• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    APPLIANCE FOR SEPARATING SOLIDS FROM SOLID DRILLED DRILLING FLUID, SCREEN ASSEMBLY, SHALE SHAKER, AND METHOD OF USING THE SOLID FOR SEPARATING SOLID SOLID SOLID SOLID DRILLING SOLIDS FOR SOLID SOLIDS FOR SOLID SOLIDS FOR SOLID SOLIDS FOR SOLID SOLIDS FOR SOLID SOLIDS. from drilling fluids loaded with solids, the apparatus comprising a shale shaker and a screen assembly (300), the shale shaker comprising a base and a basket (30) isolated from said base, a drain pan (301) arranged in said basket (30) for directing the filtered drilling fluid, the sieve assembly (300) comprising at least one layer of filtration material (299), a sieve holder (340) having a perimeter with at least one support point within said perimeter, characterized by the fact at least one raised portion (313a-313e) to support said screen assembly (300); there is also disclosed an apparatus for separating solids from drilling fluids laden with solids, the apparatus comprising a shale shaker comprising a basket (30) having side supports (109,110) and at least one intermediate support (313a-313e) disposed between said side supports (109,110), the screen assembly (300) comprising a screen support (340) which (...).
    公开号:BR112012025909B1
    申请号:R112012025909-1
    申请日:2011-03-24
    公开日:2020-11-03
    发明作者:George Alexander Burnett
    申请人:National Oilwell Varco, L.P;
    IPC主号:
    专利说明:

    [001] The present patent application relates to an apparatus and method for the separation of solids from a drilling fluid laden with solids and, in particular, but not exclusively, to an apparatus and method for the separation of solids of solids from a drilling mud laden with solids. The present application also refers to a shale shaker and respective sets of sieves.
    [002] When drilling a hole in the construction of an oil or gas well, a drill is arranged at the end of a drilling column, which is rotated to drill the hole through a structure. A drilling fluid known as a "drilling mud" is pumped through the drill string into the drill bit to lubricate the drill bit. The drilling mud is also used to transport the chips produced by the drill bit and other solids to the surface by means of a ring formed between the drilling column and the drilling hole. The density of the drilling mud is closely controlled to inhibit the collapse of the hole and to ensure that drilling is carried out optimally. The density of the drilling mud affects the drill penetration rate. When adjusting the density of the drilling mud, the penetration rate changes to the detriment of the possible collapse of the well. Drilling mud can also transport lost circulating materials to seal porous sections of the well. The acidity of the drilling mud can also be adjusted according to the type of layer formation being drilled. The drilling mud contains, inter alia, expensive synthetic oil-based lubricants, and it is therefore normal to recover and reuse the drilling mud used, but this requires, inter alia, that the solids be removed from the drilling mud . This is achieved by processing the drilling mud. The first part of the process is to separate the solids from the solid-loaded drilling mud. This is at least partially achieved with a vibrating separator, such as the shale shakers disclosed in US 5,265,730, WO 96/33792 and WO 98/16328. Additional processing equipment, such as centrifuges and hydrocyclones, can be used to clean the sludge from solids. The solids are covered with contaminants and waste. It is not uncommon to have 30 to 100 m3 of drilling fluids circulating in a well.
    [003] The resulting solids, referred to here as "drilling debris" are processed to remove substantially all residues and contaminants from the solids. The solids can then be disposed of in landfills or discharged into the sea, in the same environment from which they came. Alternatively, solids can be used as a material in construction or have other industrial uses.
    [004] Shale shakers generally comprise an open bottom basket, having an open discharge end and a walled solids feed end. A number of rectangular sieves are placed on the open bottom of the basket. The screens may be substantially planar, or have a slight crown. The basket is arranged on springs above a receiver to receive the recovered drilling mud. A jump or ditch is provided under the open discharge end of the basket. A motor is attached to the basket, which has a drive rotor provided with a weight of compensating chipboard. In use, the motor rotates the rotor and the weight of the compensating chipboard, which causes the basket and sieves attached to it to shake. The sludge laden with solids is fed into the feed end of the basket for the sieves. The stirring motion induces the separation of the drilling mud from the solids, the drilling mud passing through the screens and the solids above the screens. The stirring motion also causes the solids to move along the sieves towards the open discharge end. The recovered drilling mud is received at the receiver for further processing, and the solids pass over the discharge end of the basket into the ditch or container.
    [005] Rectangular sieves can be arranged at an angle to the horizontal plane, such as a seven degree tilt angle from the feed end to the discharge end of the shale shaker. The angle can be adjustable. Sieves are usually attached to the basket and the basket is adjustable to adjust the angle of the sieves in relation to the horizontal. The flow of the drilling fluid laden with solids can form a cluster on the inclined screens. The action of the vibrating mechanism causes the solids to scale the inclined screens to the discharge end of the agitator and to the ditch or container.
    [006] Generally, a vibratory mechanism that induces a circular vibration tends to throw the solids from the sieve into the air in circular movements, which is common in shale shakers with a horizontal sieve tray. A vibratory mechanism inducing an elliptical movement will cause the solids to move in the direction of the largest ellipse string, which is often used in shale shakers with an inclined sieve tray, such that in use, the movement of solids even the tilted sieve tray is facilitated. A shale shaker having a vibrating mechanism inducing a very thin ellipse is known as a linear shale shaker and induces rapid movement of the solids along the sieve, although the sieve tends to undergo rapid degradation due to the sudden deceleration of the solids when are in the sieve.
    [007] The sieves used in a shale shaker have high values of acceleration and heavy load during the processing of drilling fluids. The high acceleration values are necessary to induce transfer through the sieves and to transmit the solids on the discharge screen.
    [008] The shale shaker drive device is bulky in order to induce an ideal stroke profile based on the total mass of the set, including the shaking device, basket, sieves and drilling fluids loaded with solids in ie, all vibrated components, essentially the suspended mass. The screens are fixed or otherwise attached to the basket and the screens support the drilling fluids loaded with solids being processed.
    [009] The movement induced in the set is typically a simple harmonic movement, in which from its lowest point on the vibrating unit, basket, sieves and fluids loaded with drilling solids are accelerated upwards normally in an elliptical movement, the largest string of the ellipse set around forty-five degrees in front of the basket due to positive high acceleration forces the reduction in the direction of the middle course, in which the acceleration values are reduced to zero, and then a negative deceleration occurs reducing to a speed minimum at the top of the course. This cycle is repeated in the descending stroke showing that the high acceleration values, (positive and negative) occur at each end of the stroke where the speed is minimized and the acceleration values are zero at each midpoint of the stroke, at which the speeds are the highest.
    [010] As the fluids are not physically attached to the screens, the loading of the screen therefore varies depending on the stroke cycle. During the upward stroke, the sieve is accelerated to the mass of the fluid, thereby inducing the transfer, and then the sieve accelerates away from the fluid mass in the downward stroke, only so that the mass of fluid falls on the sieves. again at the bottom of the stroke due to gravity and the complete cycle is then repeated, typically at about 1800 to 2000 rpm.
    [011] For optimum performance, in general, the sieve should preferably move as an entity corresponding to the basket's course profile and any deviation should be minimized. If the sieve deflects, this can lead to much higher acceleration values, which leads to premature wear and uneven load distribution across the sieve width. Since movement is also used to transmit solids through the sieve, any additional deformation of the sieve will result in uneven transport along the width of the sieve.
