1. Field of the Invention
The present invention relates to a screen assembly, for a shale shaker, a panel for a screen assembly, a support structure for a screen assembly, a shale shaker comprising a screen assembly, a shale shaker comprising a support structure and a method for fitting a screen assembly into a shale shaker.
2. Description of the Related Art
In the drilling of a borehole in the construction of an oil or gas well, a drill bit is arranged on the end of a drill string and is rotated to bore the borehole. A drilling fluid known as “drilling mud” is pumped through the drill string to the drill bit to lubricate the drill bit. The drilling mud is also used to carry the cuttings produced by the drill bit and other solids to the surface through an annulus formed between the drill string and the borehole. The drilling mud contains expensive synthetic oil-based lubricants and it is normal therefore to recover and re-use the used drilling mud, but this requires the solids, to be removed from the drilling mud. This is achieved by processing the drilling fluid. The first part of the process is to separate the solids from the solids laden drilling mud. This is at least partly achieved with a shale shaker, such as those disclosed in U.S. Pat. No. 5,265,730, WO 96/33792 and WO 98/16328.
Shale shakers generally comprise an open bottomed basket having one open discharge end and a solid walled feed end. A number of rectangular screens are arranged in the basket, which are held in C-channel rails located on the basket walls, such as those disclosed in GB-A-2,176,424. The basket is arranged on springs above a receptor for receiving recovered drilling mud. A skip or ditch is provided beneath the open discharge end of the basket. A motor is fixed to the basket, which has a drive rotor provided with an offset clump weight. In use, the motor rotates the rotor and the offset clump weight, which causes the basket and the screens fixed thereto to shake. Solids laden mud is introduced at the feed end of the basket on to the screens. The shaking motion induces the solids to move along the screens towards the open discharge end. The recovered drilling mud is received in the receptor for further processing and the solids pass over the discharge end of the basket into the ditch or skip.
The screens are generally of one of two types: hook-strip; and pre-tensioned.
The hook-strip type of screen comprises several rectangular layers of mesh in a sandwich, usually comprising one or two layers of fine grade mesh and a supporting mesh having larger mesh holes and heavier gauge wire. The layers of mesh are joined at each side edge by a strip which is in the form of an elongate hook. In use, the elongate hook is hooked on to a tensioning device arranged along each side of a shale shaker. The shale shaker further comprises a crowned set of supporting members, which run along the length of the basket of the shaker, over which the layers of mesh are tensioned. An example of this type of screen is disclosed in GB-A-1,526,663. The supporting mesh may be provided with or replaced by a panel having apertures therein.
The pre-tensioned type of screen comprises several rectangular layers of mesh, usually comprising one or two layers of fine grade mesh and a supporting mesh having larger mesh holes and heavier gauge wire. The layers of mesh are pre-tensioned on a rigid support comprising a rectangular angle iron frame and adhered thereto. The screen is then inserted into C-channel rails arranged in a basket of a shale shaker. An example of this type of screen is disclosed in GB-A-1,578,948.
A further example of a known rigid support is disclosed in WO 01/76719, which discloses, amongst other things, a flat panel like portion having apertures therein and wing portions which are folded to form a support structure, which may be made from a single sheet of material. This rigid support has been assigned the Trade Mark “UNIBODY” by the applicants.
European Patent Publication Number 1 002 588, discloses a panel comprising a plurality of groups of perforations, each group comprising six generally equally triangular apertures arranged with their apices facing a central portion, wherein the apices of two opposing ones of said triangular apertures are spaced apart further than the apices of opposed ones of the remaining triangular apertures.
The layers of mesh in the screens wears out frequently and therefore needs to be easily replaceable. Shale shakers are generally in the order of 5 ft wide and 10 ft long. A screen of dimensions 4 ft wide by 10 ft long is difficult to handle, replace and transport. It is known to use two, three, four or more screens in a single shale shaker. A standard size of screen currently used is of the order of 4 ft by 3 ft. A pre-tensioned type of screen is generally easier and faster to replace than the hook strip type, as the layers of screening material do not need to be tensioned in the shale shaker. A pre-tensioned type of screen is especially easily and quickly replaceable when used in a shale shaker having rails provided with inflatable bladders, such as those disclosed in GB-A-2,176,424 to clamp the pre-tensioned type of screen in place.
