MULTI-LAYER COMPOSITE FILTER MEDIA AND METHOD OF MAKING SAME

Abstract

The present disclosure describes a hydroentangled composite filter media that includes a first layer having a plurality of first staple fibers that are entangled. The plurality of first staple fibers have a denier between 0.01 to 1.0. The hydroentangled composite filter media may include a second layer having a plurality of second staple fibers that are entangled. The plurality of second staple fibers have a denier between 1.0 to 50. The second layer extends along and is entangled with the first layer so as to define a gradient of fiber denier along a thickness direction that extends from the first side to the second side. The hydroentangled composite filter media may include a bonding material that at least partially bonds the first staple fibers of the first layer to the second staple fibers of the second layer to impart stiffness to the hydroentangled composite filter media.

Description

CROSS-REFERENCE TO RELATED APPLICATION

The present application claims priority to and the benefit of Indian Application No. 201721028148, filed Sep. 8, 2017, the entire disclosure of which is incorporated by reference into the present application for all purposes.

TECHNICAL FIELD

The present disclosure relates to a composite filter media and a method of making such a composite filter media.

BACKGROUND

Modern automobiles are complicated machines having numerous moving parts which have to work smoothly in a synchronized fashion to give an optimum output, both in terms of power and efficiency. To keep the parts moving smoothly and efficiently it is essential that they are properly lubricated. All the moving parts in the engine need clean oil to properly lubricate them. However, due to constant metal-to-metal contact, tiny bits of metal tend to dislodge due to friction while the engine is working. These dislodged metallic bits flow in the oil stream. If these dislodged bits of metal are allowed to recirculate through the oil, they could damage other metallic parts, which eventually will cause erosion in the engine. A quality oil filter can be employed to stop this erosion from happening. The oil filter cleans the oil as it passes through the filter and prevents abrasive contaminants from damaging other parts in the engine. It is also important that foreign contaminants not be introduced into the fuel line. Fuel filters are used in the fuel line to screen out dirt and rust particles from the fuel. Fuel filters are normally made into cartridges containing a filter paper. Fuel filters serve a vital function in today's modern, fight-tolerance engine fuel systems.

The automotive industry is striving to meet increasingly stringent fuel emission standards and demand for higher efficiently engines. The advent of Bharat-IV and Euro 6 emission standards coupled with the trend toward more compact engines are pushing automotive manufactures and their supplies to develop components that can help address the market shifts related to fuel-efficient. One area of focus is fuel and oil filters. Recent advances in manufacturing and material technologies have led to the development of numerous types of filters. Filter media which were traditionally used were selected from steel wool, wire meshes, metal screens, etc. Today, filters are made from numerous materials such as cellulose or paper, synthetic material, or micro-glass.

Filters may be manufactured from a woven or nonwoven materials. Of the two, nonwoven materials are generally preferred, since nonwovens exhibit certain desirable characteristics, such as versatility, low cost and diverse functionality. Conventional nonwovens may be manufactured using mechanical bonding, chemical bonding, and/or thermal bonding techniques. For filter media, a common bonding technique is needle punching, a form of mechanical bonding. In needle punching, individual fibers are consolidated to form a web by repeated insertion and withdrawal of barbed needles through a fibrous matt of fibers. The constant insertion and withdrawal of the needles may weaken the fabric structure and create undesirable perforations. The perforations can compromise the filtering efficiency of the filter. Hydroentangling is another form of mechanical bonding whereby high pressure water jets are used to entangle the fibers. U.S. Pat. No. 7,381,669 and U.S. Patent App. Pub. No. 2005/0000890 describe exemplary nonwovens manufactured using hydro-entanglement.