    [012] The prior art has shown that the sieve can cover the distance between the sieve clamps on the sides of the basket that are used to secure the sieve to the basket, but this requires a significant amount of materials in order to provide the necessary stiffness. The disadvantage of this approach is that the sieves are generally larger and heavier, not as good for handling and can be more expensive to manufacture.
    [013] Sieves are generally one of two types: wall hooks; and pre-tensioned.
    [014] the wall hook sieve type comprises several rectangular layers of mesh in a sandwich, usually composed of one or two layers of fine mesh and a support mesh having larger holes and heavier gauge cable. The mesh layers are joined at each side end by a strip that is shaped like an elongated hook. In use, the elongated hook is connected to a tensioning device arranged along each side of a shale shaker. The shale shaker also comprises a set of support elements in the form of a crown, which run along the length of the shaker basket, over which the mesh layers are tensioned. An example of this type of screen is disclosed in GB-A-1, 526,663. The support mesh can be provided with, or replaced by, a panel with openings in the support mesh.
    [015] The type of pre-tensioned sieve comprises several layers of rectangular mesh, usually comprising one or two layers of fine mesh and a support mesh having larger holes and heavier gauge cable. The mesh layers are pre-tensioned on a rigid support comprising an angled rectangular iron frame adhered to them. The sieve is then inserted into the channels of channel C arranged inside a basket of a shale shaker. An example of such a screen is disclosed in GB-A-1, 578,948 and an example of a shale shaker suitable for receiving pre-tensioned type screens is described in GB-A-2, 176,424.
    [016] WO 2004/035234 describes a screen set for a shale shaker, the screen set comprising a panel and a support structure, the panel having an area provided with a plurality of openings and at least , a layer of filtration material arranged over the multiplicity of openings. The openings have flaps that project downward to provide rigidity to the panel. The flaps of the adjacent openings form ribs on the panel. The support structure comprises a plurality of transverse support ribs. The transverse ribs of the panel fit into the transverse support ribs. The panel is removable from the support structure.
    [017] WO 03/013690 and WO 2004/069374 disclose a screen assembly comprising a screen element and a separate support. The screen element comprising a mesh panel and angled support side members having a downwardly sloping face. The support comprises a rigid frame having angled side surfaces on each side. When in use, the sieve assembly is slid on the tracks of a shale shaker. A pneumatic seal arranged on the rails is activated to press the lateral support members inclined towards the inclined surfaces of the rigid structure to create a tension in the mesh panel on the support. The screen element may comprise a light and flexible plate with openings.
    [018] A problem associated with shale shakers is that the sieves used in it tend to mask, especially when the solids are gummy, such as clay, or bulky solids close to the size of the sieve mesh. The latter type of masking is known as particle masking of similar sizes. Several solutions have been proposed to solve this problem, as described in document GB-A-1, 526.663, in which a sieve set with two layers of filtration material in a sandwich and which allows the layers of filtration material to move independently dislodges any similarly sized particles lodged in one of the sieves. WO 01/76720 relating to the rotating drum separator also discloses the use of air nozzles outside the drilled drum to provide positive air pressure through the drilled drum in the dry zone, ensuring that the perforations are not clogged with solids.
    [019] It is advantageous to use fine mesh filters to filter very small particles, for example, of a size in the range of 50 to 200 p or more, without the filtering device becoming clogged with small particles. However, it is fine-mesh filters, in particular, that are prone to such unwanted clogging.
    [020] It is also advantageous to provide a separator that works at low noise levels, in compliance with health and safety legislation. It is also advantageous to have a simple and reliable separator to inhibit downtime for maintenance and repairs.
    [021] It is preferable, in certain circumstances, to retain particles, for example, of a particle size in the range of 50 to 60 p or greater, by means of a filter.
    [022] When drilling an oil or gas well, there may be cracks in the well wall. Such cracks can propagate, which could cause structural problems in the well wall and / or allow drilling fluids to escape through the crack into the structure. In addition, if substantial amounts of drilling fluids are lost, the pressure in the drilling fluid in the well may drop, which can cause the well bore to collapse. Consequently, well reinforcement materials can be added to the circular drilling fluid. The well reinforcement materials comprise sized particles. When the drilling fluid is circulated around the well wall with cracks, the dimensioned particles become chocked in the cracks, which reduces the probability of propagation of these cracks. It is beneficial to recover these sized particles and reuse them in the circulated drilling mud. Shale shakers were thus modified to size solids in drilling fluids laden with solids. Such a shale shaker is disclosed in USSN 12 / 490,492. A variety of sizes of solids can be extracted using as a shale shaker and recirculated as well reinforcement material in fresh drilling fluid.
    [023] In order to accelerate the tracking of drilling mud filled with solids, it is necessary to transmit energy to the drilling solids load at the moment when filtration occurs, that is, at the moment when the drilling mud loaded with solids find yourself in the sieve. The inventors found that, when a tray vibrates in the fluid bed, the energy in the form of (sic).
    [024] The prior art also shows that the basket configuration can be such that additional support is provided between the sides of the basket, GB-A-2, 206.501, thereby reducing the extension of the screen and reducing , thus, the necessary rigidity of the screen so that the screen can be smaller and lighter.
    [025] Bailey and Fisher's document US-A-2007/0187303 discloses a sieve set for separating solids from drilling fluids loaded with solids, the sieve set comprising a sieve element and a frame holder inserted into a shale shaker fixation device. The support structure has a plurality of support elements. The sieve element comprises mesh panels with longitudinal end portions which, in use, are clamped between the angled surfaces of the support structure to secure the mesh panels to the support elements between the surfaces. It should be noted that, in use, the filtered fluid flows through the sieve element and support element.
    [026] GB-A-2, 425,743 by Burnett, describes a screen set for separating solids from drilling fluids loaded with solids, the screen set shown in Figure 1 comprising a screen panel for receiving filtered material and a sieve holder that can be inserted into a shale shaker fixing device. The sieve panel comprises inverted longitudinal T-rails which are pulled down onto the support by means of the fixing action on the shale shaker fixing device. The sieve set shown in Figure 2 of GB-A-2, 425,743 comprises a sieve panel with the respective filtered materials and a sieve holder separated by crown-insertable ribs in a shale agitator fixture. The sieve panel is attached to the sieve holder on the shale agitator fixture. It should be noted that, in use, the filtered fluid flows through the sieve element and support element.
    [027] The present application for a patent provides greater support for the sieves, minimizing the interval between the supports, and the use of tapered surfaces forces the sieve to be placed on the support structure. This, together with the increase in the contact area between the screen and the support structure, dictates that the frictional forces to be overcome when lifting the screen from the support structure are higher than the force required for a structure of a simple point of contact.
    [028] The inventors noted that, for the simple contact point structure, the reaction forces acting on the sieve and the support structure are vertical only, so that support is provided only during the upward stroke of the basket.
    [029] The proposed conical surfaces dictate that the reaction forces are at an angle perpendicular to the inclined faces and that equivalent loads can be calculated comprising a vertical component and a horizontal component. The horizontal component reacts against the sieve and is an additional force to be overcome when the sieve deflects under its own weight during the downward stroke of the basket. Maximizing this force, therefore, will help to minimize the deflection of the sieve during the downward stroke.
