KR102211164B1 - Polyurethane vibratory screen - Google Patents

Abstract

A molded polyurethane vibrating screen comprising a body, wherein the body has opposite side edge portions 14 and 16, upper edge portion 18 and lower edge portion 20, upper surface and lower surface, and between the side edge portions The first members 101 extending and the second members 102 extending between the lower edge portion and the upper edge portion extend in a direction substantially parallel to each other between the side edge portions, and Third members 203 having a plurality of first members therebetween, extending in a direction substantially parallel to each other between the lower edge portion and the upper edge portion, and having a plurality of second members therebetween. A molded polyurethane vibrating screen comprising reinforcing members 50 integrally molded with the fourth members 204, the first members 10 or the second members 102.

Description

Polyurethane vibratory screen}

Cross-reference to related applications

This application claims priority to U.S. Patent Application No. 13/838,968 filed on March 15, 2013, the U.S. Patent Application Serial No. 12/763,046 filed on April 19, 2010. It is a continuing application in part, and the above US patent application is expressly incorporated herein by reference in its entirety.

The present invention relates to an improved molded polyurethane screen.

Molded polyurethane screens with a reinforcing agent therein are known in the art.

However, in the past, the dividing strip between the holes was relatively large, and accordingly, the ratio of the hole area of the screen among the surface area of the screen was undesirably low, and as a result, the screen was relatively inefficient. Was made to be.

The present invention is an improvement over U.S. Patent Nos. 4,819,809 and 4,857,176, both of which are expressly incorporated herein by reference. The present invention provides an improved screen with a relatively high ratio of open screening area and high efficiency.

According to an exemplary embodiment of the present invention, the vibrating screen includes a flexible molded polyurethane body, and the flexible molded polyurethane body includes substantially parallel side edge portions positioned at opposite ends of the body, the side edge First members and second members forming a lower edge portion substantially perpendicular to portions, an upper edge portion substantially perpendicular to the side edge portions and opposite the lower edge portion, an upper surface, a lower surface, and screening holes , And third members and fourth members.

The first members extend between the side edge portions. The second members extend between the lower edge portion and the upper edge portion. The third members and the fourth members may have a thickness greater than that of the first members and the second members. The third members extend in a direction intersecting substantially in parallel between the side edge portions and have a plurality of first members therebetween. The fourth members extend in a direction substantially parallel to each other between the lower edge portion and the upper edge portion, and have a plurality of second members therebetween. The reinforcing members are integrally formed with the third members and the fourth members.

Exemplary embodiments of the present invention are described in more detail below with reference to the accompanying drawings.

1A is a partial plan view of a vibrating screen according to an exemplary embodiment of the present invention;
FIG. 1B is a top isometric view of the screen shown in FIG. 1A;
Fig. 1C is a bottom isometric view of the screen shown in Fig. 1A;
Fig. 2 is a partial cross-sectional view taken substantially along line 2--2 in Fig. 1A;
FIG. 3 is a partial cross-sectional view taken substantially along line 3--3 of FIG. 1A and the circled portion is an enlarged partial cross-sectional view of a portion of the screen shown in FIG. 3;
FIG. 4 is a plan view of a portion of the screen shown in FIG. 1A and a portion indicated by a circle is an enlarged plan view of a portion of the screen shown in FIG.
FIG. 5 is a partial cross-sectional view taken along line 5--5 in FIG. 1A and the circled portion is an enlarged partial cross-sectional view of a portion of the screen shown in FIG. 5;
Fig. 6 is an enlarged partial cross-sectional view substantially similar to the drawing taken along line 5--5 of Fig. 1A, but only showing a cross-sectional configuration of a modified shape of the first members having reinforcing members;
Fig. 7 is a view similar to Fig. 6 but showing first members without a reinforcing member;
Fig. 8 is a partial cross-sectional view showing how the improved screen of Fig. 1A is mounted on a vibration screening machine;
9 is an enlarged isometric view of a portion of a vibrating screen according to an exemplary embodiment of the present invention having first members forming screen holes and reinforcing members integral with the second members;
10A is a top isometric view of a vibrating screen according to an exemplary embodiment of the present invention;
Fig. 10b is a bottom isometric view of the screen shown in Fig. 10a;
11A is a top isometric view of a view of a vibrating screen according to an exemplary embodiment of the present invention;
Fig. 11B is a bottom isometric view of the screen shown in Fig. 11A;
FIG. 12 is a top isometric view of a vibrating screen from which a portion of the screen showing reinforcing rods according to an exemplary embodiment of the present invention has been removed, and a portion indicated by a circle is an enlarged top isometric view of a portion of the screen shown in FIG. Is a perspective view;
13 is an isometric view of a part of a vibration screening machine equipped with a vibration screen according to an embodiment of the present invention;
14 is an isometric view of a part of a vibration screening machine equipped with a vibration screen according to an embodiment of the present invention.