The inventor has noted that the support structure for the screen assembly has to be very rigid. It is known to strip the layers of mesh off used screen assemblies and to replace the worn layers of mesh. However, this is a time consuming process conducted in a workshop. The inventor has also noted that all of the screen assembly need not be replaced. In one aspect, the present invention attempts to provide a screen assembly to replace a known screen assembly of the pre-tensioned type.
The present invention also attempts to provide a panel for a screen, which will increase the life of layers of screening material arranged thereon.
The present invention also attempts to retain rigidity in the screen assembly, whilst being easy to replace.
In accordance with the present invention, there is provided a screen assembly for a shale shaker, the screen assembly comprising a panel and a support structure, the panel having an area provided with a multiplicity of apertures and at least one layer of screening material arranged over the multiplicity of apertures, the panel further comprising at least one support rib characterised in that said panel is removable from said support structure and wherein at least one member is arranged between said panel and said support structure within the perimeter of said panel over which said at least one support rib and said panel is deflectable, such that at least two spans are defined by said panel. The layers of screening material are the most likely components of a screen assembly to fail in use. A screen assembly of the present invention allows replacement of the panel with layers of screening material attached thereto, without having to replace the entire screen assembly. It has been noted that a replaceable screen support is friendlier to the environment, as only the panel and worn layers of screening material need be sent for recycling and the screen support be reused on site.
Preferably, the support structure is removable from said shale shaker. Advantageously, the screen assembly is insertable into a clamping mechanism of a shale shaker. Advantageously, the panel has a perimeter, at least part of which, in use is arranged in the clamping mechanism and is pushed on to the support structure when operated.
Preferably, the at least one member is arranged substantially centrally such that the panel has at least two distinct screening areas, the at least two distinct areas have half the free span between fixing points, which in the case of the VSM 300 brand shale shaker sold by Varco limited, is between the two side rails. By reducing the span by half, the rigidity of the screen assembly can be reduced proportionally by a much greater amount. Accordingly, the screen assembly can be made much lighter, as less of the same material is required. Hence a reinforced screen panel is suitable in combination with a rigid support structure providing the support member.
Advantageously, at least one of the support structure and the panel comprises the member over which the panel is deflectable in use. Most preferably, the member is rigidly fixed support structure and/or the panel. Preferably, the support structure comprises a structural support member and the panel comprises a corresponding support member, which engage or co-operate to form a member over which the panel is deflectable in use. Advantageously, one of the structural support member and the support member has a convex rounded profile and the other has a corresponding concave rounded profile. The support member and structural support member may be formed to co-operate to allow slight movement to facilitate deflection of the panel over the support member and/or to facilitate location of the panel on to the support structure. It is important to provide means for the user to facilitate location of the panel over the support structure accurately so that downward force provided by the fixing means in the shale shaker, preferably an inflatable bladder or wedges, will properly fix the panel in the shale shaker. An interface is provided at the front end and back end of the panel, which may facilitate proper location of the panel over the support structure by abutting an adjacent screen or an interface means provided in the shale shaker. The interface may also facilitate sealing between panel to inhibit particles passing between screens and through interfaces.
Advantageously, the structural support member comprises a bar or tube extending across a substantial portion of the structural support. The structural support preferably extends along the entire length of the panel. The structural support member may comprise a square, oblong, triangular or circular section bar or tube.
Preferably, the support member comprises portions having openings therein. The openings advantageously allow fluid and small particles to flow through the openings. The openings also reduces the overall weight of the panel.
The panel may take the form of a rectangle or a circle. Preferably, the panel is rectangular having a pair of opposing sides and a pair of opposing ends, wherein the part of the perimeter is the two opposing sides.
Advantageously, the member is arranged equidistant the two opposing sides and is arranged substantially parallel to the two opposing sides. The member is arranged substantially centrally such that the panel has at least two distinct areas, the at least two distinct areas having half the free span between fixing points.
Preferably, two support members are arranged between the two opposing sides and are arranged substantially parallel to the two opposing sides. Each of the two members is preferably arranged approximately a third the way along the free span between the two sides, such that the panel has at least three distinct areas, the at least three distinct areas having a third the free span between fixing points.
Advantageously, the structural support comprises an outer frame and cross members. The outer frame and cross members are preferably made from steel tubing of square or circular cross section and are advantageously welded together at the junctures.
Preferably, the panel comprises a perforate plate, the multiplicity of apertures therein. Advantageously, the panel comprises a flat plate which may be of mild steel, aluminium or a plastics material. The apertures may be punched out, drilled, cast or cut out with a laser or saw.