    [030] In accordance with the present patent application, an apparatus is provided for separating solids from drilling fluids loaded with solids, the apparatus comprising a shale shaker and a sieve assembly, the shale shaker comprises a flow tray for directing the filtered drilling fluid, and the sieve assembly comprises at least one layer of filtration material, a support and a perimeter having at least one support point within it, characterized by the fact that the flow tray comprises at least an elevated portion to support the screen assembly. Thus, the flow tray is preferably used as a structural component to increase the rigidity of the screen assembly.
    [031] Preferably, the drain pan is arranged at an angle between the horizontal and twenty-five degrees from a horizontal plane and, more preferably, between five and fifteen degrees, advantageously, twelve degrees. Advantageously, the drilling fluid flow tray directs the filtered drilling fluids to the feed end of the basket in which, preferably, the filtered drilling fluid is directed to at least one duct and preferably in a conduit of a flow distribution device. Preferably, the sieve set is in the foreground and the drain pan is in the background, the sieve set in the foreground being different from the drain pan in the second plane. Advantageously, the foreground and background diverge at an angle between one and ten degrees. Preferably, the drain pan comprises a series of projecting parts configured to support the screen assembly, found at the divergent angle of the drain pan.
    [032] Preferably, at least a raised portion comprises at least one wear strip. Advantageously, the drain pan is made of a composite material. Advantageously, at least an elevated portion defines flow channels for directing the filtered drilling fluid along the flow tray. Preferably, the raised portion forms a longitudinal wall that comprises at least one main part and, advantageously, the entire length of the drain pan. Preferably, the drain pan is substantially the same length as the sieve pan in which the sieve assembly or sieve assemblies are in use. Alternatively, the flow tray has a length that is a major part of the length of the sieve tray. Preferably, the flow channels are tapered to facilitate the flow of the filtered drilling mud. Preferably, tapered in depth, the flow channel has a high bottom at a first end and a low height at the second end, at which the filtered drilling fluid is discharged. The inventors have noted that considerable longitudinal forces are induced in the screen assembly by the vibrating mechanism in use. The conical portions, preferably, fit over the corresponding conical portions, thus providing a large contact area. The large contact area provides a high degree of surface tension and thus inhibits the movement of the sieve set relative to the sieve tray and therefore to the basket, while still allowing easy insertion of the sieve sets when replacing the sets of sieves.
    [033] Advantageously, the shale shaker comprises a basket, the drain pan being fixed to the basket. Preferably, the basket comprises sides, the drain pan being fixed to the sides. Advantageously, each side has a rail, with the drain pan resting on the rail. Preferably, the flow tray is adhered, riveted, screwed, glued, welded or otherwise fixed to the rail and / or the sides. Alternatively, the drain pan may be removable from the basket, preferably slidably removable.
    [034] Preferably, the drain pan comprises a plurality of contours, with at least one of the contours forming at least one of the raised portions.
    [035] Advantageously, at least one high portion is a plurality of high portions. The higher the portions, the better the support for the sieve assembly, although the flow channels need to be bulky to remove the yield of the filtered drilling mud, which can be in the order of a thousand gallons per minute.
    [036] Preferably, the screen support comprises a conical surface. Advantageously, at least an elevated portion comprises a conical support surface for receiving the conical surface of the screen support. Preferably, the tapered surface is formed from a laminated material, which can be of bent sheet metal, to form a tapered surface. Preferably, the conical material has openings to allow the filtered drilling mud to flow through the filtration material.
    [037] US-B1-6, 454,099 from Adams, discloses sieve sets for a shale shaker for separating solids from solid-laden drilling fluids, the sieve sets having strips of hooks with support strips and filtered material arranged between them. The filtered material has the high portions in the material.
    [038] US-B1-6, 302,276 from Seyffert, discloses a sieve set for a shale shaker for separating solids from drilling fluids laden with solids, the sieve set having a strip of support, with the strips arranged transversely to the agitator and having elevated portions to support the filtered material that have corrugations in the portions, with the corrugations running in parallel with the sides of the sieve assembly. It also reveals a screen set comprising replaceable panels.
    [039] The present patent application also provides an apparatus for separating solids from drilling fluids laden with solids, the apparatus comprising a shale shaker and a screen set, the shale shaker being comprises a basket with side supports and at least one intermediate support arranged between the side supports, and the screen assembly comprises a screen support that supports at least one layer of filtered material, the screen support that has at least at least two sides being supported by the side supports and at least one support member between the sides for coupling with at least one intermediate support, characterized by the fact that the screen support comprises a conical surface and at least an intermediate support having a conical support surface, such that, in use, the conical surface and the inclined support surface come into contact with each other. Preferably, this arrangement prevents lateral and tangential movement of said set of sieve in said basket. Advantageously, the conical surface or inclined surfaces are substantially flat, although they can be curved; they have bumps and / or have a rough surface. Preferably, the additional tapered surface is of the same magnitude as the angle to the horizontal, as the tapered surface. Advantageously, the additional tapered surface is of a different magnitude depending on the angle to the horizontal, like the tapered surface. Preferably, the angles of the tapered support surface and the additional tapered support surface are the same or substantially the same to obtain a large contact surface area between them.
    [040] Preferably, the screen support comprises an additional tapered surface with an angle opposite to the tapered surface and at least one intermediate support has an additional tapered support surface with an angle opposite to the tapered support surface, in such a way that in use, the tapered surface and the additional tapered surface abut against the tapered support surface and the additional tapered support surface. Advantageously, the conical surface and the additional conical surface of the screen support diverge from the screen support, preferably being divergent at an acute angle, although it may be at an obtuse angle. Preferably, the tapered support surface and the additional tapered support surface of said intermediate support converge from the intermediate support, advantageously at an acute angle of convergence, although it may be at an obtuse angle.
    [041] The present application also provides a sieve assembly comprising at least one layer of filtration material, a sieve holder and a perimeter with a plurality of support points within the perimeter, characterized by fact that at least one of the support points comprises a conical surface.
    [042] Preferably, the conical surface is on a plane, between ten and eighty degrees from a horizontal plane. Advantageously, the conical surface is on a plane, between forty and seventy degrees from a horizontal plane.
    [043] Advantageously, the sieve assembly comprises an additional tapered surface with an angle opposite to the tapered surface, and at least one intermediate support has an additional tapered support surface with an angle opposite to the tapered supporting surface, such that, in use, the tapered surface and the additional tapered surface abut the tapered support surface and the additional tapered support surface. Preferably, this arrangement prevents lateral movement of said sieve assembly in said basket. Preferably, the additional tapered surface is of the same magnitude as the angle to the horizontal, as the tapered surface. Advantageously, the additional tapered surface is of a different magnitude from the angle to the horizontal, like the tapered surface.
    [044] The present application also provides a shale shaker, comprising a base, a basket isolated from the base, a vibrating device for vibrating the basket and a sieve tray in the basket and a drain tray for directing the filtered drilling mud laden with solids, characterized by the fact that the drain pan comprises at least a raised portion to support the sieve assembly.
    [045] Preferably, the basket further comprises a second sieve tray, with the flow tray directing the drilling fluid loaded with solids.
