The present invention is directed to woven wire screenings and a method of forming the same. More particularly, a preferred embodiment of the present invention is directed to woven wire screenings used in a shaker or vibrating screen apparatus that classifies material flowing through one or more woven wire screenings.
One or more woven wire screens have been used in shaker or vibrating screen apparatus to size material passing through the woven wire screens. Known woven wire screens typically consist of a plurality of interwoven weft and warp wires forming a plurality of openings for permitting suitably sized material to pass through the screen. The openings can be square or rectangular. Alternatively, the screen can be formed as a long slot screen where the warp wires are maintained in spaced parallel relation by weft wires arranged in groups of three at spaced intervals along the length of the warp wires.
Conventional woven wire screens have limited efficiency due to the limited throughput of product through known woven wire screens for a given period of time. The preferred forms of the present invention are designed to significantly improve the throughput and thereby significantly improve the efficiency of woven wire screens.
An object of the present invention is to provide a novel and unobvious woven wire screening and a method of forming the same.
Another object of a preferred embodiment of the present invention is to provide a woven wire screening having an upper screening surface configured to improve the tumbling action of product impacting the upper screening surface to improve the throughput of the woven wire screening.
A further object of a preferred embodiment of the present invention is to provide a woven wire screening configured to obtain greater throughput than a conventional screen having the same open area.
Yet another object of a preferred embodiment of the present invention is to provide a woven wire screening with weft wires crimped to have a first crimp depth and warp wires crimped to have a second crimp depth creating a first knuckle height differential between the warp wires and weft wires and at least one additional wire configured to change the first knuckle height differential when the warp wires, the wefts wires and the at least one additional wire are interwoven to form the woven wire screening.
Still another object of a preferred embodiment of the present invention is to provide a woven wire screening that includes a plurality of weft wires and a plurality of warp wires where at least one of the warp and weft wires is configured such that the wire has at least one upper knuckle that is offset vertically from at least one other upper knuckle of the wire.
Yet still another object of a preferred embodiment of the present invention is to provide a woven wire screening having an upper screening surface configured to enhance tumbling action of product contacting the upper screening surface.
A further object of a preferred embodiment of the present invention is to provide a woven wire screening having an upper screening surface configured to enhance tumbling action of product contacting the upper screening surface where all wires of the woven wire screening are substantially identical.
It must be understood that no one embodiment of the present invention need include all of the aforementioned objects of the present invention. Rather, a given embodiment may include one or none of the aforementioned objects. Accordingly, these objects are not to be used to limit the scope of the claims of the present invention.
In summary, a preferred embodiment of the present invention is directed to a woven wire screening for use in classifying material flowing through the woven wire screening. The woven wire screening includes a plurality of weft wires and a plurality of warp wires. The plurality of warp wires includes a plurality of first warp wires and at least one second warp wire. The plurality of warp wires and the plurality of weft wires being interwoven to form an integral wire cloth having a plurality of openings for permitting material to be classified to flow through the openings. Each of the plurality of first warp wires is crimped to form upper and lower knuckles. Each of the plurality of weft wires is crimped to form upper and lower knuckles. The plurality of weft wires have a first crimp depth and the plurality of first warp wires have a second crimp depth different from the first crimp depth such that the upper knuckles of the weft wires are offset vertically from the upper knuckles of the warp wires creating a knuckle height differential between the upper knuckles of the weft wires and the upper knuckles of the first warp wires. The at least one second warp wire is one of a straight wire and a crimped wire having a crimp depth different from the second crimp depth. The plurality of warps wires and the plurality of weft wires are arranged relative to each other such that substantially all of the openings of the integral wire cloth have substantially the same size.