Preferably, the panel comprises at least one support rib. In a rectangular screen, the ribs are arranged between sides preferably to increase rigidity across the screen, although the ribs are considerably smaller than for a screen assembly spanning the full distance between sides. The inherent rigidity of the panel must be equal or greater than the rigidity of a standard screen assembly designed to be held free between the two opposed side rails when arranged in the shaker in use, but can be much less rigid when not in use: between a third and a quarter as rigid when a single centrally mounted member is used and between a ninth and a sixteenth of the rigidity with two members arranged at approximately evenly spaced intervals across the width of the panel. Advantageously, the support rib is fixed to the perforate plate. Preferably, a multiplicity of the support ribs extend across the panel. Advantageously, the perforate plate comprises a series of panel ribs formed in the perforate plate, the support ribs aligned with and underneath the panel ribs.
Preferably, the panel comprises folded portions. Advantageously, the folded portions are perimeter portions. The folded perimeter portions may be located along the sides of a rectangular panel, which may increase the rigidity of the panel. The folded portions may be located at the ends of a rectangular panel, which may be folded to increase the rigidity of the panel and also to provide an interface between adjacent panels or to provide a holder for a seal for an interface between adjacent panels.
Advantageously, the folded portions form the apertures. The folded portions may form flanges which increase the overall rigidity of the panel, especially if all or a substantial number of the apertures are formed in this way.
Preferably, the panel has side portions, which are not provided with apertures. In a shale shaker provided with inflatable bladders or wedges as means for fixing the screen assembly in the shale shaker, the side portions are blinded by the means.
Advantageously, the at least one layer of screening material is adhered to the side portions of the perforate plate. Preferably, the at least one layer of screening material is adhered to at least a portion of the perforate plate. Advantageously, the at least one layer of screening material is adhered to the area provided with apertures. Preferably, the panel further comprises a second layer of screening material of substantially the same mesh size. Advantageously, a coarse mesh backing screen is arranged between the at least one layer of screening material and the perforate plate. The coarse mesh backing screen may have larger openings and larger wires to support the screening material.
Preferably, the support structure comprises a plurality of support ribs on which, in use the panel is pushed on to. Advantageously, the support structure has a crowned profile and the panel is pushed down over the support structure by a clamping mechanism at an outer perimeter of the panel. Preferably, the panel is semi-flexible, preferably such that the panel may change shape when a force is applied to it by the clamping mechanism of the shale shaker. The clamping mechanism may provide a tonne of force over the side edges of the screen assemblies arranged in the shale shaker, which may cover 3 to 12 m over 1 to 2 cm in width through a pneumatic hose. Advantageously, the panel is flexible, wherein it is easy to apply the layers of screening material to the panel and a tension in the layers of screening material is held by the panel, advantageously, such that the panel does not bend under then tension in the layers of screening material. Advantageously, wherein it is easy to transport the panel with at least one layer of screening material arranged thereon.
The present invention also provides a shale shaker comprising a screen assembly of the invention, the shale shaker comprising a basket, a vibratory mechanism and a clamping mechanism for fixing the screen assembly to the basket. Preferably, the clamping mechanism firmly fixes the panel to the support structure. Advantageously, the clamping mechanism comprises a pneumatic means. Preferably, the pneumatic means comprises a pneumatic hose. Alternatively, a hydraulic hose could be utilized and preferably, provided with an accumulator.
The present invention also provides a method for fitting a screen assembly in a shale shaker, the screen assembly comprising a panel having at least one layer of mesh thereon and a support structure, the panel further comprising at least one support rib arranged, the method comprising the steps of inserting the screen assembly into a clamping mechanism of a shale shaker, operating the clamping mechanism wherein at least part of a perimeter of said panel of said screen assembly is pushed down over at least one member arranged within the perimeter of the panel such that the at least one support rib and the panel is deflected over the at least one member to define at least two spans.
For a better understanding of the present invention, reference will now be made, by way of example, to the accompanying drawings, in which:
Referring to
Referring to
The panel 101 is formed from a blank shown in
The area 106 of the blank shown in
Referring back to
Similarly, circular opening 165 is drilled, punched, laser cut or otherwise formed in the panel 101 between vertices 166, 167, 168, 169, 170 and 171 of forward pointing triangular aperture 140, rearward pointing triangular aperture 172, forward pointing triangular aperture 173, rearward pointing triangular aperture 174, forward pointing triangular aperture 175, and rearward pointing triangular aperture 147 respectively.
