means can be employed in place of the resilient member.
[00123] It is believed that the invention presented herein encompasses multiple distinct inventions with independent utility. While each of these inventions has been presented in its preferred form, the specific embodiments thereof as presented and illustrated herein are not to be considered in a limiting sense, as numerous variations are possible. Each example defines an embodiment presented in the invention above, but any one example does not necessarily encompass all the features or combinations that may eventually be claimed. Where the description recites "a" or "a first" element or equivalent thereof, such description includes one or more such elements, neither requiring nor excluding two or more such elements. In addition, ordinal indicators, such as first, second or third, for identified elements are used to distinguish between elements, and do not indicate a required or limited number of such elements, and do not indicate a particular position or order of such elements. unless specifically stated otherwise.

权利要求:
Claims (9)
[0001]
1. Wear member (12) for an earth coupling equipment, comprising a wearable body (18) having an inner surface facing a base (58) in the equipment and an opposite outer surface, an extending hole from the outer surface to the inner surface, and a latch (14) integrally mounted in the hole for movement between a locked position where the latch contacts the base to secure the wear member in the earth coupling equipment and a release position where the latch releases the base, wherein the latch has a latch body (18) having a support surface (166) for releasably engaging the base and a coupling structure (62) for engaging the wearable body, a locking member (22) movable relative to the locking body between a first position for engaging the wearable body (18) to secure the lock alternatively in the locked position and the release position, and a second retracted position of the first. in the position, and a drive member (20) operative to move the locking member (22) from the first position to the second position, and move the locking body relative to the wearable body (18), wherein the drive member rotates relative to the locking body on a first axis (A); characterized in that in a first phase of turning the actuating member moves the locking member from the first position to the second position, and in a second phase of turning, the actuating member (20) moves the locking body around a bracket (64) between the locked position and the release position.
[0002]
2. Wear member according to claim 1, characterized in that it includes a resilient member (24) to urge the locking member to the first position.
[0003]
3. Wear member according to claim 1, characterized in that the locking member is pivotable around a second axis (B) between the first and second positions.
[0004]
4. Wear member according to claim 3, characterized in that the first axis and the second axis are parallel and not aligned.
[0005]
5. Wear member according to claim 3, characterized in that the first axis and the second axis are non-parallel.
[0006]
6. Wear member according to claim 3, characterized in that the first axis diverges from the second axis at an angle of up to 45° as measured in a plane to which both axes are projected.
[0007]
7. Wear member according to claim 1, characterized in that the lock body generally moves around an axis of the lock body (C) between the coupling and release positions, and in that the first axis and the axis of the lock body are not parallel.
[0008]
8. Wear member according to claim 1, characterized in that the drive member includes a tool interface (28) and a cam (36) to engage the lock member and translate the movement of the drive member to the lock member to move the lock member between the first and second positions.
[0009]
9. Wear member (12) according to claim 6, characterized in that the first axis diverges from the second axis at an angle between 0.5° and 45°, as measured in a plane to which both axes are designed.

类似技术:

---

公开号 | 公开日 | 专利标题

---

BR112014012274B1|2021-05-18|wear member for ground coupling equipment

---

NZ719130B2|2017-01-31|Wear assembly

---

NZ623750B2|2016-08-30|Wear assembly

同族专利:

---

公开号 | 公开日

---

CN103958792A|2014-07-30|

---

EA201400605A1|2014-12-30|

---

NZ623750A|2016-05-27|

---

EA038846B1|2021-10-27|

---

EA201691552A1|2016-12-30|

---

JP2014533787A|2014-12-15|

---

MY181372A|2020-12-21|

---

AU2017200709A1|2017-02-23|

---

PH12016501242B1|2016-11-21|

---

AU2016202743B2|2017-06-15|

---

SI2783052T1|2021-04-30|

---

PE20181170A1|2018-07-20|

---

US20160201299A1|2016-07-14|

---

US10024036B2|2018-07-17|

---

PH12016501241B1|2016-11-21|

---

EA201891545A1|2018-11-30|

---

CN107338827B|2020-09-18|

---

EP2783052A4|2015-08-19|

---

BR122015028690B1|2021-05-18|

---

BR122015028712A2|2019-08-27|

---

KR102149755B1|2020-08-31|

---

KR102039152B1|2019-10-31|

---

EP3604697B1|2022-01-05|

---

CO6960518A2|2014-05-30|

---

AP2014007635A0|2014-05-31|

---

EA028644B1|2017-12-29|

---

PE20142021A1|2014-12-15|

---

HUE053731T2|2021-07-28|

---

US20200240120A1|2020-07-30|

---

KR20190125513A|2019-11-06|

---

ES2847892T3|2021-08-04|

---

BR122015028712B1|2021-08-03|

---

CL2014001348A1|2014-11-28|

---

CN103958792B|2017-12-26|

---

AU2012318298A1|2013-06-06|

---

US10655307B2|2020-05-19|

---

WO2013078101A1|2013-05-30|

---

EP3604697A1|2020-02-05|

---

MX2014006070A|2014-08-26|

---

JP6198747B2|2017-09-20|

---

RS61610B1|2021-04-29|

---

KR102134646B1|2020-07-16|

---

CN107905289A|2018-04-13|

---

EP3604696A1|2020-02-05|

---

BR122020005546B1|2021-08-10|

---

US11155982B2|2021-10-26|

---

KR20200000469A|2020-01-02|

---

BR122015028690A2|2019-08-27|

---

EP2783052B1|2021-01-06|

---

EA036057B1|2020-09-21|

---

MX346723B|2017-03-30|

---

PH12014501085A1|2014-07-28|

---

CA3039227A1|2013-05-30|

---

IN2014DN03361A|2015-06-05|

---

CL2018001300A1|2018-08-24|

---

PH12014501085B1|2014-07-28|

---

JO3727B1|2021-01-31|

---

CN106120942A|2016-11-16|

---

NZ719130A|2016-10-28|

---

PH12016501242A1|2016-11-21|

---

AU2017200709B2|2018-09-27|

---

BR112014012274A2|2017-05-30|

---

CN107338827A|2017-11-10|

---

PE20181169A1|2018-07-20|

---

CA2852303C|2020-10-27|

---

JP2018159266A|2018-10-11|

---

JP6703043B2|2020-06-03|

---

US20140215868A1|2014-08-07|

---

UA115536C2|2017-11-27|

---

JP2017137755A|2017-08-10|

---

US20180148908A1|2018-05-31|

---

NZ721079A|2016-10-28|

---

LT2783052T|2021-03-25|

---

AU2016202743A1|2016-05-19|

---

AR088953A1|2014-07-16|

---

PH12019502611A1|2021-01-11|

---

US9322150B2|2016-04-26|

---

CN106120942B|2018-11-23|

---

CA3039227C|2021-11-23|

---

KR102077225B1|2020-02-13|

---

BR122020005555B1|2021-08-10|

---

EP2783052A1|2014-10-01|

---

KR20140103916A|2014-08-27|

---

PH12016501241A1|2016-11-21|

---

CA2852303A1|2013-05-30|

---

KR20190133297A|2019-12-02|

---

EA028644B9|2018-02-28|

---

CA3133687A1|2013-05-30|

---

PE20200359A1|2020-02-19|

---

AU2012318298B2|2016-02-04|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

---

US2064059A|1934-12-21|1936-12-15|Finkl & Sons Co|Detachable dipper tooth|

---

US4067657A|1976-02-17|1978-01-10|Caterpillar Tractor Co.|Cam lock retaining means for ripper tips|

---

US4433496A|1983-03-14|1984-02-28|Esco Corporation|Locking device for excavating equipment|