Another preferred embodiment of the present invention is directed to a woven wire screening for use in classifying material flowing through the woven wire screening. The woven wire screening includes a plurality of warp wires and a plurality of weft wires. The plurality of warp wires and the plurality of weft wires are interwoven to form an integral wire cloth having a plurality of openings for permitting material to be classified to flow through the openings. The plurality of warp wires includes a plurality of crimped warp wires crimped to form upper and lower knuckles. The plurality of weft wires includes a plurality of crimped weft wires crimped to form upper and lower knuckles. The plurality of weft wires have a first crimp depth and the plurality of first warp wires have a second crimp depth different from the first crimp depth such that the upper knuckles of the weft wires are offset vertically from the upper knuckles of the warp wires creating a knuckle height differential between the upper knuckles of the weft wires and the upper knuckles of the first warp wires. The plurality of weft wires includes at least one of a straight weft wire and a crimped wire having a crimp depth different from the first crimp depth.
A further preferred embodiment of the present invention is directed to a method of forming a woven wire screening used in classifying material flowing through the woven wire screening. The method includes the steps of: (a) providing a plurality of crimped warp wires having upper and lower knuckles; (b) providing a plurality of crimped weft wires having upper and lower knuckles, the plurality of crimped weft wires are crimped differently than the plurality of crimped warp wires creating a first knuckle height differential between the upper knuckles of the crimped weft wires and the upper knuckles of the crimped warp wires; (c) providing at least one additional wire, the at least one additional wire is one of a straight wire and a crimped wire having a crimp depth different from the crimp depth of one of the following: (i) the plurality of crimped warp wires; and, (ii) the plurality of crimped weft wires; (d) interweaving the plurality of crimped warp wires, the plurality of crimped weft wires and the at least one additional wire such that the at least one additional wire changes the first knuckle height differential between an upper knuckle of at least one crimped warp wire and an upper knuckle of at least one crimped weft wire; and (e) forming an integral wire cloth such that substantially all openings in the integral wire cloth have substantially the same size.
Still another preferred embodiment of the present invention is directed to a woven wire screening for use in classifying material flowing through the woven wire screening. The woven wire screening includes a plurality of weft wires and a plurality of warp wires. Each of the plurality of warp wires is crimped to form upper and lower knuckles. Each of the plurality of weft wires is crimped to form upper and lower knuckles. The woven wire screening includes at least first and second straight wires. The first straight wire has a cross-sectional height greater than the second straight wire and extends substantially parallel to the second straight wire. The plurality of warp wires, the plurality of weft wires and the first and second straight wires are interwoven to form an integral wire cloth having a plurality of openings for permitting material to be classified to flow through the openings.
Still a further preferred embodiment of the present invention is directed to a woven wire screening for use in classifying material flowing through the woven wire screening. The woven wire screening includes a plurality of weft wires and a plurality of warp wires. The plurality of warp wires and the plurality of weft wires are interwoven to form an integral wire cloth having a plurality of openings for permitting material to be classified to flow through the openings. A first wire includes a first set of knuckles. The first wire is either a warp wire or a weft wire. The first set of knuckles is one of a plurality of upper knuckles and a plurality of lower knuckles. At least one of the first set of knuckles is offset vertically from at least one other of the first set of knuckles.
The preferred forms of the invention will now be described with reference to
Referring to
The first set of warp wires 2, the second set of warp wires 4 and the plurality of weft wires 6 are interwoven to form an integral wire cloth having a plurality of openings 8 through which appropriately sized product passes through during the process of classifying materials into various sizes or size ranges. In the most preferred embodiment, all of the openings 8 in woven wire screen A are of the same size and shape. Preferably, openings 8 are rectangular or square. It should be noted that the present invention is not limited to woven wire screens having openings of the same size and shape. For example, the screen can be formed as a long slot screen where the warp wires are maintained in spaced parallel relation by weft wires arranged in groups of three at spaced intervals along the length of the warp wires. The long slot screen has at least two different size openings.
The first set of warp wires 2 are straight wires, i.e., wires that are not crimped prior to interweaving the weft and warp wires to form the integral wire cloth. The warp wires 2 are shown as having a circular cross-section. However, warp wires 2 can be shaped in a similar manner as warp wires 4 to have two substantially flat sidewalls. Warp wires 4 are crimped prior to interweaving of the warp and weft wires to form upper knuckles 10 and lower knuckles 12 alternately spaced along the length of each of the warp wires 4. The distance between the upper knuckles 10 and the lower knuckles 12 of a given wire is referred to as the crimp depth.