SUMMARY

There is a need to develop a filter media that exhibits better efficacy and sustain higher working temperatures over the life of the filter. An embodiment of the present disclosure is a hydroentangled composite filter media with a first side and a second side opposite the first side. The hydroentangled composite filter media may include a first layer having a plurality of first staple fibers that are entangled and defining the first side, the plurality of first staple fibers having a denier between about 0.01 to 1.0. The hydroentangled composite filter media may include a second layer having a plurality of second staple fibers that are entangled and defining the second side, the plurality of second staple fibers having a denier between about 1.0 to about 50. The second layer extends along and is entangled with the first layer so as to define a gradient of fiber denier along a thickness direction that extends from the first side to the second side. The hydroentangled composite filter media may include a bonding material that at least partially bonds the first staple fibers of the first layer to the second staple fibers of the second layer to impart stiffness to the hydroentangled composite filter media.

Another embodiment of the present disclosure is a method for manufacturing a composite filter media. The method includes forming a first fibrous web comprising a plurality of first staple fibers, the first staple fibers having a denier of between about 0.01 to 1.0. The method may include forming a second fibrous web comprising a plurality of second staple fibers, the second staple fibers having a denier of between 1 to about 50. The method may include combining the first fibrous web along one side of the second fibrous web to from a fibrous assembly having a gradient of fiber denier. The method may include hydroentangling the fibrous assembly with a hydro-entanglement unit so that the first fibrous web layer is substantially entangled with the second fibrous web layer so as to define a monolithic composite fibrous media.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing summary, as well as the following detailed description of illustrative embodiments of the present application, will be better understood when read in conjunction with the appended drawings. For purposes of illustrating the present application, the drawings show exemplary embodiments of the present disclosure. It should be understood, however, that the present disclosure is not limited to the precise arrangements and instrumentalities shown in the drawings. In the drawings:

FIG. 1 is a schematic perspective view of a portion of a composite filter media according to an embodiment of the present disclosure;

FIG. 2 is a cross-sectional view of the composite filter media taken along line 2-2 in FIG. 1;

FIG. 3 is a detailed sectional view of a portion of the composite filter media shown in FIG. 2;

FIG. 4 is a process flow diagram for a method of making a composite filter media illustrate din FIGS. 1-3;

FIG. 5 is a schematic of a portion of a manufacturing line used to form the composite filter media illustrated in FIG. 1; and

FIG. 6 is graph illustrating certain properties of a composite filter media according to an embodiment of the present disclosure.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

Referring to FIGS. 1-3, embodiments of the present disclosure include a composite filter media 10. The composite filter media 10 comprises a plurality of layers of staple fibers that are consolidated together via a hydroentangling process as further described below. The composite filter media 10 may be referred to as a hydroentangled composite filter media. The composite filter media 10 may be formed into a filter article suitable for range of applications, such as automotive filters, including, but not limited to, oil filter, air filters, fuel filters, and the like. However, the composite filter media may be used for applications other than automotive uses. The composite filter media, prior to conversion into a filter article, has a planar configuration for packaging in a roll good form, similar to textile roll goods. The composite filter media can be wound, slit, and/or formed into desired shapes for assembly into a filter article.

Continuing with FIGS. 1-3, the composite filter media 10 includes a plurality of layers. In one example, the composite filter media includes first layer 60 of staple fibers and a second layer 80 of staple fibers that is integrated with the first layer 60 of staple fibers. In an alternative embodiment, the composite filter media includes a third layer (not shown) of staple fibers integrated with the first and second layers 60 and 80. In accordance with the illustrated embodiment, the first layer 60 of staple fibers has a first side 62 (also a web face 62) and a second side 64 (or web back 64) opposed to the first side 62 along a vertical direction V. The second layer 80 of staple fibers also has a first side 82 (also a web face 82) and a second side 84 (or web back 84) opposed to the first side 82 along the vertical direction V. The second layer 80 of staple fibers is disposed adjacent to the second side 64 of the first layer of staple fibers along the vertical direction V. The composite filter media 10 has a thickness T that extends from the first side 62 to the second side 84 along the vertical direction. The first and second layers 60 and 80 of staple fibers are substantially coplanar with respect each other. Specifically, the hydroentangled composite 10 can be an elongate material having a length L (see FIG. 1) that extends along a machine direction and a width W along a cross direction CD that is perpendicular to the machine direction MD. The cross direction and machine direction are perpendicular to each other and have the meaning one of skill in the art would ascribe to those terms.