---

DE3611493C2|1986-04-05|1988-08-18|O & K Orenstein & Koppel Ag, 1000 Berlin, De|

---

US4716666A|1986-09-29|1988-01-05|Esco Corporation|Wear runner for excavating bucket|

---

US5152087A|1990-10-09|1992-10-06|A. M. Logistic Corporation|Holding clamp and reversible earth working cutting teeth|

---

US5337362A|1993-04-15|1994-08-09|Ricoh Corporation|Method and apparatus for placing data onto plain paper|

---

US5435084A|1994-02-17|1995-07-25|Harnischfeger Corporation|Apparatus and method for attaching a digging tooth tip|

---

US5718070A|1995-11-13|1998-02-17|Gh Hensley Industries, Inc.|Self-adjusting tooth/adapter connection system for material displacement apparatus|

---

US5709043A|1995-12-11|1998-01-20|Esco Corporation|Excavating tooth|

---

CN1204376A|1995-12-11|1999-01-06|埃斯科公司|Wear member|

---

US5666748A|1995-12-11|1997-09-16|Esco Corporation|Wear cap and components useable therewith|

---

US5833323A|1997-02-03|1998-11-10|Kennametal Inc.|Cutting toolholder retention system|

---

US5913605A|1997-09-17|1999-06-22|G. H. Hensley Industries, Inc.|Rotary lock system for wear runner assembly|

---

US5983534A|1997-09-17|1999-11-16|G. H. Hensley Industries, Inc.|Rotary lock system for excavating tooth/adapter assembly|

---

US6085448A|1997-10-30|2000-07-11|Caterpillar Inc.|Mechanical retention system for ground engaging tools|

---

US5987787A|1998-02-11|1999-11-23|Wright Equipment Company Limited|Ground engaging tool components|

---

US6216368B1|1998-06-15|2001-04-17|Robert S. Bierwith|Excavating bucket with replaceable wedge-locked teeth|

---

US6675509B2|1998-06-15|2004-01-13|Robert S. Bierwith|Excavating bucket with replaceable wedge-locked teeth|

---

US6393738B1|1998-06-15|2002-05-28|Robert S. Bierwith|Excavating bucket with replaceable wedge-locked teeth|

---

US6108950A|1999-03-08|2000-08-29|Gh Hensley Industries, Inc.|Self-adjusting tooth/adapter connection system for material displacement apparatus|

---

US6439796B1|2000-08-02|2002-08-27|Gh Hensley Industries, Inc.|Connector pin apparatus and associated methods|

---

AUPR576701A0|2001-06-18|2001-07-12|Keech Castings Australia Pty Limited|Locking assembly and method|

---

US6993861B2|2001-07-06|2006-02-07|Esco Corporation|Coupling for excavating wear part|

---

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

---

KR101017165B1|2001-07-06|2011-02-25|에스코 코포레이션|Coupling for excavating wear part|

---

US6668472B2|2001-07-16|2003-12-30|Robert Bierwith|Wedge-locking system and excavation bucket assembly with wedge-locking system|

---

US20030070330A1|2001-10-12|2003-04-17|Olds John R.|Tooth retainer with rotary camlock|

---

US6708431B2|2001-12-03|2004-03-23|Hensley Industries, Inc.|Excavating tooth assembly with rotatable connector pin structure|

---

EP1852557B1|2002-09-19|2010-07-21|Esco Corporation|Wear assembly and lock for an excavating bucket|

---

AU2002951728A0|2002-09-30|2002-10-17|Cutting Edges Replacement Parts Pty Ltd|Component interlocking|

---

US6826855B2|2002-11-04|2004-12-07|Hensley Industries, Inc.|Excavating tooth point/adapter assembly with rotatably lockable connector structure|

---

US7080470B2|2003-04-30|2006-07-25|Esco Corporation|Wear assembly for excavator digging edge|

---

US6986216B2|2003-04-30|2006-01-17|Esco Corporation|Wear assembly for the digging edge of an excavator|