    [046] The present patent application also provides a method of using the apparatus of the present patent application, the method comprising the step of positioning the sieve assembly in the shale shaker basket, draining the fluid drilling laden with solids in the sieve assembly with at least a fraction of the solids flowing over the sieve assembly and at least a fraction of said drilling fluid flowing through said sieve assembly.
    [047] For a better understanding of the present invention patent application, reference will now be made, by way of example, to the attached drawings, in which: Figure 1 shows a perspective view of an apparatus for the separation of solids a from drilling mud laden with solids; Figure 2A is a schematic cross-sectional side view of an apparatus for separating and dimensioning solids from drilling mud loaded with solids, the apparatus comprising a base and a floating basket on the base; Figure 2B is an end view of the basket illustrated in Figure 2A showing sieve trays and sieve assemblies contained in the trays; Figure 3 is a schematic end view, partly in section of a sieve tray, a drain pan and a sieve assembly; Figure 3A is a top plan view of the flow tray shown in Figure 3; Figure 4 is a schematic end view, partly in section of a sieve tray, a pouring tray and a sieve assembly according to the present patent application; Figure 4A is a top plan view of the flow tray shown in Figure 4; Figure 5 is a schematic end view, partly in section of a sieve tray, a drain pan and a sieve assembly according to the present application, and Figure 6 is an end view. schematic, partly in section of the flow tray shown in Figure 5, spaced from the sieve assembly shown in Figure 5; Figure 6A is a top plan view of the flow tray shown in Figure 5; Figure 6B is a perspective view of the screen assembly shown in Figure 5; Figure 7 is a schematic end view, in cross-section of the screen assembly shown in Figure 5, spaced from a screen tray according to the present patent application; and Figure 8 is a schematic top view of a screen assembly positioned on a drain pan according to the present application.
    [048] Figure 1 shows an apparatus for separating solids from a drilling mud laden with solids, generally referred to as a shale shaker and identified here by reference H. Shale shaker H comprises a base D having a open bottom R disposed over a collection container (not shown) to receive the drilling mud from the screen. A basket B is arranged on springs C on the base D. A vibrating device E is provided at the top of the basket B. The vibrating device E comprises a rotary hydraulic or electric motor N rotating weights of compensating agglomerates hidden within the housing S, which induce movement in basket B. The upper, upper intermediate, lower intermediate and lower Al, A2, A3, A4 sieve assemblies are arranged in basket B and fixed to it in rails (not shown), so that the induced movement in the basket is transferred to the screen sets A1, A2, A3, A4. Drilling fluids laden with solids are fed to the A1-A4 sieve assemblies from a feed chamber F at one end of the apparatus. The movement induced in the A1-A4 sieve sets facilitates the separation of solids from drilling mud. The filtered drilling mud passes through the sieve sets to the collection receiver (not shown) and the solids scale along the sieve sets A1-A4 to a discharge end P from the shale shaker to a container, ditch, or other chip transfer device (not shown).
    [049] Figures 2A and 2B show a shale shaker 10 having a base 20 and a basket 30 arranged on the base on springs (not shown). The basket 30 comprising a screening platform 11, an upper primary platform 12 and a lower primary platform 13. The upper primary platform 12 has a left-handed side 12a and a right-handed side 12b. The lower primary platform has a left-handed side 13a and a right-handed side 13b. Drilling fluids laden with solids are introduced to a feed end of the shale shaker 14 from a feeder (not shown) to a sieving screen 15 arranged in C-shaped channels 16 of the sieving platform 11. A pneumatic bladder expandable 17 is arranged at the top of the C-shaped channels 16 to secure the sieving screen 15 therein. Alternatively, a wedge can be used to fix the sieve screen 15 in the C-shaped channels 16. The sieve screen 15 comprises a sieve 18 with relatively large openings, to inhibit the passage of large particles through the primary platform, but allowing some drilling solids and mud to pass through it. The sieving platform 11 and the sieve 15 arranged on the platform are arranged at an upward inclination of about two degrees from the horizontal plane, although the sifting screen 15 and the sifting platform 11 can be arranged horizontally, at a slightly sloping angle. or slightly higher upward. The vibrating apparatus 16a attached to the basket 30 induces movement within it. The movement facilitates the separation of large solids from the solid-loaded drilling mud and induces movement in the large solids along the sieve screen 15 from the feed end 14 to the discharge end 19 of the shale agitator. Large solids can be captured in a ditch or a means of transport and further transformed or used in other operations. The solid-loaded drilling fluid that passes through the sieve screen 15 falls onto a flow tray 21, which directs the solid-filled drilling fluids to the feed end 14 of the screen assemblies 22a and 22b on the upper primary platform. 12. A dam 23 is arranged at the feed end of the main platform 12 to retain drilling fluids laden with solids. If the level of the solid-filled drilling fluid increases beyond the height of the dam 23, the solid-filled drilling fluids pass over the dam in a duct 24 and over the sieve assemblies 25a and 25b on the lower primary platform 13. The screen sets 22a, 22b and 25a and 25b are preferably of the same type and have the same screen mesh over them.
    [050] A gate valve 26 in the form of a sliding tray, is in a closed position, closing the duct 29, to rotate the shale agitator in a parallel mode. The filtered drilling mud falls through the sieve assemblies 22a and 22b into the upper sieve tray in a drain pan 27 and onto the closed gate valve 26 within a duct 28, which runs in parallel with the duct 24. However, duct 28 leads to the bottom of the basket and directly to the collection container (not shown) below it. The solids fall from the discharge end 31 of the upper sieve tray 12 and the discharge end 32 of the lower sieve tray 13 into a container or other transport apparatus to transport the solids for further processing or reuse.
    [051] The sluice valve 26 can be retracted to allow the filtered drilling mud to pass through the screen assemblies 22a and 22b on the upper screen platform 12 to be further filtered by the screen assemblies 25a and 25b on the platform. bottom sieve 13. The shale shaker thus runs in a serial mode. In this situation, it is preferable to use a finer sieve mesh in the sieve assemblies 25a and 25b than the sieve mesh used in the sieve assemblies 22a and 22b. The drilling mud filtered through the sieve assemblies 22a and 22b on the upper sieve platform 12 flows into the drain pan 27 and into a duct 29, which directs the filtered drilling mud over the feed end of the sieve assemblies 25a and 25b on the lower screen platform 13. Bulky solids fall from the discharge end 31 of the upper screen tray 12 onto a conveyor (not shown), to be transported and mixed in a new batch of drilling mud for recirculation. These bulky solids are used to block the formation of cracks, as described above. The solids discharged from the discharge end 32 of the lower screen platform 13 are transported by a separate conveyor or added to a container for further processing or to be used for other purposes.
    [052] Referring to Figures 3 and 3A, a screen assembly 100 and a drain pan 101 are shown. The drain pan 101 comprises a recess area 102, a closed end 103, an open end 104 and a pair of sides 105 and 106. Sides 105 and 106 comprise flange portions 107 and 108, such flange portions 107 and 108 being slid into C-shaped channels 109 and 110 in the basket 30 attached thereto. Preferably, the flange portions 107 and 108 are glued, or otherwise adhered, to the C-shaped channels 109 and 110, but can be slidably removed from the channels and secured with the sieve assembly 100 by a hose seal expandable pneumatic 111. The recess area 102 can have a substantially flat horizontal base which, when fixed in said C-shaped channels 109 and 110, assumes an inclination equal to the inclination of the sieve assembly 100, which preferably has seven degrees. The tray also has an opening 112 in it. The gate valve 26 of the shale shaker 10 selectively prevents and allows the drilling mud to be filtered through the opening 112.
