US3388805A - Wire filter media - Google Patents

Description

United States Patent Oce Patented .fune it, i968 3,388,805 WIRE FILTER MEDlA Richard E. Lovett, Corbin, Ky., assigner to National- Standard Company, Niles, Mich., a corporation of Delaware Filed Mar. 5, 1965, Ser. No. 437,452 2 Claims. (Cl. ZIO-499) ABSTRACT F THE DSCLSURE A warp free wire filter media having a plurality of weft wires of substantially sinusoidal configuration lying in successive adjoining parallel planes in the lengthwise directions of the weft wires, in which the sinusoidal configurations of adjacent weft wires are substantially 180 out of phase with respect to each other, and wherein adjacent weft wires are joined at their crossing portions to each other.

The present invention relates to filter media.

lt is known-that a filter media may be made by combining two or more fabrices as, for example, first and second fabrics, each of which is composed of a first set of substantially parallel filaments, and a second set of substantially parallel filaments extending transversely of the filaments of the first sets, and of which the filaments of the first sets are more easily destructible than the filaments of the second sets. Such first and second fabrics may be disposed in superimposed relation with their second sets of filaments in crossing relation, the crossing portions joined to each other, as by sintering, and then destroying the first sets of filaments of the first and second fabrics to thus provide a filter media composed of the filaments of the second sets in crossing and joined relation providing mesh openings therebetween.

A filter media fabricated as aforenoted is satisfactory for many filtering purposes but has some limitations in that regard in that the mesh openings are normal to the axes of the weft or filler filaments and elongated small diameter foreign material and particles by impact against the surface of the filter media may frequently pass therethrough. Also such known filter media are expensive to fabricate by reason of the need of at least two fabrics with filaments of each thereof being destroyed to provide the end filter media.

A filter media from a single fabric component may be achieved by forming a fabric of rst and second sets of filaments extending in crossing relation with respect to each other, such as a plurality of weft or filler filaments arranged in contacting relation in their lengthwise direction, and a plurality of warp filaments. The weft or filler filaments may then be joined at their contacting portions, for example, by presently known expedients such as by adhesives, sintering, brazing, or welding. Thereafter, the warp filaments may be removed such as by dissolving, vaporizing or melting the same, 0r removing them by mechanical means to provide a filter media composed of the joint weft or filter filaments. Thereafter, if desired, the filter media thus formed may be calendered or otherwise flattened by further sintering or bonding to reduce the size of opening and create a stronger bond at the joint portions of the weft or filler filaments.

An object of the invention is to provide a filter media composed of a single layer of successive weft or filler filaments and in which the weft or filler filaments provide mesh openings therebetween which are not normal to the axes of the weft or filler filaments.

The above and other objects and advantages of the invention will appear from the following detailed description of a preferred embodiment of the invention.

Now in order to acquaint those skilled in the art with the manner of practicing the present invention, there is described below a preferred embodiment of the invention.

The single figure of the drawing shows a filter media on a greatly enlarged scale of and constructed in accordance with the present invention.

In accordance with the present invention it is proposed to form a filter media from a fabric defined by a first set or plurality of first filaments extending in the same lengthwise direction, such as weft or filler filaments, in which the successive or adjacent filaments of the first set have portions thereof in contacting relation, such as by abutting each other at portions of the lengths thereof and/or being disposed in laterally overlapping relation, and a second set or plurality of second filaments extending in the same lengthwise direction in spaced apart relation with respect to each other, such as warp filaments, and with the warp and weft filaments being in crossing relation. Typically, in the art a Dutch weave, either plain or twilled, may be suitably employed in the present invention although it will be understood that the weft or filler filaments and warp filaments need not necessarily be woven, it being suitable for `the present invention to have first and second sets of such fialments in crossing relation.

A typical plain Dutch weave cloth suitable for practicing the present invention may, by way of example, be of x700 mesh embodying .004 inch diameter patented or annealed carbon steel warp Wires, and .0016 inch diameter type 304 stainless steel weft or filter wires. Such fabric may then be sintered to join the contacting portions of successive or adjacent weft or filler wires to each other and to join the crossing portion of the weft or filler wires and the warp wires. Thereafter, the warp wires may be removed, as 4by leaching, leaving an assembly or filter media composed of the weft or filler wires in joined relation with mesh openings therebetween. lf desired, the assembly thus formed may again be sintered to increase the bond strength between the joined weft or filler wires.

More specifically, in carrying out the above method a fabric as above described and in preparation for sintering of the asembly, is preferably cleaned and placed in a mufiie of a sintering furnace. The fabric may then be sintered at 1900 F. for 2 hours in the environment of a reducing atmosphere of dried hydrogen maintained in the mufiie of the sintering furnace. Such a muffie may, for example, 'be made of Inconel and in that event the fabric may be supported on prefired fire brick to prevent its sintering to the muffle. After sintering as above described, the fabric may then be positioned in a section of the inutile extending from the furnace and cooled in the hydrogen atmosphere to prevent scaling on removing of the fabric into room air. Thereafter, the warp wires may be removed by leaching in the typical example above noted in a 30% nitric acid solution at 170 F. for about 1 minute or until all the warp wires are dissolved. Preferably, and again after rinsing and drying, the assembly of the joined weft or filler elements may again `be placed in a sintering furnace and heated for 2 hours at 2200o F. This second sintering step increases the bond strength between the weft or filter wires by increasing the diffusion of the contactinff portions of the wires with each other. It should be observed that the second higher sintering temperature should not be used in the first sintering step as it may well cause undesirable diffusion between the warp and weft or filler wires. Again, after the second sintering step and cooling in the manner above described, a completed filter media according to the invention is provided.