Referring to
Referring to
Referring to
The screen assembly 100 is assembled by sliding the inverted T-shape rails 176 and 177 of the panel 101 into the receiving rails 198 and 199 of the pull down member 103. The pull down member 103 is located in the support structure 102. The ribs 178 to 189 are inserted into support ribs 202 to 213. End ribs 178 and 189 are inserted inside support ribs 202 and 213. Rib 179 is arranged one interval from support rib 203 and one interval from support rib 204; Rib 180 is arranged one interval from support rib 204 and one interval from support rib 205; rib 181 is arranged one interval from support rib 205 and one interval from support rib 206; rib 182 is arranged one interval from support rib 206 and one interval from support rib 207; rib 183 is arranged one interval from support rib 207 and one interval from support rib 208; rib 184 is arranged one interval from support rib 208 and one interval from support rib 209; rib 185 is arranged one interval from support rib 209 and one interval from support rib 210; rib 186 is arranged one interval from support rib 210 and one interval from support rib 211; rib 187 is arranged one interval from support rib 211 and one interval from support rib 212; rib 188 is arranged one interval from support rib 212 and one interval from support rib 213 and slightly less than one interval from rib 189. The support ribs 203 to 212 align underneath the lines of panel ribs 226 to 235 between structural portions folded to form the edge of the apertures. Support rib 202 aligns with line of panel ribs 236 and support rib 213 aligns with line of panel ribs 237.
The panel 101 has at least one layer screening mesh arranged thereon. The layer of screening mesh may be tensioned and adhered to the outer perimeter of the panel 101 and to all of the panel ribs. Preferably, at least three layers are applied. The layers may be of the same mesh grade or of different mesh grades. Preferably, a layer of screening mesh having larger openings and larger wires lies beneath layers of fine mesh.
In use, the screen assembly 100 having layers of mesh (not shown) arranged on the panel, is slid into clamping rails 104 and 105 of a shale shaker. The clamping rails 104 and 105 comprise a C-shape rail 240 and 241 having a bottom surface 242 and 243 on which the support structure 102 of the screen assembly 100 rests. The C-shape rail 240 and 241 also has a pneumatically inflatable bladder 244 and 245 fixed to an upper part 246 and 247 of the C-shape rail. The inflatable bladder 244, 245 is inflated which pushes down on side portions 107 and 108 of the panel 101, pushing the panel 101 on to the top edges 225 of the twelve supporting ribs 202 to 213. The pneumatic bladder also engages side runners 196 and 197 of the pull down member 103, which pushes the pull down member 103 downwardly, pulling the inverted T-shape rails downwardly within recesses 223 and 224. The panel 101 is pulled down along the inverted T-shape rail to pull the panel 101 down on to the supporting ribs 202 to 213. The supporting ribs 202 to 213 lie underneath the circular openings 119, 165, which partially blinds the openings, however, this is not significant as the ribs are below the level of the top surface of the layers of screening mesh.
The downwardly folded wings 114 and 115 of the panel 101 locate over the ends of the supporting ribs 202 to 213 and forward end portion 116 and rear end portion 117 are located over supporting rib 213 and 202.
Drilling mud having solids entrained therein is introduced at a feed end of the shale shaker and is shaken along the layers of mesh on the screen assembly. Fluid and small particles pass through the layers of mesh on the screen and through the triangular apertures and the circular openings in the panel 101 and past the pull down member 103 and the support structure 102 and into a receiver (not shown). The larger solids pass over the layers of screening material and out of a discharge end of the shale shaker into a skip or ditch.
The most likely component to wear out or fail first, is the layers of screening material arranged on the panel 101. The screen assembly 100 is removed from the C-shape rails 104 and 105. The panel 101 having layers of worn out screening mesh thereon and the pull down member 103 may be lifted from frictional engagement with the support structure 102. The panel 101 is slid out from receiving rails 198 and 199 and replaced with a new panel having layers screen mesh thereon. The rails of the new panel are slid into the receiving rails of the pull down member 103. The pull down member 103 with the new panel is placed on the original support structure 102 and slid back into the shale shaker.
It is envisaged that the panel may be of any known type, such as 1.5 mm to 3 mm steel, aluminium or plastics material plate with a multiplicity of apertures punched therein or perforated plate, not having folded edges to the apertures. The apertures may be oblong, pentagonal, hexagonal, heptagonal, octagonal, circular or any other shape.
