US3240237A

US3240237A - Method for making screen

Info

Publication number: US3240237A
Application number: US308149A
Authority: US
Inventors: Wallace E Bixby
Original assignee: Wedge Wire Corp
Current assignee: Wedge Wire Corp
Priority date: 1961-08-10
Filing date: 1963-09-11
Publication date: 1966-03-15
Anticipated expiration: 1983-03-15

Description

March 15, 1966 w, I Y 3,240,237

METHOD FOR MAKING SCREEN Original Filed Aug. 10, 1961 INVENTOR. WHLLA CE E, 5W8? sv' g Hi5 ATTOENE 5 United States Patent M 3,240,237 METHOD FOR MAKING SCREEN Wallace E. Bixhy, Wellington, Ohio, assiguor to Wedge Wire Corporation, Wellington, Ohio, a corporation of Ghio Griginal application Aug. 10, 1961, Ser. No. 130,559, now Patent No. 3,116,239, dated Dec. 31, 1963. Divided and this application Sept. 11, 1963, Ser. No. 308,149 4 Claims. ((31. 149-71) The present application is a division of my copending application Serial No. 130,559, now Patent No. 3,116,239 filed August 19, 1961, for Screen.

This invention relates to a method for making screen assemblies and more particularly to a method for making a marcelled screen assembly suitable for use in dewatering operations carried out in the mining industry, however, the invention is not necessarily so limited.

A screen assembly of the type herein described typically comprises one or more screen sections mounted on a support, each section including a plurality of generally parallel metallic wire elements of narrow width and relatively great length supported by spaced parallel cross bars. The wires are spaced one from the other so as to permit the passage of liquids, dust and small particles of predetermined size through the screen. The individual screen sections may be of any suitable size, a common size being eight feet in length and approximately three feet in width. Often the support for the screen is a vibratory support which shakes the screen and thereby aids in the screening operation. These screens and uses to which they are put are well known in the art.

In operations involving screens of this type, a particu lar problem is encountered when the material passing over the screen includes slivers or platelets as well as generally round or cubical particles. This problem arises from the fact that the earlier screens contained elongated linear slots between the generally parallel wire elements. Platelets or slivers of comparatively large area could pass freely through these slots and in most operations the passage of these comparatively large particles through the screen is objectionable.

In order to alleviate this problem, attempts have been made to form protuberances on the parallel wire elements at spaced intervals, which protuberances would provide localized obstructions in the slots between the wire elements to prevent the passage of oversized slivers or platelets through the screen. For reasons of economy of manufacture, the material forming the protuberances was forced out of the wires in a forming operation. This type of screen was not favorably accepted in the trade for two principal reasons, one being that this type of construction reduces the open area in the screen and the other being that this type of construction is eiteetive only in screens having a comparatively small slot width (one millimeter or less). For large slot widths, the protuberances, which were limited in size clue to the fact that they were taken from the wire, had little effect on the passage of slivers or platelets through the screen. Within the limited range of opening sizes in which the protuberances were effective, the passage of platelets through the screens is generally of minor importance, the problem with platelets being most prominent where the screen opening size exceeds one millimeter.

An object of the present invention is to provide a new and improved screen of the type described, wherein the parallel wire elements which form the screen surfaces are sinuously curved or marcelled, so as to restrict the passage of large slivers or platelets through the screen without limiting the open area of the screen.

Another object of the present invention is to provide a 324,237 Patented Mar. 15, 19%5 new and improved method for fabricating sinuous wire elements useful in screens of the type described.

Other objects and advantages reside in the construction of parts, the combination thereof, the method of manufacture and the mode of operation, as will become more apparent from the following description.

In the drawing:

FIGURE 1 is a fragmentary exploded perspective view illustrating a partially formed wire element employed in the screen of the present invention;

FIGURE 2 is another fragmentary exploded perspective view illustrating a coining operation performed on the partially formed wire elements of FIGURE 1;

FIGURE 3 is a fragmentary perspective view illustrating the wire element after coining according to FIG- URE 2;

FIGURE 4 is a fragmentary plan view illustrating a portion of the screen of the present invention;

FIGURE 5 is a fragmentary sectional view, taken substantially along the line 55 of FIGURE 4;

FIGURE 6 is a fragmentary sectional view, taken substantially along the line 66 of FIGURE 4.

Referring to the drawing in greater detail, FIGURE 4 illustrates a portion of a screen 10 formed according to the present invention. This screen comprises a plurality of generally parallel wire elements 12, each of which is looped about spaced support rods 14. Qnly one of the support rods 14 is illustrated in FIGURE 4. These wire elements are secured in fixed relation by means of nuts 16 threadcdly engaging the ends of the support rods 14.

It is to be understood that FIGURE 4 illustrates only a small portion of the screen which, as previously mentioned, may comprise a section eight feet in length and approximately three feet in width, the support rods 14 being spaced at approximate three-inch intervals along the length of the screen.