Like reference numerals indicate like parts in several drawings.

According to an exemplary embodiment of the present invention, the vibrating screen 10 comprises a body 12 of molded polyurethane having unperforated side edges 14 and 16. The side edge portions 14 and 16 are U-shaped upwards and each may include a cast-in structural member such as an angle 15 as shown in FIG. 2. Further, the side edges 14, 16 may be formed without a cast-in structural member and/or may include other structural members. The side edges 14, 16 may be formed in a U-shape, or may be formed in any other suitable shape for attachment to a vibration screening machine. In one exemplary embodiment, the side edge portions 14, 16 may comprise a molded member, for example a metal member bent in a desired shape, for example a U-shape. The molded member may be attached to the polyurethane body by heating, pressing, mechanical molding, chemical molding and/or any suitable method/arrangement. 11A to 11B, the angle 15 may form an upward U-shape. The angle 15 may be extended by the entire length of the side edge portions 14 and 16. The side edges 14, 16 can be configured for mounting the vibrating screen 10 in a vibrating screening machine, as is well known. In addition, the body 12 comprises a lower edge portion 18 and an upper edge portion 20, which together with the side edge portions 14, 16 define the outer rim of the screen 10. In certain embodiments, the angle 15 may be included within the upper edge portion 20 and the lower edge portion 18. See, for example, FIGS. 10A-10B. In these embodiments, the angle 15 may extend the entire length of the upper edge portion 20 and the lower edge portion 18. In an exemplary embodiment, the upper edge portion 20 and the lower edge portion 18 may be configured for mounting on a vibrating screen 1010 designed to mount the screen from front to rear. See, for example, FIG. 13. The body 12 further comprises first members 101 and second members 102 comprising an upper surface 22 and a lower surface 24 and forming screen holes 26. The body 12 may include third members 203, fourth members 204, fifth members 305 and sixth members 306. The body 12 may include various configurations of the third members 203, the fourth members 204, the fifth members 305 and/or the sixth members 306. The third members 203, the fourth members 204, the fifth members 305 and/or the sixth members 306 may or may not include the reinforcing members 50. And is generally configured to provide support to the screen apertures 26 formed by the first members 101 and the second members 102. The body 12 includes first members 101 and second members without third members 203, fourth members 204, fifth members 305 and/or sixth members 306 It may include s 102. The first members 101 and/or the second members 102 may be configured to include reinforcing members 50. In certain embodiments, reinforcing rods 1050 are parallel to the corners of the screen with the vibrating machine attachment arrangements (e.g., corners with U-shaped structural members discussed herein). It may be included in members extending in the direction. See, for example, FIG. 12. The reinforcing rods 1050 are deformed from the side edges, for example, the side edges 14 and 16 shown in Figs. 10A, 10B, 11A, 11B, and 12 and/or the hourglass It provides stability to the screen 10 by preventing hourglassing. Reinforcing rods are substantially rigid, provided for structural support, and the vibration will generally limit significant movement or deflection of the screen assembly when force is applied to the corners that connect with the vibration screening machine tension members. It does not extend in a direction perpendicular to the corners of the screen with the machine attachment arrangement.