Continuing with FIGS. 1-3, the first layer 60 includes a plurality of first staple fibers 68 that are entangled together, and the second layer 80 includes a plurality of second staple fibers 88 that are entangled together. The plurality of first staple fibers 68 have a denier between about 0.01 to about 1.0. The plurality of second staple fibers 88 having a denier between about 1.0 to about 50. The second layer 80 extends along, and is entangled, with the first layer 60 so as to define a gradient of fiber denier along the thickness T. The fiber denier gradient between the first layer 60 and the second layer 80 creates a pore size gradient that that helps improve filtration efficiency of the composite filter media. Other parameters of the staple fibers may be selected to aid in processing and/or filtration efficiency. In one example, the staple length of the fibers, whether in the first layer 60 and/or second layer 80, can be about 5 mm to about 50 mm. The fiber diameter can range from about 0.1 microns to about 30 microns or higher.

The composite filter medial 10 can be comprised of a range of synthetic fibers. One of all of the layers 60,80 of staple fibers include polypropylene (PP) fibers, polyethylene terephthalate (PET) fibers, polyamide (PA6 and/or PA6,6) fibers, polyethylene (PE) fibers, and/or polylactic acid (PLA) fibers, and/or copolymer of polymer fibers. The fibers can include homogenous staple fibers, bicomponent fibers, or multi-component fibers. Multi-component and/or bi-component fibers have sheath-core configuration, islands-in-the sea configuration, and/or segmented-pie configuration. Furthermore, the cross-sectional shape of the fibers can be varied and include a circular, trilobal, pentalobal, or multi-lobed shaped. While synthetic polymers are possible other fibers types could be used. Furthermore, different fibers blends may be selected for the first layer 60 and/or second layer 80 of fibers.

Continuing with FIGS. 1-3, the first layer 60 and the second layer are integrated together. As shown, the staple fibers in the first layer 60 are entangled and knotted with staple fibers in the second layer 80 using the techniques described herein. Advantageously, the composite filter media 10 is constructed such that the first layer 60 of staple fibers is substantially integrated with the second layer 80 of staple fibers. In one example, the layers 60, 80 are integrated in such a manner that if one attempted to delaminate the layers of fibers, the structural integrity of the each individual fiber layer 60, 80 would be destroyed. Accordingly, the first layer 60 of fibers and the second layer 80 of fibers are not merely laying adjacent to each other. Rather, the first layer 60 of fibers and the second layer 80 of fibers define a monolithic composite web. The composite filter media may also employ a bonding material that at least partially bonds the first layer to the second layer to impart stiffness to the hydroentangled composite filter media. In one example, the bonding material may be chemical bonding or low-melt polymer fibers melted during processing to impart stiffness.

The composite filter media 10 has a range of basis weights. For instance, the hydroentangled composite has a basis weight in the range of about 100 grams per square meter to about 330 grams per square meter. In one embodiment, the basis weight of the hydroentangled composite is in the range of about 150 grams per square meter to about 250 grams per square meter. In another embodiment, the basis weight is in the range of about 170 grams per square meter to about 200 grams per square meter. The basis weight referred to herein can be determined according to ISO 9073-1:1989, Textiles—Test methods for nonwovens—Part 1: Determination of mass per unit area.”

The composite filter media 10 may be formed into a filter article. In operation, the filter media 10 has a fiber composition that is selected withstand elevated temperatures during filtration of oil, filter, air and the like. In one example, the composite filter media is adapted to configured to withstand temperatures of −40 Celsius to about 250 degrees Celsius. In this context, the composite filter media does not substantially degrade over time when exposed to the wide range of temperatures and/or even cyclic variations of temperatures that extend from 40 Celsius to about 250 degrees Celsius.