Warp wires 4 are shown as being shaped wires, i.e., wires that have passed through shaping rollers to form two substantially flat sidewalls. However, warp wires 4 could have a circular cross-section. In the embodiment illustrated in
Each of the weft wires 6 are preferably crimped wires having upper knuckles 14 and lower knuckles 16. Referring to
Referring to
The variation in orientation of upper knuckles of the weft wires is readily apparent from
By forming the warp wires 4 prior to interweaving with the weft wires 6 such that the crimp depth of the warp wires 4 is less than the crimp depth of the weft wires 6, upper knuckles 10 of the warp wires 4 will be offset vertically from upper knuckles 14 of weft wires 6 to further vary the orientation of upper knuckles in the screen A to further enhance tumbling action of product impacting the upper surface of the woven screen A. This knuckle height differential between the upper knuckles 14 of weft wires 6 and the upper knuckles 10 of the warp wires 4 created by the crimping process is altered when the weft wires and warp wires are interwoven due to the use of alternating straight warp wires 2 and crimped warp wires 4. For example, the height differential between the upper knuckle 14 of a weft wire 6 that passes over a straight wire 2 and an adjacent upper knuckle 10 of a warp wire 4 will be greater than the height differential between these knuckles created during crimping of the corresponding weft wire and warp wire.
Referring to
The first set of weft wires 24, the second set of weft wires 26 and the plurality of warp wires 28 are interwoven to form an integral wire cloth having a plurality of openings 30 through which appropriately sized product passes through during the process of classifying materials into various sizes or size ranges. Preferably, all of the openings 30 in woven wire screen H are of the same size and shape. Openings 30 are preferably rectangular or square. It should be noted that this embodiment is not limited to woven wire screens having openings of the same size and shape. For example, the screen can be formed as a long slot screen where the warp wires are maintained in spaced parallel relation by weft wires arranged in groups of three at spaced intervals along the length of the warp wires. The long slot screen has at least two different size openings.
The first set of weft wires 24 are straight wires, i.e., wires that are not crimped prior to interweaving the weft and warp wires to form the integral wire cloth. The weft wires 24 are shown as having a circular cross-section. However, weft wires 24 can be shaped in a similar manner as weft wires 26 to have two substantially flat sidewalls. Weft wires 26 are crimped prior to interweaving of the warp and weft wires to form upper knuckles 32 and lower knuckles 34 alternately spaced along the length of each of the weft wires 26.
Weft wires 26 are shown as being shaped wires, i.e., wires that have passed through shaping rollers to form two substantially flat sidewalls. However, weft wires 26 could have a circular cross-section similar to that of weft wires 24. In the embodiment illustrated in
Each of the warp wires 28 are preferably crimped wires having upper knuckles 36 and lower knuckles 38. Warp wires 28 are shown as being shaped wires having two substantially flat sidewalls. However, warp wires 28 can have a circular cross-section similar to weft wires 24. It should be noted that regardless of the cross-sectional shape of the warp and weft wires each of the warp wires 28 and weft wires 24 and 26 can originate from the same size wire. The crimp depth of the weft wires 26 of screen H is less than the crimp depth of warp wires 28. However, it will be readily appreciated that the crimp depth of weft wires 26 can be greater than the crimp depth of warp wires 28. Screen H may be formed such that the ratio of the knuckle height differential between the upper knuckles of the weft wires 26 and the upper knuckles of warp wires 28 and a width of opening 30 ranges from 5% to 35% pursuant to the teachings of U.S. Pat. No. 7,815,053.
Woven wire screen H achieves a knuckle height differential between adjacent upper knuckles 36 of the warp wires 28 even though each of the warp wires 28 has an identical configuration by using alternating straight and crimped weft wires. This variation in the orientation of the upper knuckles 36 in the warp wires 28 will increase the tumbling action of screen A to improve the throughput of product during the process of classifying material. It should be further noted that a variation in orientation of the upper knuckles of the warp wires 28 could be achieved by using a crimped wire for each of the straight weft wires 24 where the crimp depth is different than the crimp depth of weft wires 24.