---

US7162818B2|2003-08-04|2007-01-16|Hensley Industries, Inc.|Connector pin assembly and associated apparatus|

---

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

---

US7596895B2|2004-03-30|2009-10-06|Esco Corporation|Wear assembly|

---

US7707755B2|2004-03-30|2010-05-04|Metalogenia, S.A.|Removable device for attaching two mechanical parts|

---

US7121022B2|2004-03-31|2006-10-17|Berkeley Forge And Tool, Inc.|Cam action locking assembly|

---

FR2884841B1|2005-04-26|2008-12-05|Predac Sarl|METHOD AND DEVICE FOR CONNECTION BETWEEN A WEAR PIECE AND ITS SUPPORT THROUGHOUT EQUIPMENT FOR HANDLING MATERIALS BY PUBLIC WORKS MACHINERY|

---

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

---

US7603799B2|2006-05-11|2009-10-20|Hensley Industries, Inc.|Cammed connector pin assembly and associated excavation apparatus|

---

AP2508A|2006-06-16|2012-11-16|Esco Corp|Lock for securing wear parts to earth-working equipment|

---

CA2667186C|2006-08-16|2013-10-01|Caterpillar Inc.|Ground engaging tool system|

---

CN101558206B|2006-09-01|2011-12-14|麦塔洛吉尼亚股份有限公司|Prong and fitting for a dredging machine|

---

US7526886B2|2006-10-24|2009-05-05|Esco Corporation|Wear assembly for an excavating bucket|

---

PE20081127A1|2006-10-24|2008-08-15|Esco Corp|WEAR MOUNTING FOR AN EXCAVATOR BUCKET|

---

US20080092412A1|2006-10-24|2008-04-24|Esco Corporation|Wear Assembly For An Excavating Bucket|

---

US20080209772A1|2007-03-02|2008-09-04|Kan Cui|Connector pin assembly|

---

WO2008116942A1|2007-03-28|2008-10-02|Metalogenia, S.A.|Detachable fastening system between a male piece and a female piece, pin and female piece|

---

US7874086B2|2007-04-24|2011-01-25|Esco Corporation|Lock assembly for securing a wear member to earth-working equipment|

---

US8776408B2|2007-08-23|2014-07-15|Wearforce Pty Ltd|Shroud assembly|

---

US8434248B2|2008-02-08|2013-05-07|Gary Woerman|Excavation retention assembly|

---

US7788830B2|2008-02-08|2010-09-07|Cqms Razer Llc|Excavation retention assembly|

---

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

---

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

---

CA3050939C|2009-12-11|2021-10-19|Cqms Pty Ltd|A lock assembly for an excavator wear member|

---

NO332031B1|2009-12-17|2012-05-29|Kverneland Group Operations Norway As|Device at wear part for work tools|

---

JO3763B1|2010-04-20|2021-01-31|Esco Group Llc|Coupling assemblies with enhanced take up|

---

CN101942850A|2010-06-02|2011-01-12|中钢集团衡阳重机有限公司|Method for repairing bucket lip of abraded bucket|

---

JP5210415B2|2011-05-09|2013-06-12|株式会社小松製作所|Construction machine bucket tooth|

---

JP5504205B2|2011-05-09|2014-05-28|株式会社小松製作所|Bucket tooth assembly for construction machine and bucket equipped with the same|

---

JOP20200019A1|2011-07-14|2017-06-16|Esco Group Llc|Wear assembly|

---

WO2013033751A1|2011-09-08|2013-03-14|Cqms Pty Ltd|A lock assembly for an excavator wear member|

---

MX346723B|2011-11-23|2017-03-30|Esco Corp|Wear assembly.|

---

US8904677B2|2012-07-12|2014-12-09|Kan Cui|Locking pin assembly|

---

US9027268B2|2013-03-15|2015-05-12|Caterpillar Inc.|Retainer systems for ground engaging tools|