    [053] Figure 4 shows a screen assembly 200 and a drain pan 201 according to the present application. The drain pan 201 comprises three recess zones 202a, 202b and 202c, a closed end 203, an open end 204 and a pair of sides 205 and 206. The sides 205 and 206 comprise flange portions 207 and 208, such being flange portions 207 and 208 are slid into C-shaped channels 109 and 110 in basket 30 and attached to it. Preferably, the flange portions 207 and 208 are glued, or otherwise adhered, to the C-shaped channels 109 and 110, but can be slidably removed from the channels and fixed with the 200 sieve assembly by means of of an expandable pneumatic hose seal 111. The recess zones 202a, 202b and 202c can have a substantially flat horizontal base which, when fixed in the said channels in the form of C 109 and 110, assumes an inclination equal to the inclination of the set of screen 200, which is preferably seven degrees. The board also has an opening 212 in it. The gate valve 26 of the shale agitator selectively prevents and allows the drilling mud to be filtered through opening 212. A pair of intermediate supports 213 and 214 connects the recess zones 202a, 202b and 202c. The supports 213 and 214 comprise edges 215 and 216 that have the same measure of the length of the drain pan 201. Each edge has a T-shaped connector 217 and 218 fixed to or integrated with the connector, with a wear strip disposed on it . The wear strip can be made of any wear-resistant material, such as HDPE [High-density polyethylene]. The upper part of the wear strips 219 and 220 is slightly above the upper part of the flange portion 207 and 208 of the drain pan, preferably at 2 or 3 mm in the center. The sieve assembly 200 is at the top of the wear strips 219 and 220 and is maintained on the strips by inflating the inflatable pneumatic hose 111 in the C-shaped channels 109 and 110. The structural rigidity of the said drain pan is, therefore, used to support the screen set 200.
    [054] Figures 5 to 6B show a sieve assembly 300 and a drain tray 301 according to the present patent application. Flow tray 301 comprises six recess zones 302a, 302b, 302c, 302d, 302e and 302f, a closed end 303, an open end 304 and a pair of sides 305 and 306. The sides 305 and 306 include flange portions 307 and 308, such flange portions 307 and 308 being slid in the C-shaped channels 109 and 110 in the basket 30 and attached to it. Preferably, the flange portions 307 and 308 are glued, or otherwise adhered, to the C-shaped channels 109 and 110, but can be slidably removed from the channels and fixed with the sieve assembly 300 by means of an expandable pneumatic hose seal 111. The recess zones 302a to 302f can have a substantially flat horizontal base, which, when attached to said C-shaped channels 109 and 110, takes a slope from the discharge end 31 to the feed end 14 of the shale shaker equal to the inclination of the sieve assembly 200, which is preferably seven degrees. The board also has openings 312a, 312b, 312c and 312d in it. The gate valve 26 of the shale shaker 10 selectively prevents and allows the filtered drilling mud to pass through the openings 312a to 312d. Five intermediate supports 313a, 313b, 313d, 313d and 313e connect recess zones 302a to 302e. Only support 313e will be described in detail in this document, but it should be noted that all members of structural support 313a to 313e are described for members of structural support 313e. The support 313 comprises a flange 317 which has the same measurement as the length of the drain tray 301. The flange 317 has a strip 315 fixed or integrated with the flange 317. The strip 315 has two sides, each side having a conical portion 318 and 319. The cone of each conical portion 318, 319 preferably has an acute angle to the plane of the drain pan 301, preferably between ten and eighty degrees, advantageously between forty five and seventy degrees, and more preferably still, from sixty to seventy degrees from a horizontal plane. Each conical portion 318 and 319 has a long T-shaped member 320 and 321 attached to or integrated with the portion, with a wear strip 322 and 323 disposed thereon. The conical portions 318 and 319 each have a cone with an angle of convergence from the flow tray 301. The wear strips 322 and 323 can be made from a wear-resistant material, such as HDPE. An upper part 325 of strip 315 is slightly above the upper part of the flange portion 307 and 308 of the flow tray, preferably at 2 or 3 mm in the central support 313c, from 1 to 2 mm over the adjacent supports 313b and 313d and from 0.5 to 1 mm on the external supports 313a and 313e. Wear strips 322 and 323 have a chamfered portion 324, and the upper part 325 of strip 315 has a light crown. The chamfered portions 324 provide a smooth transition between the upper part 325 and the wear strips 322 and 323.
    [055] The screen assembly 300 comprises a screen holder 340 comprising a perforated plate 351, such as a perforated metal plate or a perforated plastic or perforated composite material. The perforations in the perforated plate 351 can be rectangular, as shown, which are preferred, or any other appropriate shape, such as octagonal, hexagonal, triangular, square, circular. At least one layer of filtration material 299 is adhered to, or otherwise attached to, an upper surface of the perforated plate 351. At least one layer of filtration material 351 can be two layers of filter material with the same mesh size and can be supported on a support layer of filtration material with a larger mesh size and larger gauge cables.
    [056] The screen support 340 comprises external tubular structural elements 352 and 353 along each side of the screen support. Each tubular structural member 352 and 353 has a hollow rectangular cross section. The structural support members 350a to 350e are welded, or otherwise connected, or integrated with the perforated plate 351. Only the structural support members 350a will be described in detail here, although it should be noted that all members of the structural support 350a to 350e are described for the members of the structural support 350a. The structural support member 350a is symmetrical, having a first side 354 and a second side 355, which are mirror images of each other. The first side 354 has an external conical portion 356 arranged in a plane about sixty degrees from a horizontal plane. The upper edge of the outer tapered portion 356 is welded, or otherwise connected, to the perforated plate 351. An inner tapered portion 357 is connected to the other side 355 with a curved portion 358. The inner tapered portion 357 on the inner side 354 and the conical portion 357a on side 355 diverge from the perforated plate 351. The curved portion 358 is formed in such a way that, in use, it sits along the upper crown 325 and chamfered portions 324 of the wear strips 322 of each support 313a to 313e of the flow tray 301. The curved portion 358 is not attached to the perforated plate 351 and remains free, creating a gap between the plate. The lower part 359 is in a plane of about sixty-five degrees from a horizontal plane to conform to an external face of the wear strip 324 in the conical portion 318 of each support from 313a to 313e. The structural support members 350a to 350e further comprise a curved portion 358 that connects the two sides 354 and 355. The structural support members 350a to 350e have a plurality of openings 360 in them to allow fluid to flow through the openings. up to the drain tray 301. The structural support members 350a to 350e can be made from a metal sheet, such as galvanized steel, and can be formed by bending the metal sheet. The 360 openings can be drilled or laser cut into the metal sheet before being folded. Alternatively, the structural support members 350a to 350e can be formed from a composite material, such as a fiber reinforced material such as KEVLAR ™.