As clearly appears in FIGURE 4, each of the wire elements 12 is sinuously undulated in a direction transverse to its length. In the assembled screen, the undulations occupy substantially a common plane, the adjacent wire elements being nested together, so as to form sinuous slots 18 therebetween. These slots 18 each have a substantially constant width throughout the distance between adjacent support rods 14.

In the manufacture of the present screen, it is found impractical to form sinuous undulations in the wire elements 12 prior to the time these wire elements are looped for engagement with the support rods 14. Thus, existing machinery for looping the wire elements requires straight wire elements of uniform cross section. It is therefore advantageous in the formation of the present screen to first loop the wire and then produce the sinuous undulations in the wire. The method for forming the wire elements 12 is illustrated in FIGURES 1 and 2.

FIGURE 1 illustrates a length of wire 12:: of circular cross section which has been looped at spaced intervals to form loops 20 therein, these loops being substantially coplanar. Methods and apparatus for looping the wire element 12a are well established in the art and form no part of the present invention. Ordinarily, spindles 22, as shown in FIGURE 1, engage the loops 20 to maintain a fixed spacing between these loops.

After the wire 12a has been looped, it is passed between a pair of coining

dies

24, 26, as shown in FIG- URE 2. The die 26 is provided with spindles 28 which replace the spindles 22 of the looping machine. The die 24 is provided with apertures 30 to receive the spindles 28, thus enabling the dies to move into close operative relationship.

Disposed between the apertures 30 and the die 24- are a plurality of coining punches 32 having generally trapezoidal working faces and arranged in a linear array. The spaces 34 between the coining punches are recessed away from the working faces of the coining punches to receive metal displaced from the wire elements during the coining operation, as will be more fully described subsequently. At the working face, each coining punch 32 slopes inwardly of the die 24 as it moves upwardly, establishing a shoulder 33 overlying the coining punches. The die 26 has a similar array of coining punches adapted to fit under the shoulder 33 as the

dies

24, 26 coact. In the die 26, the coining punches have a shape similar to that of the coining punches 32, but are staggered relative to the coining punches 32, such that the coining punches in the die 26 are directly opposite the recesses 34- in the die 24.

FIGURE 3 illustrates a wire element 12 formed by compressing the wire element 12a between the coining

dies

24, 26. As can be observed, this wire element has spaced indentations or flats 33 along the sides thereof formed by the coining punches in the coining dies, the indentations on one side of the wire element being staggered relative to the indentations on the other side of the wire element.

Between the indentations on each side of the wire ele- :ment are protuberances 40 produced by the displacement of material from the wire elements, which is guided into the recesses 34 of the coining dies due to the shape of the coining dies.

Due to the aforementioned slope in the working faces of the coining punches 32 in each of the

dies

24, 26, the opposing working faces diverge from bottom to top. Thus, when the

dies

24, 26 coact, the wire element 12a is wedged upwardly by the working faces of the coining punches. The wire element 12a is therefore forced against the under surface of the shoulder 33 on the coining die 24, producing a flat upper surface 44 on the completed wire element 12. The

dimples

42 and 43 which appear on the upper and lower surfaces, respectively, of the wire element represent surface portions of the original wire element 12a which were not directly engaged by portions of the coining dies.

Surrounding each aperture in the die 24 and each spindle 28 in the die 26 is an annular recess 36 which permits the dies to coact without exerting pressure on the lower portions of the loops 20 formed in the wire element. However, at the upper portion of the loop where the wire crosses itself, the wire is of double thickness and this portion is compressed between the

die elements

24 and 26 to form flattened surfaces 46 at the tops of the loops. When the wire elements 12 are assembled side by side, as illustrated in FIGURE 4, the spacing between these wire elements is determined by the extent to which the wire elements have been compressed at the point of cross-over in the loops. It will be understood, of course, that the thickness of the wire element at the point of cross-over in the loops determines only the minimum separation between wire elements. Where a greater separation is desired, washers or shims can be used to increase the separation, as is well known in the art.

FIGURE 5 illustrates the cross sectional shape of the wire elements at the point where a protuberance has been formed in a recess 34 of one of the coining dies. Due to the slope of the working face of the coining punch on one die, and due to a complementary slope in the recess 34 on the opposite die, the coined wire element has a converging taper from top to bottom, as shown in FIGURE. 5.

FIGURE 6 illustrates the cross section at a point intermediate the protuberances 40 where both sides of the wire elements have been acted on by the working face of a coining punch. Here, again, since the coining punches are sloped in a complementary manner, the wire element has a converging taper from top to bottom. Thus, at substantially all points along the length of the formed wire element 12, except at the loops 20 therein, the wire elements have a downwardly converging cross sectional shape. This feature is highly desirable in screening surfaces for the reason that it permits particles which pass through the minimum thickness of the slots in the screen to fall freely through a diverging gap. Since the point of minimum thickness of the slots is near the top working surface of the screen, particles which cannot pass through the slots are held at the top of the screen where they can be carried off the screen by the fiow of material passing thereovcr.