In one exemplary embodiment, the reinforcing rods 1050 may be integrated with the fourth members 204 and/or the sixth members 306 (including those integrated by molding in one piece). The reinforcing rods 1050 may be made of plastic, metal, polymer, or any other suitable material having the required structural properties.

The first members 101 and the second members 102 form a first integrally molded grid structure 100 defining the screen apertures 26. The third members 203 and the fourth members 204 may form the second integrally formed grid structure 200. The reinforcing rods 1050 may be integrally molded within the fourth members 204. The fifth and sixth members may form a third integrally formed grid structure 300. The reinforcing rods 1050 may be integrally molded in the sixth members 306. 1A, 2, 3, 4 and 6, the grid structures 200 and 300 are bi-directional to form support grids within the members. ) Including integrally molded reinforcing members. Due to the properties of the reinforcing members 50 and their placement into the bidirectional grid structure, which are further discussed herein, the members in which the reinforcing members 50 are embedded have a relatively small size and increased openness. Provide screening area. The grid structures provide screen strength, support to the holes 26 during vibratory loading and significantly increase the open screening area. Although the second grid structures and the third grid structures are discussed herein, a smaller number of grid structures or additional grid structures may be provided.

The first members 101 may extend substantially parallel to each other in a direction intersecting between side edge portions. The second members 102 may be substantially parallel to each other and may extend in a direction intersecting between the lower edge portion 18 and the upper edge portion 20. The second members 102 may have a thicker thickness than the first members, and thus may provide additional structural support to the screen holes 26.

The first members 101 and/or the second members 102 may include reinforcing members 50, and may or may not be supported by additional support members or support grid structures. have. See, for example, FIGS. 6 and 9. As shown in Fig. 9, the body 12 has first members 101 and second members 102 having bidirectional reinforcing members 50 integrally molded. These configurations require screens with large screen apertures, which can be beneficial for screening applications.

In certain embodiments, the reinforcing rods 1050 may be incorporated into at least one of the fourth members 204 and the sixth members 306, respectively, and may be provided from the corner 14 to the corner 16. have. See, for example, FIG. 12. The reinforcing rods 1050 provide stability or prevent hourglass deformation or other deformation of the screen occurring along the edges 14 and 16 of the screen without U-shaped channels. do. These implementations include the first members 101, the second members 102, the third members 203, the fourth members 204, the fifth members 305 and/or the sixth members. Reinforcing members 50 may be included within 306. The reinforcing members 50 include the first members 101, the second members 102, the third members 203, the fourth members 204, the fifth members 305 and/or the It may be included in all or some of the six members 306. The reinforcing members 50 provide screen characteristics as discussed herein.

As shown in Fig. 4, the screen holes 26 are extended, the screen holes 26 have a length dimension greater than the width dimensions, the length dimension being the end of the side surfaces running along the sides. And the width dimensions refer to the side surfaces, and the length dimensions of the screen holes 26 extend in a direction intersecting the corner portions 14 and 16. The screen holes 26 may have a width (ie, between adjacent inner surfaces of the first members 101) of about 0.044 mm to about 4 mm, and a length (ie, adjacent second members 102 ). Between the inner surfaces of) may be about 0.088mm to 60mm. The screen holes 26 may have a variety of shapes including a generally square shape. The overall dimensions of screen 10 may be about 1.2 meters by 1.6 meters, or any other desired size. All dimensions presented herein are presented by way of example, and are not limited thereto.

The screen holes 26 may be divided downward between the upper surface 22 and the lower surface 24 and the first members 101 may have a substantially inverted trapezoidal shape. See, for example, FIGS. 6 and 7. This general shape of the first members 101 prevents blinding of the screen 10. As shown in FIG. 6, the first members 101 include reinforcing members 50. As shown in FIG. 7, the first members 101 do not include the reinforcing members 50.