By forming the warp wires 28 such that the crimp depth of the warp wires 28 is greater than the crimp depth of the weft wires 26, upper knuckles 36 of the warp wires 28 will be offset vertically above upper knuckles 32 of weft wires 26 to further vary the orientation of upper knuckles in the screen H to further enhance tumbling action of product impacting the upper surface of the woven screen H. This knuckle height differential between the upper knuckles 36 of warp wires 28 and the upper knuckles 32 of the warp wires 26 created by the crimping process is altered when the weft wires and warp wires are interwoven due to the use of alternating straight weft wires 24 and crimped weft wires 26. For example, the height differential between the upper knuckle 36 of a warp wire 28 that passes over a straight wire 24 and an adjacent upper knuckle 32 of a weft wire 26 will be greater than the height differential between these knuckles created during crimping of the corresponding weft wire and warp wire.
Referring to
The first set of warp wires 42, the second set of warp wires 44, the first set of weft wires 46 and the second set of weft wires 48 are interwoven to form an integral wire cloth having a plurality of openings 50 through which appropriately sized product passes through during the process of classifying materials into various sizes or size ranges. In the most preferred embodiment, all of the openings 50 in woven wire screen I are of the same size and shape. Preferably, openings 50 are rectangular or square. It should be noted that the present invention is not limited to woven wire screens having openings of the same size and shape. For example, the screen can be formed as a long slot screen where the warp wires are maintained in spaced parallel relation by weft wires arranged in groups of three at spaced intervals along the length of the warp wires. The long slot screen has at least two different size openings.
The first set of warp wires 42 and the first set of weft wires 46 are shaped, crimped wires. The second set of warp wires 44 and weft wires 48 are straight wires, i.e., wires that are not crimped prior to interweaving the weft and warp wires to form the integral wire cloth. While wires 44 and weft wires 48 are shown as having a circular cross-section, these wires can be shaped similar to wires 42 and 46 to have two substantially flat sidewalls. Alternatively, all weft and warp wires could have a circular cross-section.
Warp wires 42 are crimped prior to interweaving of the warp and weft wires to form upper knuckles 52 and lower knuckles 54 alternately spaced along the length of each of the warp wires 42. Weft wires 46 are crimped prior to interweaving of the warp and weft wires to form upper knuckles 56 and lower knuckles 58 alternately spaced along the length of each of the warp wires 42.
In the embodiment illustrated in
Preferably, the crimp depth of the weft wires 46 is greater than the crimp depth of warp wires 42. Screen I may be formed such that the ratio of the knuckle height differential between the upper knuckles of the weft wires 46 and the upper knuckles of warp wires 42 and a width of opening 50 ranges from 5% to 35% pursuant to the teachings of U.S. Pat. No. 7,815,053. It should be noted that the crimp depth of the weft wires 46 could be less than the crimp depth of the warp wires 42.
The use of alternating straight and crimped weft and warp wires creates a screen having an irregular upper screening, i.e., the height of the screening surface various across the width and length of the screening surface to increase the tumbling action of product impacting the irregular screening surface. To further accentuate the irregular nature of the screening surface, two or more different size warp wires 44 and weft wires 48 could be used in a repeating pattern, e.g., a first straight warp wire having a first height followed by a second straight warp wire having a height greater than the first straight warp wire and a first straight weft wire having a first height followed by a second straight weft wire having a height greater than the height of the first straight weft wire. It should be noted that screen I can be formed such that the height of the straight warp wires are different from the height of the straight weft wires.
Referring to
Referring to
Referring to
While this invention has been described as having a preferred design, it is understood that the preferred design can be further modified or adapted following in general the principles of the invention and including but not limited to such departures from the present invention as come within the known or customary practice in the art to which the invention pertains. The claims are not limited to the preferred embodiment and have been written to preclude such a narrow construction using the principles of claim differentiation.
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Clean Thru, Buffalo Wire Works, Mar. 2005, 2 pages. |
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Number | Date | Country | |
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20150021240 A1 | Jan 2015 | US |