ln the above specific example, the filter media thus formed retained 92% of particles in a range of 45-50 microns contained in the fiuid passed through the filter as determined by a Coulter particle counter. Substantially the same values apply to filtering characteristics of Dutch weave fabric as above described and prior to processing in accordance with the method of the invention. However, and as established in comparative tests between an unprocessed Dutch weave fabric, namely one which was subjected to the first described sintering operation but unleached, and a second processed sample of such Dutch weave fabric which was sintered and leached in accordance with the above described method of the invention, it was found in filtering fluid media containing particles as small as 15 microns that in the unprocessed fabric there is a decrease in the number of particles in the filtrate in the size range of 15 microns whereas in the processed fabric there is no decrease in particle size between 30-35 microns. Thus particles in a range of l5 microns are retained in the unprocessed fabric which in short time would impede filtering of tiuid passing therethrough. In the processed fabric more uniform mesh opening is provided as illustrated yby the foregoing comparative tests.

In further comparative tests of the foregoing processed and unprocessed Dutch weave fabrics the flow rate of the processed fabric was considerably enhanced. At a pressure drop of .15 p.s.i. the flow rate of the processed fabric ran 350 gallons per minute as against 180 gallons per minute for the unprocessed fabric. At 1 p.s.i. differential the fiow rate for the processed fabric was 1000 gallons per minute against 650 gallons per minute for the unprocessed fabric. Thus, at a pressure drop of .15 p.s.i. the tiow rate is increased 85% and at a pressure drop of 1 p.s.i. the fiow rate improves by 54%.

From the foregoing it was observed that the particle retention characteristics of the processed fabric had not been altered to any great extent by removal of the warp wires but rather, in fact, had resulted in improvement because of the smaller range of particle size retention. Further, lbyreason of the decrease in pressure drop of the processed fabric the filter media may be used for a :longer period of time or the filter media may be made of smaller area for miniaturization of a filtering system as well as providing a highly efficient filter media at less cost. In the filter media of the present invention the mesh openings are not normal to the axes of the weft or filler wires and hence are effective in retaining elongated small diameter foreign material from passing through the filter media as well as retaining particles which would normally pass through the filter media by impact.

Also, in practicing the aforedescribed process embodying the second sintering step, the filler 0r weft wires are pressed together into substantially a common plane thus decreasing the size of opening and in one instance was instrumental in reducing the particle size retention from 40 microns to 20 microns.

In addition to the foregoing and after the above discussed second sintering step the joined weft or filler filaments, if desired, may be calendered or pressed, and then sintered for a third time for purposes of increasing the strength of the filter media by providing more and larger areas of contact of the weft or filler filaments.

Referring to the drawing, there is shown somewhat diagrammatically and on a greatly enlarged scale a filter media of the present invention constructed in accordance with the above described method. The filter media indicated at 1 is defined essentially by a plurality of filler or weft wires Zthrough 7 lying in successive adjoining parallel Iplanes perpendicular to the face of the filter media and extending in the lengthwise directions of the wires. Each of the wires 2 through 7 are of substantially sinusoidal or serpentine configuration in their lengthwise directions. Alternate wires, such as wires 2, 4 and 6, are positioned out of phase with the Wires 3, l5 and 7 and adjacent wires at their crossing contacting portions or nodes, as indicated at o, are fused or joined to each other to provide an integrated filter media of the several wires 1 through 7 forming mesh openings as aforedescribed.

It will be understood that the foregoing described filter media concerns one preferred form of the invention but it will be understood that the filler or weft could be secured to'each other in other ways than sintering such as by adhesives, brazing or welding and that the warp wires could be removed by vaporizing, melting or by mechanical means rather than by dissolving as above specifically described. Further, the materials used for the warp and weft or filler filaments may be selected compatible with the steps employed for bonding the weft or filler filaments and for the selective removal of the warp filaments as may be dictated by the chemical and physical characteristicsL desired in the finished filter media. Thus, the warp and weft and filler filaments could include any of many metals, plastic, textile fibers or fiber glass or other suitable materials capable of being arranged to form a fabric of the nature above described.

While there has been disclosed a preferred embodiment of the invention, it will be understood that various modifications and rearrangements may be made therein without departing from the spirit and scope of the invention.

The invention claimed is:

1. A warp free Wire filter media consisting essentially of a plurality of weft wires lying in successive parallel planes in the lengthwise directions thereof, said weft wires each being of substantially sinusoidal configuration in their lengthwise directions, said sinusoidal configurations of adjacent weft wires of said plurality of weft wires being substantially 180 out of phase with respect to each other, and said adjacent weft wires of said plurality of weft wires being fused at their crossing portions to each other.

2. A warp free wire filter media consisting essentially of a plurality of weft wires lying in successive parallel planes perpendicular with the face of said filter media and extending in the lengthwise directions of said weft wires, said weft wires each being of substantially sinusoidal configuration in their lengthwise directions, said sinusoidal configurations of adjacent weft Wires of said plurality of weft wires being substantially 180 out of phase with respect to each other, and said adjacent weft wires of said plurality of weft wires being fused at their crossing portions to each other.

References Cited UNITED STATES PATENTS 1,804,529 5/1931 Dreyfus 156-7 X 2,076,935 4/1937 Burckhalter 21'0-499 X 3,130,487 4/1964 Mears 29-424 3,132,099 5/1964 Eilhauer 210-499 X 3,231,091 1/1966- Kingsbury et al. 210-499 X H SAMIH N. ZAHARNA, Primary Examiner.

REUBEN FRIEDMAN, Examiner. W. S. BRADBURY, Assistant Examiner.

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