    [057] In use, the screen set 300 is inserted into the C-shaped channels 109 and 110 above the drain tray 301. The internal conical portions 357 of the structural support members from 350a to 350e slide along their respective strips wear from 322a to 322e and from 323a to 323e during insertion and then sit on them. The sieve assembly 300 is held in place by inflating the inflatable pneumatic hose 111 into the C-shaped channels 109 and 110. The inflation of the pneumatic hose 111 pushes the sides of the sieve assembly 300 over the flange portions 307 and 308 of the drain pan 301 and the internal conical portions 357 of the structural support members 350a to 350e slide down their respective wear strips 322 and 323 to 323e to obtain a tight fit. The gaps between the upper part of 325a to 325e and the screen support probably exist due to tolerances in the relative size and location of the structural support members from 350a to 350e and the supports 313a to 313e of the drain tray 301. However, the contact of the internal conical portions 357 of the structural support members from 350a to 350e and their respective wear strips 322 and 323 provides a large contact area that supports the screen set 300. In addition, the screen set 300 is prevented from movement side on the shale shaker basket 30.
    [058] Figure 7 shows the screen set 300 shown in Figures 5 to Figure 6B, with a drain pan 401. The drain pan 401 comprises six recess zones 402a, 402b, 402c, 402d, 402e and 402f to facilitate the flow of drilling fluid along the tray, the distal end 403, an open end 404 and a pair of sides 405 and 406. The sides 405 and 406 comprise flange portions 407 and 408, such flange portions 407 and 408 are slid in C-shaped channels 109 and 110 in basket 30 and attached to it. Preferably, flange portions 307 and 308 are glued, or otherwise adhered, to the C-shaped channels 109 and 110 and can be riveted or mechanically fixed, but can be slidably removed from the channels and attached to the assembly 300 sieve through an expandable pneumatic hose seal 111. The recess zones 402a to 402f have a wavy profile that is shaped like a deep cone from distal end 403 to open end 404, which has a slope from the discharge end 31 to the feed end 14 of the shale shaker greater than the slope of the sieve assembly 300. The slope of the sieve assembly can be adjustable between ten degrees up and one degree down, but it is preferably set at seven degrees above. The drain pan 401 also has an opening (not shown) inside. The gate valve 26 of the shale shaker 10 selectively prevents and allows the filtered drilling mud to drain through the opening. Five intermediate supports 413a, 413b, 413c, 413d and 413e connect to recess zones 402a to 402e. The flow tray 401 is preferably formed in a mold with composite material, such as, for example, KEVLAR ™. Only support 413e will be described in detail, but it should be noted that all members of structural support from 413a to 413e are the same as those described for members of structural support 413e. The support 413 comprises a molded rim 417 on the composite drain tray 401, which is the same measure as the length of the drain tray 401. The rim 417 has a strip 415 fixed or integrated with the rim 417. The strip 415 has two sides, each side having a conical portion 418 and 419. The cone of each conical portion 418, 419 is preferably between ten and eighty degrees, and preferably between forty five and seventy degrees, and most preferably still , from sixty to seventy degrees from a horizontal plane. Each conical portion 418 and 419 has, along the portion, a T-shaped member 420 and 421 attached to or integrated with the portion, with a wear strip 422 and 423 disposed thereon. Wear strips 422 and 423 can be made from a wear resistant material, such as HDPE. The upper part 425 of the strip 415 is slightly above the upper part of the flange portion 407 and 408 of the flow tray, preferably 1 to 3 mm. Wear strips 422 and 423 have a chamfered portion 424, and the upper part 425 of strip 415 has a slight crown. The chamfered portions 424 provide a smooth transition between the upper part 425 and the wear strips 422 and 423.
    [059] Figure 8 shows a sieve set of 500 and a drain pan 501. The drain pan 501 comprises six recess zones 502a, 502b, 502c, 502d, 502e and 502f to facilitate the flow of drilling fluid to the along the tray, a distal end 503, an open end 504 and a pair of sides 505 and 506. Sides 505 and 506 comprise flange portions 507 and 508, such flange portions 507 and 508 being slid into the channels in shape of C in the basket and fixed in it, as previously described. Preferably, the flange portions 507 and 508 are glued, or otherwise adhered, to the C-shaped channels and can be riveted or mechanically fixed, but they can be slidably removed from the channels and fixed with the sieve assembly 500 by an expandable pneumatic hose seal. The recessed areas 502a to 502f have a wavy profile that is shaped like a deep cone from the distal end 503 to the open end 504, which has a slope from the discharge end 31 to the feed end 14 of the shale shaker greater than the inclination of the sieve assembly 500. The inclination of the sieve assembly can be adjustable between ten degrees upwards and one degree downwards, but is preferably fixed seven degrees upwards. The drain pan 501 also has an opening (not shown) inside. The gate valve 26 of the shale shaker 10 selectively prevents and allows the drilling mud to be filtered through the opening. The screen assembly comprises at least one layer of filtration material 509 in a support structure 510. The support structure comprises a frame 511. The drain pan 501 is preferably formed in a mold with a composite material such as KEVLAR ™.
    [060] In use, the sieve assembly 500 is inserted into the C-shaped channels 109 and 110 above the drain pan 501. Five support ribs 512a to 512e, each having a wear strip are welded, glued or otherwise attached to the flat ridge tops 513a and 513e of the flow tray. The upper surface of the support ribs 512a to 512e are preferably on a plane that is 1 to 3 mm above the plane of the upper part of the flanges 507 and 508. The support structure 510 of the sieve assembly 500 is it rests on the five support ribs 512a to 512e. The sieve assembly 500 is held in place by inflating the inflatable pneumatic hose 111 into the C-shaped channels 109 and 110. The inflation of the pneumatic hose 111 pushes the sides of the sieve assembly 500 over the flange portions 507 and 508 of the drain tray 501.
    权利要求:
    Claims (19)
    [0001]
    1. "SOLID SEPARATION DEVICE FROM SOLID DRILLED DRILLING FLUIDS", the apparatus consisting of: a shale shaker (H) and a sieve set (300), the shale shaker (H) having a basket (B) and a vibrating mechanism for vibrating the basket (B), the basket (B) having lateral supports (109,110) and at least one longitudinal intermediate support (313 ae) disposed between said lateral supports (109,110), the sieve assembly (300) having a sieve holder (340) that supports at least one layer of sieving material (299), the sieve holder (340) having a length of at least two sides (352 , 353) parallel to the length of the screen support (340) and at least one longitudinal support component (350 ae) parallel to the length of the screen support (340) between said side parts (352, 353) for engagement with said intermediate longitudinal supports and at least two side parts (352, 353) supported by said links lateral supports (109,110); characterized in that at least one longitudinal support component (350 ae) is connected to a lower surface of the screen support (340), at least one longitudinal support component (350 ae) having a tapered surface (357a) and a additional tapered surface (357a) at an angle opposite to said tapered surface (357a) along the length of the sieve holder (340), wherein the tapered surface (357a) and the additional tapered surface (357a) are connected by one part curved and in which the part of the conical surface (357a) and the part of the additional conical surface (357a) extend beyond the lower surface of the screen support (340); and wherein at least one longitudinal intermediate support (313 ae) has a tapered support surface (318), an additional tapered support surface (319) at an angle opposite to said tapered support surface (318) and a strip , having an upper part crowned between them, in which the conical surface (357a) and the additional conical surface (357a) correspond to the conical support surface (318) and the additional conical support surface (319) of at least one longitudinal intermediate support (313 ae) for continuous surface-to-surface engagement between them along the length of the screen support (340) and in which the curved part is shaped to fit over the crowned upper part of at least one intermediate support longitudinal (313 ae).