Screens with various screen aperture sizes and support configurations described herein have a relatively large open screening area. For example, the open screening area can range from about 40 percent to about 46 percent. As further discussed herein, the relatively large open screening area places bidirectional reinforcing members 50 within the cross member (e.g., 203, 204) as described in various embodiments herein. It can be obtained by doing. The reinforcing members significantly reduce the size of both the bidirectional support cross members and allow for thinner screen members 101 and 102 to form the screen holes 26. The grid work of the support members and reinforcement members provides a structurally sound screen that holds the necessary screen holes during the vibration operation.

The third members 203 and the fourth members 204 may have a thickness thicker than that of the first members 101 and the second members 102, and below the lower surface 24 of the body 12 It may have a portion 210 extending downward of. The thicker thickness and the downwardly extending portion may provide additional structural support to the first members 101 and the second members 102. As shown in FIG. 1C, the portion 210 has a substantially triangular cross-section and may have a vertex protruding from the lower surface 24 of the body 12. The third members 203 may extend in a direction substantially parallel to each other between the side edge portions 14 and 16, and may have a plurality of first members 101 therebetween. The fourth members 204 may extend in a direction that intersects substantially in parallel between the lower edge portion 18 and the upper edge portion 20, and a plurality of second members 102 are interposed therebetween. Can have. The fourth members 204 may have reinforcing rods 1050 integrally formed therein. The reinforcing members 50 may be integrally formed with the third members 203 and the fourth members 204. See, for example, FIGS. 3 and 5. The third members 203 and the fourth members 204 include reinforcing members 50, so that the screen hole formed by the first members 101 and the second members 102 during the vibration screening operation It can be configured to have a minimum thickness while providing the necessary structural support to hold the s 26. The bidirectional support system provided by reinforced third members 203 and fourth members 204 greatly reduces the thickness of the support members and provides increased open screening area and overall screen efficiency. Including the reinforcing members 1050 into the fourth members 204 can add stability to the screen 10, and an hourglass variant that provides a general hourglass-type shape to the screen, i.e., side edges It is possible to prevent deformation of the parts 14 and 16 in the inward direction.

The fifth members 305 and the sixth members 306 may be included in the body 12. The fifth and sixth members may have a thickness thicker than that of the third and fourth members, and may have a portion 310 extending downward from the lower surface of the body. The thick thickness and the downwardly extending portion may provide additional structural support to the first members 101 and the second members 102. The sixth members 306 may include a portion 320 extending upward from the upper surface of the body. The portion 320 may have a substantially triangular cross section, and may have a vertex protruding from the upper surface 22 of the body 12. The sixth members 306 are shown in FIG. 2 and have a portion 320 extending upward from the upper surface of the body 12 and acting as a flow guide. The sixth members 306 may have reinforcing rods 1050 integrally formed therein. The fifth members 305 may extend in a direction substantially parallel to each other between the side edge portions 14 and 16, and may have a plurality of third members 203 between them. The sixth members 306 may extend in a direction that intersects substantially in parallel between the lower edge portion 18 and the upper edge portion 20, and a plurality of fourth members 204 therebetween. Can have. The reinforcing members 50 may be integrally formed with the fifth members 305 and the sixth members 306. The fifth members 305 and sixth members 306 may be provided to provide additional support to the screen holes 26, and by including the reinforcing members 50, the screen holes during the vibration screening operation They can be configured to have a minimum thickness while providing the necessary structural support to hold them 26. The bidirectional support system provided by reinforced fifth members 305 and sixth members 306 greatly reduces the thickness of the support members and provides increased open screening area and overall screen efficiency. Including the reinforcing members 1050 within the sixth members 306 adds stability to the screen 10 and prevents hourglass deformation.