Turning now to FIGS. 4 and 5, a process 100 and system 200 for manufacturing the multi-layer composite filter media 10 is illustrated. The process 100 as illustrated is designed to form a hydroentangled composite filter media 10 and related filter articles described above. In general, the process 100 includes fiber preparation 110, web formation 120, web introduction 130, consolidation 140, drying 150, a slitting 160, and converting 180. The manufacturing system shown in FIG. 5 includes a first carding machine 210, a second carding machine 220, a conveying member 242, a consolidation unit 230, conveying member 244, drying unit 250, and a winding/slitting unit 260.

Continuing with FIGS. 4 and 5, in fiber preparation step 110. In step 110, bales of staples fibers are opened and larger fiber tufts taken from the bale are reduced in size. The fiber preparation step may include a blending step where the tufts are further opened and a predetermined weight of fibers are deposited onto a conveyer (not shown). Optional coarse and fine opening phases further individualize the staple fiber. From there, a feeding device introduces a loose, random assembly of staple fibers to web formation equipment, such as the first card machine 210 and the second carding machine 220.

The web formation step 120 transforms the random assembly of loose fibers into an ordered fibrous web via first and second carding machines 210 and 210. In step 120, the first carding machine 210 forms a first fibrous web of staple fibers 214 and the second carding machine 220 forms the second fibrous web of staple fibers 224. The first and second webs of fibers 214 and 214 are collected onto the conveying member 242 and transported to the consolidation unit 230.

Continuing with FIGS. 4 and 5, after the web formation step 120, the layers webs of fibrous assembly are consolidated by the consolidation unit 230. In particular, during step 140, the first layer of staple fibers 214 are substantially entangled with the second layer of staple fibers 224 so as to define the hydroentangled composite 10. In accordance with illustrated embodiment in FIGS. 4 and 5, the consolidation unit 220 can be hydro-entanglement unit. The hydro-entanglement unit 220 includes a high pressure module 232 that includes a series water jet nozzle assemblies 234a, 234b, 234c, 234d . . . 228n that are spaced apart along the machine direction MD. The number of water nozzle jet assemblies can be about 2 to about 10. Four water jet nozzle assemblies are shown for illustrative purposes. More than four or less than four could be used. Each water jet nozzle assembly 234a-234d is configured to eject a plurality of high pressure water jets into fibrous web layers 214, 224. A forming surface or screen 236 carries fibrous web along each water jet nozzle assembly 234a-234d where high pressure jets of water cause the staple fibers to entangle with each other. In accordance with an embodiment of the present disclosure, the hydroentangling step 140 includes subjecting the fibrous assembly layers 214, 224 water jets at a pressure of about 100 bar to about 400 bar. A second conveyer 234 advances the hydroentangled composite toward the next process step. Advantageously, hydro-entanglement processes for manufacturing filter media leads to more dimensionally stable and stronger materials. Hydroentangled filter media may also have enhanced filtration efficiency over needle punched filter media since hydroentangled materials do not have additional perforations introduced by the needle. See FIG. 6 and tables 1 and 2 below.

Referring still to FIGS. 4 and 5, in step 150 the hydroentangled composite filter media 10 is introduced to a drying unit 240 via conveyor member 224 to remove moisture from the hydroentangled composite 10. Following the drying step 150, the hydroentangled composite may have a basis weight in the range of about 100 grams per square meter to about 330 grams per square meter. In one embodiment, the basis weight of the hydroentangled composite is in the range of about 150 grams per square meter to about 250 grams per square meter. In another embodiment, the basis weight is in the range of about 170 grams per square meter to about 200 grams per square meter. After the drying step 150, step 160 includes winding. Step 170 includes slitting the composite filter media 10 to required width.

The process 100 may include optional bonding steps whereby a supplemental bonding material is used to further bond the fibers and impart stiffness into the composite filter media 10. In one embodiment, the bonding step may include applying a chemical bonding agent to consolidated web. The chemical bonding agent may be adhesive or binder. Additional heating steps may be required to cure the chemical bonding agent as needed. In an alternative embodiment, the staple fibers include a low-melt polymer fiber. In that case, the bonding step may include an additional heating step whereby the low-melt fibers are exposed to temperature that exceed the melting temperature of the low-melt polymer fiber but do not exceed the melting temperature (or degradation temperature) of the other fibers. This causes the low-melt fibers to at least partially melt. When cooled, the low melt fibers solidity and impart the desired bonding stiffness to the composite filter media. The low melt fibers may comprise between 5% to about 40% or more by weight of the composite filter media.