From the foregoing description, it will be apparent that the method disclosed provides a means for forming a sinuously undulated wire element after loops have been formed in the wire element and without damage to the loops. As clearly appears in FIGURE 4, the wire elements formed with the method of the present invention cooperate to produce a uniform slot dimension in a marcelled screen formed from the wire elements, the slot being sinuously undulated so as to minimize the passage of platelets or slivers through the screen.

In FIGURE 4 it will be noted that the undulatory crests in one Wire element project partially between the undulatory crests of the adjacent wire element, thus precluding even the thinnest of slivers or platelets from passing through the screen if the overall length of the platelets exceeds one-half the undulatory wave length of the wire element. Due to this characteristic, it is also apparent that the spacing between wire elements can be increased with the aid of shims or washers, so as to increase the slot width of the screen without materially increasing the probability that slivers or platelets will pass through the screen. A single set of coining dies may be used to produce wire elements capable of satisfying a comparatively wide range of slot widths.

It will occur to those skilled in the art that the character of the undulations in the wire elements 12 may be varied by adjusting the size of the coining punches 32 in the coining dies 24, 26. In the coining dies illustrated, the punches 32 have a width greater than the width of the recesses 34 therebetween. Thus the opposing punches 32 in the dies 24 and 26 overlap and do not interdigitate. However, if the punches 32 are made narrower, with a consequent increase in the spacing between the punches, it is possible to produce coining dies with punch elements which interdigitate, thereby enhancing the undulating character of the wire elements. However, it is found that for screen requirements in most commercial installations, a slot width ranging from one to six millimeters is required and this range can be covered without interdigitating punch elements.

Although the preferred embodiment of the device and method of making same has been described, it will be understood that within the purview of this invention various changes may be made in the form, details, proportion and arrangement of parts, the combination thereof and mode of operation, which generally stated consist in a device capable of carrying out the objects set forth, as disclosed and defined in the appended claims.

Having thus described my invention, I claim:

1. The method of making marcelled screen structures, said method utilizing elongate wire elements and a pair of coining dies, each die supporting spaced coining punches disposed in linear array in the face thereof, said method including the steps of forming equally spaced loops along the length of a plurality of said wire elements, coining each said wire element intermediate each pair of loops therein with said coining dies, said coining dies being arranged in face to face relation with the coining punches in the opposing faces thereof disposed in staggered overlapping relation whereby a sinuous configuration is imparted to each wire element coined therebetween, and securing said plurality of coined wire elements in side by side relation with the loops therein juxtaposed and with the sinuously coined portions thereof in nesting relationship.

2. The method according to claim 1, wherein said wire elements are initially of circular cross section and wherein the coining punches in the faces of said die elements have substantially fiat working surfaces, said method including the step of inclining the working surfaces in one coining die relative to the Working surfaces in the other prior to said coining step whereby the Wire elements, when coined, have a tapered cross section and, when assembled side by side, establish diverging slots therebetween.

3. In the method of making marcelled screen structures the steps of applying pressure simultaneously to diametrically opposite sides of the wire element at spaced intervals along the length of said wire element to compress said wire element at said spaced intervals thereby extruding metal from said wire element at said spaced intervals to form spaced protuberances in said wire element between said spaced intervals, there being one protuberance formed between each pair of said spaced intervals, and simultaneously with said pressure application guiding alternate of said protuberances to one side References Cited by the Examiner UNITED STATES PATENTS 2,182,342 12/1939 Karitzky 140105 2,195,741 4/1940 Scott -30 2,573,171 10/1951 Wery 8030 2,677,398 5/1954 Medendorp 105 2,778,385 1/1957 Gier 14071 2,868,237 1/1959 Larkin 140102 2,914,643 11/1959 Fields et a1. 80-30 CHARLES W. LANHAM, Primary Examiner.

Claims

1. THE METHOD OF MAKING MARCELLED SCREEN STRUCTURES, SAID METHOD UTILIZING ELONGATE WIRE ELEMENTS AND A PAIR OF COINING DIES, EACH DIE SUPPORTING SPACED COINING PUNCHES DISPOSED IN LINEAR ARRAY IN THE FACE THEREOF, SAID METHOD INCLUDING THE STEPS OF FORMING EQUALLY SPACED LOOPS ALONG THE LENGTH OF A PLURALITY OF SAID WIRE ELEMENTS, COINING EACH OF SAID WIRE ELEMENT INTERMEDIATE EACH PAIR OF LOOPS THEREIN WITH SAID COINING DIES, SAID COINING DIES BEING ARRANGED IN FACE TO FACE RELATION WITH THE COINING PUNCHES IN THE OPPOSING FACES THEREOF DISPOSED IN STAGGERED OVELAPPING RELATION WHEREBY A SINUOUS CONFIGURATION IS IMPARTED TO EACH WIRE ELEMENT COINED THEREBETWEEN AND SECURING SAID PLURALITY OF COINED WIRE ELEMENTS IN SIDE BY SIDE RELATION WITH THE LOOPS THEREIN JUXTAPOSED AND WITH THE SINOUSLY COINED PORTIONS THEREOF IN NESTING RELATIONSHIP.