1B shows first members 101 and second members 102 forming the screen holes 26, and members 203 and 204 forming a support grid structure for the holes 26. Shows an exemplary embodiment of the present invention. As shown in FIG. 1B, the screen 10 does not include fifth members 305 and sixth members 306. 12 shows another exemplary embodiment of the present invention having reinforcing rods 1050 integrally molded therein. As shown in FIG. 12, the reinforcing rods 1050 are integrally molded in the fourth members 204. Also, the reinforcing rods 1050 may be integrally molded in the sixth members 306 or other members disposed on the members 204 and 306.

In use, the vibrating screen 10 is mounted in a vibrating screening machine 30 (Fig. 8) in a well-known manner. More specifically, it is mounted on a screen deck bed 31 mounted on a frame (not shown) of the machine. The screen deck bed 31 includes frame members 32 spaced apart from each other and substantially parallel to each other and protected from each other by transverse frame members (not shown) that are spaced apart from each other and substantially parallel. It is a plurality of substantially parallel stringers 33 equipped with channel rubbers 34 that extend in an intersecting direction between the transverse frame members. Mounted to the parallel frame members 32 are channel-shaped draw bars 35 with lower portions 36 accommodated in the side edges 14 and 16. The draw bolts 37 separate the draw bars 35 from each other, and tension the vibrating screen 10 with a necessary force. Screen deck beds of the type described above are well known in the art. The screen 10 may be mounted on another vibration screening machine, and the side edges 14, 16 may be configured in different shapes to accommodate a variety of vibration screening machines.

The embodiment shown in FIG. 13 is mounted on a vibrating screen machine 1010 from front to rear. In this embodiment, the angle 15 is included in the upper edge portion 20 and the lower edge portion 18 and is located below the upper surface 22. This embodiment has a tension applied from below the screen rather than above the screen, and the tensile force is applied from front to rear.

14 shows an embodiment with an angle 15 included in the side edges 18 and 20. This embodiment also has a tension applied from above and from side to side of the screen.

The reinforcing members 50 as described herein may be aramid fibers (or individual filaments thereof), naturally occurring fibers, or other materials having a relatively large tensile strength with a relatively small cross-sectional area. When an aramid fiber is used as the reinforcing fiber 50, it may be an aramid fiber commercially available under the trademark KEVLAR of DuPont and further identified by the name KEVLAR 29. In addition, the reinforcing members 50 may be at least one of aramid fibers commercially available under the trademarks TWARON, SULFRON, TEIJINCONEX and TECHNORA of Teijin. In addition, the aramid fiber may be a twisted multi-strand or a woven multi-strand, so that it acts as a property of a wick that absorbs the polyurethane molded around them. It provides very good bonding with. The braided multi-stranded fibers or woven multi-stranded fibers may be about 55 denier to about 2840 denier, and preferably about 1500 denier. The flexibility of the aramid fibers provides a system for reinforcing flexibility to the molded polyurethane, which is originally after the necessary bending and flexing that occurs during handling and installation into the vibrating frame member 32. You can return to the molded shape. In addition, the flexible aramid fibers allow the flexible polyurethane screen to be stretched and tensioned in an arcuate state without damage, as shown in FIGS. 8, 13, and 14. The reinforcing members 50 may be tensioned before the polyurethane is molded around them. The reinforcing members 50 of various configurations include the first members 101, the second members 102, the third members 203, the fourth members 204, the fifth members 305, and It may be provided on any one of the sixth members 306. Each member may include zero, one or more reinforcing members 50, and the reinforcing members 50 may be of various sizes and materials. The reinforcing members 50 may be positioned on the lower half of the member so that they are not exposed as early as the upper surface of the screen wears.

During operation, the first members 101 will vibrate to enhance the screening action. In this regard, it should be noted that since the first members 101 are flexible and relatively thin, they will provide a desirable vibration of relatively high amplitude. The reason why the first members 101 for creating the screen holes described in the present specification can be manufactured relatively thin is, as described in the present specification, bidirectionality having a relatively large tensile strength with a relatively small cross-sectional area. This is because of the support members and the support frame of the reinforcing members. Making the support members and the first members 101 relatively thin results in a screen with a larger proportion of the aperture area, which in turn increases the capacity of the screen.