Referring to
The support structure 302 comprises a left side plate 308 and a right side plate 309 and twelve substantially identical crowned ribs 310 to 321 welded to the left and right side plates 308, 309. The crowned rib 310 is made from 3 mm mild steel plate having a crowned top edge 322, whose central point 323 is approximately 5 mm above a horizontal line joining two top corners 324 and 325 of the crowned rib 310.
The crowned ribs 310 to 321 are spaced along the left and right side plates at a distance equal to two intervals, an interval as defined with reference to
In use, the panel 310 having layers of mesh 300 adhered thereto, is laid on to the top of the crowned ribs 310 to 321. Preferably, in-line panel ribs 326 to 329 (others not shown) lying parallel to the rear edge 306 of panel 301, each lie over the crowned ribs 310 to 321, such that, the crowned ribs do not substantially occlude the apertures and openings. As shown in
Drilling mud having solids entrained therein is introduced at a feed end of the shale shaker and is shaken along the layers of mesh on the screen assembly. Fluid and small particles pass through the layers of mesh 300 and the triangular apertures and the circular openings in the panel 301 and past the support structure 302 and into a receiver (not shown). The larger solids pass over the layers of screening material and out of a discharge end of the shale shaker into a skip or ditch.
The most likely component to wear out or fail first, is the layers of screening material 300. The screen assembly may be removed from the C-shape rails 330 and the panel 301 having layers of worn out screening mesh arranged thereon and replaced with a new panel having layers screen mesh thereon. The new panel is placed on the original support structure 302 and slid back into the shale shaker.
A further embodiment of a screen assembly is shown in
The panel 401 is of the type shown in
In use, the panel 401 has layers of mesh adhered thereto, and is laid on to the top of the crowned ribs 406. Preferably, in-line panel ribs lying parallel to the folded rear end 412 of panel 401, each lie over the crowned ribs like crowned rib 406, such that, the crowned ribs do not substantially occlude the apertures and openings. The screen assembly is slid into clamping rails 408, 408a arranged on each side of a basket 413 of a shale shaker 409. The clamping rails 408, 409 comprise a C-shape rails each having a bottom surface on which the support structure 402 of the screen assembly rests. Each of the C-shape rails also has a pneumatically inflatable bladder 414 fixed to an upper part 334 of the C-shape rail 330. Once the screen assembly 400 is slid into the clamping rails 408, 408a, the pneumatically inflatable bladder 414 is inflated which pushes down on left and right side portions 410 and (not shown) pushing and holding the panel 401 over the crowned ribs, rigidly fixing the panel 301. The folded left wing portion 411 and folded right wing portion (not shown), folded front end (not shown) and a folded rear end 412 fit about the support structure 406.
Referring to
The panel 500 further comprises supporting ribs 505. The supporting ribs 505 are arranged between sides 506 and 507 of the panel 500 and are spaced along the panel 500 at a distance equal to one interval, an interval as defined with reference to
Side portions 508 and 509 of the perforate plate 501 are not provided with apertures 504 and are folded to form substantially vertical sides and are folded back over the bottoms 510 of the ribs 505 and may be welded thereto. The ribs 505 preferably have a cross-section similar to a lazy-7 and are preferably between 0.5 and 2.5 cm deep, and most preferably 1 to 1.8 cm deep and most preferably 1.1 cm and advantageously made from 0.5 to 1.5 mm thick steel plate. However, the ribs 505 may simply be vertical strips welded to the perforate plate. End portion 511 of the perforate plate 501 is folded to form a ledge 513 and an upwardly angled portion 514 to form a longitudinal recess 515 to receive a seal member (not shown). End portion 512 of the perforate plate 501 is folded to form a ledge 516 and an end face 517.
Support members 518 and 519 are spaced along the length of the panel 500. The support members 518 and 519 may be spaced equidistant along the width of the panel 500, or preferably, equidistant between the unsupported width when arranged in a shale shaker. The support members 518 and 519 preferably take the form of rails having a curved channel 520 extending along the length of the panel 500. The support members are preferably made from sheet metal folded into a lazy-W, or formed from cut box section steel tubing and pressed to form the curved recess 520.