Following converting and/or slitting steps 160 and 170, the process 100 includes converting 180 the roll goods into filter articles. Such filter articles may include a housing that contains part of the composite filter media a pleated form suitable for the intended application as described further above.

The following examples have been prepared to illustrate various attributes of the composite filter media 10 described herein. Example 1 is a typical needlepunched filter media and example 2 is a composite filter media 10 made according to inventive principles herein. Tables 1 and 2 summarize properties of the examples 1 and 2. FIG. 5 compares the data for example 1 and example 2.

TABLE 1
Example 1
Basis Weight (gsm)               368
Filter Efficiency @ 30 micro (%) 65.06
Filter Efficiency @ 20 micro (%) 22.52
Air Permeability (l/m/s @ 200 pa) 1450
Maximum Pore Size (micron)       139

TABLE 2
Example 2
Basis Weight (gsm)               183
Filter Efficiency @ 30 micro (%) 64.57
Filter Efficiency @ 20 micro (%) 38.84
Air Permeability (l/m/s @ 200 pa) 1750
Maximum Pore Size (micron)       105

As shown in FIG. 5, table 1, and table 2, the composite filter media made as described herein has the same or better filter efficiency with a much lower basis weight. Furthermore, the composite filter media has higher air permeability and lower maximum pore size compared to example 1, the needle-punched filter media. The basis weight is tested according to ISO 9073-1. The filter efficiency is tested according to ISO 4548-4. The air permeability is tested according to ISO 9237. The maximum pore size is tested according to ISO 15901-1. All test methods cited in this disclosure refer to the ISO test methods in effect at the filing date of the present application.

It should be appreciated that the composite filter media may have range of end properties that are suitable for filtration. In one example of an embodiment of the present disclosure, the composite filter media 10 is a hydro-entangled web that includes a first layer of staple fibers with a denier up to about 1.0 denier and a second layer of staple fibers with a denier between 1.0 and 15.0. In such an example, the composite filter media has a basis weight in the range of about 100 grams per square meter to about 300 grams per square meter. In such an example, the staple fibers may be synthetic fibers, and preferably thermoplastic staple fibers. The composite filter media can have a filtration efficiency at 30 microns that is at least 60%. The composite filter media can have a filtration efficiency at 20 microns that is at least 35%. The maximum pore size may range go up to about 150 microns. The air permeability may range from about 1250 to about 2000.

It will be appreciated by those skilled in the art that various modifications and alterations of the present disclosure can be made without departing from the broad scope of the appended claims. Some of these have been discussed above and others will be apparent to those skilled in the art. The scope of the present disclosure is limited only by the claims.

Claims

1. A hydroentangled composite filter media with a first side and a second side opposite the first side, the hydroentangled composite filter media comprising: a first layer having a plurality of first staple fibers that are entangled and defining the first side, the plurality of first staple fibers having a denier between about 0.01 to 1.0;a second layer having a plurality of second staple fibers that are entangled and defining the second side, the plurality of second staple fibers having a denier between about 1.0 to about 50, wherein the second layer extends along and is entangled with the first layer so as to define a gradient of fiber denier along a thickness direction that extends from the first side to the second side; anda bonding material that at least partially bonds the first staple fibers of the first layer to the second staple fibers of the second layer to impart stiffness to the hydroentangled composite filter media.

2. The hydroentangled composite filter media of claim 1, wherein the bonding material is a chemical bonding agent comprising at least one of an adhesive and a binder.

3. The hydroentangled composite filter media of claim 1, wherein the bonding material is a thermal bonding material comprising low-melt polymer fibers.