    [0002]
    2. "APPLIANCE FOR SEPARATING SOLIDS FROM DRILLING FLUIDS LOADED WITH SOLIDS", according to claim 1, characterized by said conical surface (357a) and said additional conical surface (357a) of at least one component longitudinal support (350 ae) diverge from the sieve support (340).
    [0003]
    3. "SOLID SEPARATION DEVICE FROM SOLID DRILLED DRILLING FLUIDS", according to claim 1, characterized by said conical support surface (318) and said additional conical support surface (319) of, at least at least, a longitudinal intermediate support (313 ae) converge from said sieve support (340).
    [0004]
    4. "APPLIANCE FOR THE SEPARATION OF SOLIDS FROM DRILLING FLUIDS LOADED WITH SOLIDS", according to claim 1, characterized in that the set of sieve (300) also consists of: a perimeter with a plurality of support points within the perimeter; wherein at least one of said support points has a tapered surface (357a) and an additional tapered surface (357a) at an angle opposite the tapered surface (357a).
    [0005]
    5. "APPLIANCE FOR SEPARATION OF SOLIDS FROM DRILLING FLUIDS LOADED WITH SOLIDS", according to claim 4, characterized by said conical surface (357a) and said additional conical surface (357a) diverging from said support of sieve (340).
    [0006]
    6. "APPLIANCE FOR THE SEPARATION OF SOLIDS FROM DRILLING FLUIDS LOADED WITH SOLIDS", according to claim 4, characterized by the conical surface (357a) being in a plane that is between ten and eighty degrees from the horizontal .
    [0007]
    7. "APPLIANCE FOR THE SEPARATION OF SOLIDS FROM DRILLING FLUIDS LOADED WITH SOLIDS", according to claim 4, characterized by the conical surface (357a) being on a plane that is between forty and seventy degrees from the horizontal .
    [0008]
    8. "METHOD OF USING THE APPLIANCE FOR SEPARATING SOLIDS FROM DRILLING FLUIDS LOADED WITH SOLIDS", for the use of the apparatus defined in claim 1, the method consisting of: placing the sieve set (300) in the basket (B) of the shale shaker (H), characterized by the conical surface (357a) and the additional conical surface (357a) at an angle opposite the conical surface (357a) touching the conical support surface (318) and the additional conical support surface ( 319) corresponding at an angle opposite to the conical support surface (318); flowing the solid-loaded drilling fluid to the sieve assembly (300) with at least a part of the solids flowing over the sieve assembly (300) and at least a part of said drilling fluid passing through said screen set (300).
    [0009]
    9. "APPLIANCE FOR THE SEPARATION OF SOLIDS FROM DRILLING FLUIDS LOADED WITH SOLIDS" according to claim 1, characterized in that at least one intermediate support consists of at least an elevated part of a flow tray ( 301).
    [0010]
    10. "APPLIANCE FOR SEPARATION OF SOLIDS FROM DRILLING FLUIDS LOADED WITH SOLIDS", according to claim 9, characterized in that the basket (B) also has a second sieving platform (A2), the flow tray ( 301) directing the solid-loaded drilling fluid to it.
    [0011]
    11. "APPLIANCE FOR THE SEPARATION OF SOLIDS FROM DRILLING FLUIDS LOADED WITH SOLIDS", according to claim 4, characterized by said conical surface (357a) and said additional conical surface (357a) being formed of a laminated material.
    [0012]
    12. "SCREEN SET", for a shale shaker (H) of the apparatus defined in claim 1, the sieve set (300) consisting of: a sieve holder (340) to support at least one layer of material for sieving (299), the sieve assembly (300) having a length with two sides substantially parallel to the length of the sieve assembly (300); and characterized in that the screen assembly also has a plurality of longitudinal structural support components connected to a lower surface of the screen assembly (300) between said two sides and arranged substantially parallel to the length of the screen assembly (300), at least , one of the longitudinal structural support components having a tapered surface (357a) and an additional tapered surface (357a) at an angle opposite to said tapered surface (357a) along the length of the screen assembly (300), on which the surface taper (357a) and the additional taper surface (357a) are joined by a curved part, where a part of the tapered surface (357a) and a part of the additional tapered surface (357a) extend beyond the bottom surface of the screen support (340), wherein the tapered surface (357a) and the additional tapered surface (357a) correspond to a tapered support surface (318) and an additional tapered support surface (319) of, by at least, a longitudinal intermediate support (313 ae) for continuous engagement surface to surface between them along the length of the screen support (340) and in which the curved part is shaped to fit over the crowned upper part of at least , a longitudinal intermediate support (313 ae).
    [0013]
    13. "SCREEN ASSEMBLY" according to claim 12, characterized in that the screen holder (340) is a flat panel with openings therein.
    [0014]
    14. "SCREEN SET" according to claim 12, characterized in that said additional conical surface (357a) diverges from said conical surface (357a).
    [0015]
    15. "SCREEN ASSEMBLY" according to claim 12, characterized in that said additional conical surface (357a) is at an angle opposite to the conical surface (357a).
    [0016]
    16. "SCREEN SET" according to claim 12, characterized in that the conical surface (357a) is on a plane that is between ten and eighty degrees from the horizontal.
    [0017]
    17. "SCREEN SET" according to claim 12, characterized in that the conical surface (357a) is on a plane that is between forty and seventy degrees from the horizontal.
    [0018]
    18. "SCREEN ASSEMBLY" according to claim 12, characterized in that said conical surface (357a) is formed of a laminated material.
    [0019]
    19. "SCREEN ASSEMBLY" according to claim 12, characterized in that said conical surface (357a) has openings in it.