According to an exemplary embodiment of the present invention, the vibrating screen 10 includes a flexible molded polyurethane body 12, and the flexible molded polyurethane body 12 is located at opposite ends of the body 12. Substantially parallel side edge portions 14, 16, a lower edge portion 18 substantially perpendicular to the side edge portions 14, 16, and substantially perpendicular to the side edge portions 14, 16 and the lower The first members 101 and the second members 102 forming the upper corner 20, the upper surface 22, the lower surface 24, and the screening holes 26 opposite the corner 18 ), and the first members 101 extend between the side edge portions 14 and 16, and the second members 102 have the lower edge portion 18 and the upper edge portion ( 20) extends between. In addition, the body may include third members 203 and fourth members 204. The third members 203 and the fourth members 204 may have a thickness greater than that of the first members 101 and the second members 102. The third members 203 extend in a direction crossing substantially in parallel between the side edge portions 14 and 16, and have a plurality of first members 101 therebetween. The fourth members 204 extend in a direction that intersects substantially in parallel between the lower edge portion 18 and the upper edge portion 20, and a plurality of second members 102 are interposed therebetween. Have. The reinforcing members 50 may be integrally formed with the third members 203 and/or the fourth members 204. The reinforcing rods 1050 may be integrally formed with the fourth members 204. In addition, the body includes fifth members 305 and sixth members 306. The fifth members 305 extend in a direction that intersects substantially in parallel between the side edge portions 14 and 16. The sixth members 306 extend in a direction that intersects substantially in parallel between the lower edge portion 18 and the upper edge portion 20. The fifth members and sixth genital members have a thickness thicker than that of the third members and the fourth members, and include reinforcing members 50 integrally formed therewith. The reinforcing rods 1050 may be integrally formed with the sixth members 306. A vibrating screen according to this configuration may have an open screening area of greater than 40 percent and a mesh size ranging from about 0.375 mesh to about 400 mesh. As an example, tested screens with the above configuration included a 43 mesh size screen, a 140 mesh size screen and a 210 mesh size screen. Each of these screens had an open screening area of about 40 percent to about 46 percent. For such a fine mesh size, such a large screening area is determined by the third members 203, the fourth members 204, the fifth members 305, and the sixth members 306, and It is achieved through a relatively strong and thin grid frame created by integrally molded reinforcing members. In the above-described exemplary embodiments and embodiments, the size of each grid unit formed by the intersection of the third members 203 and the fourth members 204 is about 1 inch by 1 inch. In general, the grid unit is larger in the case of a screen with large screen holes, and smaller in the case of a screen with small screen holes. These principles may generally be applicable in the case of each exemplary implementation discussed herein. Further, the grid unit may have a generally rectangular shape or any other suitable shape suitable for supporting the screen aperture.

According to an exemplary embodiment of the present invention, a method of manufacturing a vibrating screen includes generating a mold configured to manufacture the vibrating screen, the vibrating screen having a flexible molded polyurethane body; Installing reinforcing members in the mold, wherein the reinforcing members are configured to be integrally molded with the body; Installing reinforcing rods in the mold, wherein the reinforcing rods are configured to be integrally molded with the body, and filling the mold with polyurethane; And forming the vibrating screen, wherein the vibrating screen includes substantially parallel side edge portions positioned at opposite ends of the body, a lower edge portion substantially perpendicular to the side edge portions, and substantially at the side edge portions. And first members and second members, third members and fourth members forming an upper corner portion, an upper surface, a lower surface, and screening holes opposite the lower corner portion, and the first member Are extended between the side edge portions, the second members are extended between the lower edge portion and the upper edge portion, the reinforcing rods are integrally formed with the fourth members, and the third The members extend in a direction intersecting substantially in parallel between the side edge portions and have a plurality of first members between them, and the fourth members are substantially parallel between the lower edge portion and the upper edge portion. And having a plurality of second members extending in an intersecting direction therebetween, wherein the reinforcing members are integrally formed with at least one of the first members and the second members.