In use, the support structure 600 is slid into side rails 650 and 651 of a shale shaker (not shown) and rests on surfaces 652 and 653 of the rails. The shale shaker may be of the type sold under the brand name VSM 300 by Varco Limited. The panel 500 is then slid into the rails 650 and 651 such that the support members 518 and 519 run along respective structural support members 605 and 606 of the support structure 600. The distance between the bottom of the panel 500 and the top of the box-section steel tubing perimeter 601, is preferably 1 mm to 30 mm, and most preferably 5 mm to 10 mm. Inflatable bladders 654 and 655 are arranged in the rails 650 and 651. Upon inflation of the inflatable bladders 654, 655, the sides 506 and 507 of the panel 500 are pushed down on to the box-section steel tubing perimeter 601, deflecting the panel 500 over the circular-section steel tubing 605 and 606.
In use, the support structure 700 is inserted in side rails 750 and 751 of a shale shaker (not shown) and rests on surfaces 752 and 753 of the rails. A panel 800, is generally similar to the panel 500 shown in
The layers of mesh used in any of the embodiments shown herein and in any embodiment of the invention, may be pre-tensioned and adhered, bonded or otherwise attached to the panel. The layer of mesh may be bonded using a heat activated powder.
In accordance with the present invention, there is provided a screen assembly for a shale shaker, the screen assembly comprising a panel and a support structure, the panel having an area provided with a multiplicity of apertures and at least one layer of screening material arranged over the multiplicity of apertures, wherein said panel is removable from said support structure. The layers of screening material are the most likely components of a screen assembly to fail in use. A screen assembly of the present invention allows replacement of the panel with layers of screening material attached thereto, without having to replace the entire screen assembly.
Advantageously, there is a friction fit between the panel and the support structure. The panel may be provided with wing portions which fit over the support structure to provide a friction fit, such that the panel may be aligned thereon.
Advantageously, the screen assembly further comprises a pull down member located within the panel for pulling the panel on to the support structure. Preferably, the pull down member is linked to said panel at at least two intermediate points. Preferably, the pull down member is releasably connected to the panel. Advantageously, the pull down member comprises a rail and preferably, the panel comprises a rail, which co-operate to enable the pull down member to pull on said panel. Preferably, the panel is rectangular and the pull down member is located between sides of the rectangular panel Advantageously, the pull down member is operated by the clamping mechanism preferably, such that, in use, the clamping mechanism pushes down on the pull down member, which pulls the panel on to the support structure. Most advantageously, at least a portion of the perimeter of the panel is, in use, arranged in the clamping mechanism, such that the perimeter of the panel is pushed on to the support structure by the clamping mechanism. Preferably, the pull down member comprises at least one rib, which advantageously extends between sides of the rectangular panel. Advantageously, the at least one rib has two ends each having a top face which, in use is contactable by said clamping mechanism. Preferably, the pull down member comprises a plurality of ribs linked by a side runner on each of said two ends to form said top face which, in use is contactable by said clamping mechanism. Advantageously, the support structure comprises a plurality of support ribs on which, in use the panel is pushed or pulled on to. Preferably, each support rib has a top edge which is flat, in use the panel is pushed or pulled on to the flat top edge.
The present invention also provides a panel for the screen assembly of the invention, the panel having a perimeter comprising a multiplicity of apertures and a member arranged inside said perimeter for reception with a pull down member to pull said panel on to a support structure.
The present invention also provides a support structure for a screen assembly comprising a plurality of substantially parallel support ribs having top edges, characterised in that said top edges are flat.
The present invention also provides a shale shaker comprising a basket, a vibratory mechanism and a set of support ribs arranged across said basket characterised in that said ribs have flat top edges and a clamping mechanism arranged about the basket. Preferably, the clamping mechanism comprises a pneumatic bladder.
A method for fitting a screen assembly in a shale shaker, the screen assembly comprising a panel having at least one layer of mesh arranged thereon and a support structure, the method comprising the steps of inserting the screen assembly into a clamping mechanism of a shale shaker, operating the clamping mechanism wherein at least part of a perimeter of said panel of said screen assembly is pushed down on to said support structure, the screen assembly further comprises a pull down member, and the method further comprises the step of operating the clamping mechanism depresses a pull down member, pulling intermediate parts of said panel on to said support structure.
Whereas the present invention has been described in particular relation to the drawings attached hereto, it should be understood that other and further modifications apart from those shown or suggested herein, may be made within the scope and spirit of the present invention.
Number | Date | Country | Kind |
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0224156.0 | Oct 2002 | GB | national |
0301508.8 | Jan 2003 | GB | national |
This Application is a division of U.S. patent application Ser. No. 10/530387 filed on Oct. 16, 2003 and incorporated by reference herein for all it contains.
Number | Date | Country | |
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Parent | 10530387 | Feb 2006 | US |
Child | 12469862 | US |