---

AU2013204854B2|2013-04-12|2016-04-21|Bradken Resources Pty Limited|Excavation Tooth Assembly|

---

US9212553B2|2013-11-08|2015-12-15|The Sollami Company|Dirt and rock cutting bit tool|

---

AU2015279586B2|2014-06-27|2019-07-11|Robert S. Bierwith|Self-locking connector pin for demountably securing consumable ground digging components to containers of earth moving equipment|

---

US20170328035A1|2016-05-12|2017-11-16|Hensley Industries, Inc.|Connector systems in earth engaging wear member assemblies|MX346723B|2011-11-23|2017-03-30|Esco Corp|Wear assembly.|

---

CA2908544C|2013-03-25|2020-08-25|Keech Castings Australia Pty Limited|Lock assembly|

---

NO20131382A1|2013-10-18|2015-04-20|Kverneland Group Operations Norway As|

---

US20160177544A1|2014-12-19|2016-06-23|Caterpillar Inc.|Lock for ground engaging tool|

---

US10196799B2|2014-12-19|2019-02-05|Caterpillar Inc.|Ground engaging tool|

---

US10030368B2|2015-10-06|2018-07-24|Hensley Industries, Inc.|Excavating tooth assembly with locking pin assembly|

---

PE20181870A1|2016-05-05|2018-12-05|Esco Group Llc|A WEAR PART FOR EARTH WORK TEAM|

---

USD797157S1|2016-06-03|2017-09-12|H&L Tooth Company|Wear assembly lock structure|

---

US10774500B2|2017-03-09|2020-09-15|Caterpillar Inc.|Power operated locking system earth moving equipment and method|

---

US10494794B2|2017-06-14|2019-12-03|Caterpillar Inc.|Edge protection system for an implement|

---

US10538899B2|2017-06-14|2020-01-21|Caterpillar Inc.|Edge shroud and method for removing edge shroud from an implement|

---

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

---

US10538900B2|2017-11-30|2020-01-21|Caterpillar Inc.|Wear member for a work tool|

---

AU2019391600A1|2018-12-07|2021-07-22|Keech Castings Australia Pty Limited|Wear part and lock assembly|

---

US20210095444A1|2019-09-30|2021-04-01|Caterpillar Inc.|Anti-tipping retainer for a retaining mechanism|

---

CN111088825B|2020-01-02|2020-12-08|四川大学|Grab bucket of excavator and excavator|

法律状态:
2018-12-04| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

---

2019-12-24| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

---

2020-11-10| B25A| Requested transfer of rights approved|Owner name: ESCO GROUP LLC (US) |

---

2020-12-08| B06A| Patent application procedure suspended [chapter 6.1 patent gazette]|

---

2021-03-23| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

---

2021-05-18| 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 16/11/2012, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

---

申请号 | 申请日 | 专利标题

---

US201161563448P| true| 2011-11-23|2011-11-23|

---

US61/563,448|2011-11-23|

---

US201261720928P| true| 2012-10-31|2012-10-31|

---

US61/720,928|2012-10-31|

---

PCT/US2012/065689|WO2013078101A1|2011-11-23|2012-11-16|Wear assembly|BR122015028690-5A| BR122015028690B1|2011-11-23|2012-11-16|wear resistant member|

---

BR122015028712-0A| BR122015028712B1|2011-11-23|2012-11-16|LOCK FOR FIXING A WEAR RESISTANT MEMBER TO A BASE ON AN EARTH COUPLING EQUIPMENT|

---

BR122020005555-3A| BR122020005555B1|2011-11-23|2012-11-16|WEAR MEMBER FOR EARTH COUPLING EQUIPMENT|

---

BR122020005546-4A| BR122020005546B1|2011-11-23|2012-11-16|FIXING LOCK FOR FIXING A WEAR MEMBER TO AN EARTH COUPLING EQUIPMENT|