While preferred embodiments of the present invention have been disclosed, it will be appreciated that the present invention is not limited thereto and may be embodied otherwise within the scope of the following claims.

Claims (23)

As a vibrating screen,
The vibration screen includes a flexible molded polyurethane body, and the flexible molded polyurethane body includes substantially parallel side edge portions positioned at opposite ends of the body, and a lower edge disposed in a direction intersecting between the side edge portions A portion, an upper edge portion disposed between the side edge portions and facing substantially parallel to the lower end portion, an upper surface, a lower surface, a first integrally formed grid structure, a second integrally formed grid structure, and a third integrally formed grid structure And screen holes, wherein the first integrally formed grid structure includes first members and second members forming screening holes, wherein the first members are in a direction intersecting substantially in parallel between the side edge parts. And the second members extend in a direction that intersects substantially in parallel between the lower edge portion and the upper edge portion, and the second integrally formed grid structure includes third members and fourth members, , The third members extend in a direction that intersects substantially in parallel between the side edge portions and have a plurality of first members between them, and the fourth members are between the lower edge portion and the upper edge portion. It extends in a direction intersecting substantially in parallel and has a plurality of second members between them, the first reinforcing members are integrally formed with the first members and the second members, and the third integrally formed The grid structure includes fifth members and sixth members, wherein the fifth members extend in a direction intersecting substantially in parallel between the side edge portions and have a plurality of third members therebetween, The six members extend in a direction that crosses substantially in parallel between the lower edge portion and the upper edge portion and have a plurality of fourth members therebetween, and reinforcing rods are the fourth members and the sixth members. A vibrating screen that is integrally molded with at least one of them. The vibrating screen of claim 1, wherein the holes are 0.044mm to 4mm between inner surfaces of the first members and 0.088mm to 60mm between inner surfaces of the second members. The vibrating screen of claim 1, wherein the reinforcing member is at least one of an aramid fiber and a naturally occurring fiber. The method of claim 3, wherein the reinforcing member is an aramid fiber that is at least one of a braided multi-strand and a woven multi-strand, and the polyurethane forms a bond between the first member and the fibers therein, and the first member 2 Vibrating screen impregnated with multi-strands forming a bond between the member and the fibers therein. The vibrating screen of claim 1, wherein the reinforcing rods are at least one of plastic, metal and polymer. As a vibrating screen,
The vibration screen includes a flexible molded polyurethane body, and the flexible molded polyurethane body includes substantially parallel side edge portions positioned at opposite ends of the body, a lower edge portion substantially perpendicular to the side edge portions, the Having first members and second members, third members and fourth members forming an upper corner portion, an upper surface, a lower surface, and screening holes substantially perpendicular to the side corner portions and opposite the lower corner portion, , The first members are extended between the side edge portions, the second members are extended between the lower edge portion and the upper edge portion, and the third members are substantially parallel between the side edge portions. Extending in an intersecting direction and having a plurality of first members between them, the fourth members extending in a direction that intersects substantially parallel between the lower edge portion and the upper edge portion, and has a plurality of A vibrating screen having second members, reinforcing members integrally molded with at least one of the first members and the second members, and reinforcing rods integrally formed with the fourth members. The vibrating screen of claim 6, wherein the holes are 0.044mm to 4mm between inner surfaces of the first members and 0.088mm to 60mm between inner surfaces of the second members. The vibrating screen of claim 6, wherein the side edges are formed in a U-shaped configuration. The vibrating screen of claim 6, wherein the upper and lower corners are formed in a U-shaped configuration. The vibrating screen of claim 6, wherein the reinforcing members are at least one of aramid fibers and natural fibers. The method of claim 10, wherein the reinforcing member is an aramid fiber that is at least one of a braided multi-strand and a woven multi-strand, and the polyurethane forms a bond between the first member and the fibers therein, and the agent 2 Vibrating screen impregnated with multi-strands forming a bond between the member and the fibers therein. The vibrating screen of claim 10, wherein the reinforcing member is an aramid fiber that is at least one of a braided multi-strand and a woven multi-strand, and the fibers are 55 denier to 2840 denier. 7. The vibrating screen of claim 6, wherein the side edges comprise a cast-in member. The vibrating screen of claim 6, wherein the upper and lower corners include cast-in members. 7. The vibrating screen of claim 6, wherein the vibrating screen has an open screening area of greater than 40 percent. 7. The vibrating screen of claim 6, wherein the reinforcing rods are at least one of plastic, metal and polymer. As a vibrating screen,