    类似技术:
    公开号 | 公开日 | 专利标题
    BR112012025909B1|2020-11-03|apparatus for separating solids from drilling fluids loaded with solids, sieve assembly, and method of using the apparatus for separating solids from drilling fluids loaded with solids
    AU2014204539B2|2017-10-26|Apparatus for separating solids from a solids laden drilling fluid
    EP2667979B1|2016-08-10|Screen assembly and a method for making a structure for the screen assembly
    GB2497873A|2013-06-26|Method for making a screen support assembly
    GB2486847A|2012-06-27|Apparatus and method for separating solids from a solid laden drilling fluid
    AU2014200462B2|2015-09-17|Apparatus and method for separating solids from a solids laden drilling fluid
    AU2015202231B2|2016-05-19|Screen assembly and a method for making same
    同族专利:
    公开号 | 公开日
    KR101468286B1|2014-12-03|
    BR112012025909A2|2016-06-28|
    DK2563528T3|2016-05-09|
    US20180028947A1|2018-02-01|
    MX2012012411A|2012-12-17|
    EP2656928A1|2013-10-30|
    US10799817B2|2020-10-13|
    KR20130031830A|2013-03-29|
    EP2563528A1|2013-03-06|
    AU2011247066A1|2012-11-01|
    GB2479919A|2011-11-02|
    CN102869458A|2013-01-09|
    SG185420A1|2012-12-28|
    WO2011135320A1|2011-11-03|
    GB201007165D0|2010-06-09|
    US9815005B2|2017-11-14|
    US20200353387A1|2020-11-12|
    MX354707B|2018-03-16|
    AU2011247066B2|2014-03-06|
    CA2795505A1|2011-11-03|
    GB2479919B|2012-10-03|
    MY152986A|2014-12-15|
    CA2795505C|2016-06-14|
    CN102869458B|2015-12-02|
    MX353016B|2017-12-18|
    CN104695880A|2015-06-10|
    US20130105412A1|2013-05-02|
    EP2563528B1|2016-03-02|
    CN104695880B|2017-08-08|
    EP2656928B1|2020-11-04|
    CA2842843C|2016-08-16|
    SG2014007835A|2014-04-28|
    CA2842843A1|2011-11-03|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US2285348A|1940-06-26|1942-06-02|S S Bruce|Material separator apparatus|
    GB1526663A|1977-04-25|1978-09-27|Derrick Mfg Corp|Vibratory screening apparatus for finely divided material|
    GB1578948A|1977-10-26|1980-11-12|United Wire Group Ltd|Sifting screens|
    US4288320A|1980-05-05|1981-09-08|Litton Systems, Inc.|Vibrating screen with screen deck unclogging mechanism|
    GB8514982D0|1985-06-13|1985-07-17|Thule United Ltd|Screen clamping|
    GB2206501B|1987-07-07|1990-11-21|Thule United Ltd|Filtering screens|
    US4923597A|1989-01-13|1990-05-08|Anderson Don W|Portable screen with raising and levelling system|
    US5203460A|1992-04-01|1993-04-20|Deister Machine Co., Inc.|Tension control apparatus for vibrating screens|
    US5265730A|1992-04-06|1993-11-30|Sweco, Incorporated|Vibratory screen separator|
    US6454099B1|1993-04-30|2002-09-24|Varco I/P, Inc|Vibrator separator screens|
    US6267247B1|1993-04-30|2001-07-31|Tuboscope I/P, Inc.|Vibratory separator screen|
    US5641070A|1995-04-26|1997-06-24|Environmental Procedures, Inc.|Shale shaker|
    US5690826A|1996-05-10|1997-11-25|Cravello; William Myron|Shaker screen assembly|
    AU711860B2|1996-10-15|1999-10-21|Varco I/P Inc.|Improved vibratory screening machine|
    BR9914733A|1998-10-21|2001-07-03|Manorex Ltd|Vibrator set|
    NO312339B1|2000-04-07|2002-04-29|Sb Rotashake As|Device for separating solids from a fluid mass|
    US6672459B1|2001-04-04|2004-01-06|Southwestern Wire Cloth, Inc.|Integrated terminal deck and spout for vibrating separator and method of fabrication|
    US7942272B2|2001-08-10|2011-05-17|Axiom Process Ltd.|Screen system|
    GB0119523D0|2001-08-10|2001-10-03|Ever 1529 Ltd|Screen system|
    US20030168387A1|2002-03-08|2003-09-11|Weatherford/Lamb, Inc.|Screen panel and method of manufacturing same|
    US7571817B2|2002-11-06|2009-08-11|Varco I/P, Inc.|Automatic separator or shaker with electromagnetic vibrator apparatus|
    GB2394196A|2002-10-17|2004-04-21|Varco Int|Screen assembly for a shale shaker|
    GB0302927D0|2003-02-08|2003-03-12|Axiom Process Ltd|Screen mounting system|
    US20070108106A1|2005-11-16|2007-05-17|Burnett George A|Shakers with primary and auxiliary vibrators|
    US8453844B2|2003-06-12|2013-06-04|Axiom Process Ltd.|Screening system|
    US7344032B2|2004-06-14|2008-03-18|Action Equipment Company, Inc.|Flexible sieve mat screening apparatus|
    US7753213B2|2006-03-30|2010-07-13|M-I Llc|Composite screen|
    KR100878843B1|2008-01-02|2009-01-15|주식회사 이지엠|Vibrating screen having easily changable screens|
    US20090206011A1|2008-02-20|2009-08-20|Cudahy George F|Vibrating Screen Apparatus|
    US8113356B2|2008-10-10|2012-02-14|National Oilwell Varco L.P.|Systems and methods for the recovery of lost circulation and similar material|
    US8556083B2|2008-10-10|2013-10-15|National Oilwell Varco L.P.|Shale shakers with selective series/parallel flow path conversion|
    DE102009051946A1|2009-11-04|2011-05-05|Ludwig Krieger Draht- Und Kunststofferzeugnisse Gmbh|screening machine|GB2490647B|2011-01-27|2013-05-22|Nat Oilwell Varco Lp|Screen assembly and a method for making same|
    GB2517641B|2012-06-11|2017-06-14|M-I L L C|Shaker screen assembly|
    WO2014065670A1|2012-10-23|2014-05-01|Optipro As|Shale shaker with a filter pack adapter|
    CN103302026A|2013-05-17|2013-09-18|平湖市海特合金有限公司|Vibrating screen with reinforced bracket|
    WO2015024012A1|2013-08-16|2015-02-19|M-I L.L.C.|Separator and method of separation with a pressure differential device|
    US10704346B2|2013-11-26|2020-07-07|M-I L.L.C.|Apparatus, system and method for separating components of a slurry|
    KR101580978B1|2014-03-21|2015-12-31|삼성중공업 주식회사|Shale shakers for mud treatment|
    GB201407872D0|2014-05-02|2014-06-18|Bailey Marshall G|Screening apparatus and method|
    WO2016168375A1|2015-04-15|2016-10-20|Schlumberger Norge As|Method and system for fluid level measurement|
    US10533385B2|2015-06-05|2020-01-14|Drilling Fluids Treatment Systems Inc.|Dual deck vibratory separator|
    KR101672012B1|2015-09-16|2016-11-02|삼성중공업 주식회사|Shale shakers for mud treatment|
    CA2959851A1|2016-03-03|2017-09-03|Recovery Energy Services Inc.|Gas tight shale shaker for enhanced drilling fluid recovery and drilled solids washing|
    KR101801712B1|2016-09-28|2017-11-27|삼성중공업 주식회사|Shale Shaker|
    JP2019533573A|2016-10-14|2019-11-21|デリック・コーポレーション|Apparatus, method and system for vibrating sieve|
    WO2018146089A1|2017-02-07|2018-08-16|Bühler AG|Receiving arrangement for a screen frame and bulk material screening apparatus having such a receiving arrangement|
    US10456810B2|2017-10-27|2019-10-29|M-I L.L.C.|Inflation-activated separator screen|
    CN112974223A|2021-02-07|2021-06-18|中海油田服务股份有限公司|Sorting vibrating screen and dry-wet material distributing equipment|
    法律状态:
    2019-01-08| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|
    2020-04-14| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|
    2020-11-03| 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 24/03/2011, OBSERVADAS AS CONDICOES LEGAIS. |
    优先权:
    申请号 | 申请日 | 专利标题
    GB1007165.2A|GB2479919B|2010-04-29|2010-04-29|Apparatus and method for separating solids from a solids laden drilling fluid|
    GB1007165.2|2010-04-29|
    PCT/GB2011/050599|WO2011135320A1|2010-04-29|2011-03-24|Apparatus and method for separating solids from a solids laden drilling fluid|
    [返回顶部]