4. The hydroentangled composite filter media of claim 1, wherein the plurality of first staple fibers and the plurality of second staple fibers each comprise mono-component staple fibers.

5. The hydroentangled composite filter media of claim 1, wherein the plurality of first staple fibers and the plurality of second staple fibers each comprise multi-component staple fibers.

6. The hydroentangled composite filter media of claim 5, wherein the multi-component staple fibers are one of a) islands-in-the sea fibers, b) segmented pie fiber, c) sheath-core fibers, d) side-by-side fibers, and e) lobe-tipped fibers.

7. The hydroentangled composite filter media of claim 1, wherein the plurality of first staple fibers and the plurality of second staple fibers include at least one of a) polypropylene fibers, b) polyethylene terephthalate fibers, c) polyamide fibers, d) polyethylene fibers, and e) polylactic acid fibers.

8. The hydroentangled composite filter media of claim 1, further comprising a third layer between the first layer and the second layer, the third layer having a plurality of third staple fibers, the plurality of third staple fibers having a denier that is different than the denier of the plurality of first staple fibers and the denier of the plurality of second staple fibers, wherein the third layer extends and is entangled with the first layer and second the layer.

9. The hydroentangled composite filter media of claim 1, wherein the composite fibrous media is configured to withstand a temperature in the range of −40 degrees Celsius to 250 degrees Celsius.

10. A method for forming a composite fibrous media, the method comprising: forming a first fibrous web comprising a plurality of first staple fibers, the first staple fibers having a denier of between about 0.01 to 1.0;forming a second fibrous web comprising a plurality of second staple fibers, the second staple fibers having a denier of between 1 to about 50;combining the first fibrous web along one side of the second fibrous web to from a fibrous assembly having a gradient of fiber denier; andhydroentangling the fibrous assembly with a hydro-entanglement unit so that the first fibrous web layer is substantially entangled with the second fibrous web layer so as to define a monolithic composite fibrous media.

11. The method of claim 10, wherein consolidating the first layer and the second layer includes defining a gradient of fiber denier along a thickness direction that extends from a first of the composite filter medial to a second side of the composite filter media.

12. The method of claim 10, further comprising bonding the composite fibrous media to impart stiffness to the hydroentangled composite filter media.

13. The method of claim 12, wherein the bonding step includes applying an aqueous chemical solution comprising a chemical bonding agent to the composite fibrous media.

14. The method of claim 12, wherein the bonding step includes melting low melt polymer fibers in at least one of the first fibrous layer and the second fibrous layer.

15. The method of claim 10, wherein the hydro-entanglement unit includes a plurality of water jet nozzle assemblies, wherein at least one of the water jets assemblies is oriented in the first direction and at least one of the water jets is oriented in the second direction that is offset at an angle with respect to first direction

16. The method of claim 15, wherein the plurality of water jets assemblies includes 2 up to 10 water jet assemblies.

17. The method of claim 15, wherein the plurality of water jets assemblies emit water jets at a pressure between about 50 bars to about 400 bars.

18. The method of claim 17, further comprising drying the composite fibrous media to substantially remove moisture from the composite fibrous media.

19. The method of claim 11, wherein forming the first fibrous web includes carding the plurality of first staple fibers with a first carding machine, and forming the second fibrous web includes carding the plurality of second staple fibers with a second carding machine.

20. The method of claim 10, wherein the plurality of first staple fibers and the plurality of second staple fibers each comprise mono-component staple fibers.

21. The method of claim 10, wherein the plurality of first staple fibers and the plurality of second staple fibers each comprise multi-component staple fibers.

22. The method of claim 21, wherein the multi-component staple fiber and are one of a) islands-in-the sea fibers, b) segmented pie fiber, c) sheath-core fibers, d) side-by-side fibers, and e) lobe-tipped fibers.

23. The method of claim 10, wherein the plurality of first staple fibers and the plurality of second staple fibers include at least one of a) polypropylene fibers, b) polyethylene terephthalate fibers, c) polyamide fibers, d) polyethylene fibers, and e) polylactic fibers.