The vibrating screen includes a flexible molded polyurethane body, the flexible molded polyurethane body includes substantially parallel side edge portions positioned at opposite ends of the body, a lower edge portion substantially perpendicular to the side edge portions, First members and second members forming an upper edge portion, an upper surface, a lower surface, and screening holes substantially perpendicular to the side edge portions and opposed to the lower edge portion, the first members Extending between the portions, the second members extending between the lower edge portion and the upper edge portion, and reinforcing members integrally formed with the first members and the second members; A vibrating screen, wherein reinforcing rods are integrally molded with the first members extending between the side edge portions. The vibrating screen of claim 17, wherein the holes are 0.044 mm to 4 mm between the inner surfaces of the first members and 0.088 mm to 60 mm between the inner surfaces of the second members. The vibrating screen of claim 17, wherein the reinforcing members are at least one of aramid fibers and natural fibers. The method of claim 17, wherein the reinforcing member is an aramid fiber that is at least one of a braided multi-strand and a woven multi-strand, and the polyurethane forms a bond between the first member and the fibers therein, and the agent 2 Vibrating screen impregnated with multi-strands forming a bond between the member and the fibers therein. As a method of manufacturing a vibrating screen, the method of manufacturing the vibrating screen,
Creating a mold configured to manufacture the vibrating screen, the vibrating screen having a flexible molded polyurethane body;
Installing reinforcing members in the mold, wherein the reinforcing members are configured to be integrally molded with the body;
Installing reinforcing rods in the mold, wherein the reinforcing rods are configured to be integrally molded with the body, and filling the mold with polyurethane; And
Forming the vibrating screen, wherein substantially parallel side edge portions positioned at opposite ends of the body, a lower edge portion substantially perpendicular between the side edge portions, and substantially perpendicular to the side edge portions, and the The first members and second members, third members and fourth members forming an upper corner portion, an upper surface, a lower surface, and screening holes opposite the lower corner portion, the first members are the side edges Extending between the portions, the second members extending between the lower edge portion and the upper edge portion, reinforcing members are integrally formed with the first members and the second members, and the third The members are substantially parallel and have a plurality of first members between them, the fourth members are substantially parallel and have a plurality of second members between them, and reinforcing rods are integrally molded with the fourth members. Method for manufacturing a vibrating screen comprising the step of. As a vibrating screen,
A flexible molded polyurethane body, screen holes located within the body, first substantially parallel flexible members defining opposite sides of the screen holes, second substantially parallel flexibility defining opposite sides of the screen holes Members, third members, fourth members, side edge portions, a first end and a second end, wherein the first substantially parallel flexible members are substantially parallel to the second substantially parallel flexible members. Vertically, the third members are substantially parallel and have a plurality of first members between them, the fourth members are substantially parallel and have a plurality of second members between them, the reinforcing rods are the fourth It is formed integrally with the members, the side edge portions are located on opposite sides of the body and are substantially parallel, the third members and reinforcing members therein extend between the side edge portions, The first end and the second end are located at opposite ends of the body and are substantially parallel, and between the first end and the second end, the fourth members and reinforcing members therein extend, And the side portions are substantially perpendicular to the ends. The vibrating screen of claim 22, wherein the reinforcing rods are at least one of plastic, metal and polymer.

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