Having thus described the invention in general terms, reference will now be made to the accompanying drawings, which are not necessarily drawn to scale, and wherein:
The present inventions now will be described more fully hereinafter with reference to the accompanying drawings, in which some, but not all embodiments of the inventions are shown. Indeed, these inventions may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will satisfy applicable legal requirements. Like numbers refer to like elements throughout.
A filter cartridge 10 of the type commonly used spa and pool filters is shown in
One embodiment of a filtration medium 20 in accordance with the present invention is shown in greater detail in
The filtration medium 20 includes at least one nonwoven layer formed of multicomponent continuous filaments. Preferably, the continuous filament nonwoven fabric layer is a spunbond nonwoven fabric. Examples of various types of processes for producing spunbond fabrics are described in U.S. Pat. No. 3,338,992 to Kinney, U.S. Pat. No. 3,802,817 to Matsuki, U.S. Pat. No. 4,405,297 to Appel, U.S. Pat. No. 4,812,112 to Balk, and U.S. Pat. No. 5,665,300 to Brignola et al. In general, these spunbond processes include steps of extruding molten polymer filaments from a spinneret; quenching the filaments with a flow of air to hasten the solidification of the molten polymer; attenuating the filaments by advancing them with a draw tension that can be applied by either pneumatically entraining the filaments in an air stream or by wrapping them around mechanical draw rolls of the type commonly used in the textile fibers industry; depositing the attenuated filaments randomly onto a collection surface, typically a moving belt, to form a web; and bonding the web of loose filaments.
More particularly, the continuous filaments of the nonwoven layer are randomly arranged and bonded to one another to form a strong, porous, water permeable filtration medium having a thickness and stiffness sufficient for being pleated, as described above. The multicomponent filaments have at least two thermoplastic polymer components that are arranged in substantially distinct zones within the filament cross-section. One of the polymer components has a melting temperature that is less than the melting temperature of the other polymer component or components, and this lower-melting polymer component is present on at least a portion of the surface of the filament where it functions to bond the filaments to one another. This polymer component also contains an antimicrobial agent.
The melting temperature of a polymer may be determined with differential scanning calorimetry (DSC). The melting of a polymer generally occurs over a range of temperatures during which time, heat is absorbed by the polymer as the crystalline structure of the bonds is broken and the polymer chains lose their ordered arrangement. DSC may be used to plot the amount of heat introduced into the system as the temperature increases. In the context of the present invention, the melting temperature of the polymer corresponds to the temperature at which the greatest amount of heat has been introduced into the polymer. In a DSC plot, this is generally the highest point on the graph of the melting transition.
Suitable polymers for the lower melting temperature first component include linear low density polyethylene (density 0.95-0.96), low density polyethylene (density 0.92-0.94), and high density polyethylene (density 0.96 and higher). In one advantageous embodiment, the lower melting first component comprises high density polyethylene having a density between and including 0.95 and 0.96 g/cc. Other suitable polymers include polylactic acid (PLA) polymers and copolymers,
Suitable polymers for the higher melting second component include polypropylene, polyesters such as polyethylene terephthalate (PET) or polybutylene terephthalate (PBT), and polyamides such as nylon-6 or nylon 6-6.
The continuous filaments are bonded to each other at points of contact to impart strength and integrity to the nonwoven layer, but the nonwoven structure remains sufficiently open and porous to provide the requisite air and water permeability. The bonding can be accomplished by various known means, such as by thermal area bonding, calendering, point bonding, ultrasonic bonding and the like. Area bonding and point bonding are two common techniques that may be used to thermally bond the web. Area bonding typically involves passing the web through a heated calender composed of two smooth steel rollers or passing heated steam, heated air or other gas through the web to cause the filaments to become softened and fuse to one another. In a preferred embodiment, the web is area bonded with a heated calender nip comprised of smooth steel rolls. Area bonding advantageously provides enhanced stiffness to the filtration medium due to the presence of bond sites at the filament cross-over locations. During area bonding, the lower melting temperature polymer component softens and flows together at the filament cross-over locations to produce a multiplicity of bond sites distributed uniformly throughout both the lateral extent of the fabric and its thickness. However, the fabric structure remains open and porous, with the individual filaments spaced apart from one another except at the filament cross-over locations.
Point bonding consists of using a heated calender nip to produce numerous discrete bond sites. The point bonding calender nip is comprised of two nip rolls, wherein at least one of the rolls has a surface with a patterned of protrusions. Typically, one of the heated rolls is a patterned roll and the cooperating roll has a smooth surface. As the web moves through the calender roll, the individual filaments are thermally bonded together at discrete locations or bond sites where the filaments contact the protrusions of the patterned roll. Any pattern known in the art may be used, with typical embodiments employing continuous or discontinuous patterns. Preferably the calender rolls are engraved with a pattern that produces point bonds that cover between 6 and 40 percent of the area of the web, more preferably 8 to 30 percent and most preferably 12 to 20 percent. By bonding the web in accordance with these percentage ranges, the filaments are allowed to elongate throughout the full extent of stretching while maintaining the strength and integrity of the fabric.
As used herein, the term “multicomponent” refers to continuous filaments prepared from two or more polymers which are present in discrete structured domains in the filament cross-section, as opposed to blends where the polymer domains tend to be dispersed, random or unstructured. The polymer domains or components are arranged in substantially constantly positioned distinct zones across the cross section of the multicomponent filament and extend continuously along the length of the filaments. A preferred configuration is a sheath/core arrangement, wherein the lower melting temperature first polymer component forms a sheath that substantially surrounds the higher melting temperature second component, the core. Other structured fiber configurations as known in the art may be used, such as side-by-side, segmented pie, islands-in-the-sea, or tipped multi-lobal structures. In these configurations, the lower melting temperature polymer component is present on at least a portion of the filament surface.
The higher melting temperature second polymer component provides the necessary strength, durability and stiffness for the filtration medium and preferably comprises at least 70 percent by weight of the filament, more desirably at least 75 percent by weight of the filament. The lower melting first polymer component serves for bonding together the filaments of the nonwoven layer and to provide controlled release of the antimicrobial agent. The lower melting first polymer component preferably comprises no more than 30 percent by weight, more desirably up to 25 percent of the filament. In some preferred embodiments of the invention, the filaments are sheath-core bicomponent filaments wherein the sheath component comprises 20 percent or less of the filament by weight and the core comprises 80 percent or more of the filament by weight.
In one particularly advantageous embodiment, the filtration medium includes a nonwoven layer of continuous circular cross-section sheath-core filaments with a concentric a sheath of high density polyethylene that surrounds a core of polyethylene terephthalate or polypropylene. Multicomponent filaments comprising a polyethylene sheath component and a polyethylene terephthalate or polypropylene core component may have many desirable characteristics. For example, polyethylene terephthalate has many desirable characteristics including strength, toughness, stiffness, and heat and chemical resistance. Using polyethylene as the first polymer component permits many thermally sensitive melt additives to be incorporated throughout the thickness of the polyethylene during the extrusion process without degradation or loss of desired activity, such as antimicrobial activity. As a result, a nonwoven fabric comprising a thermally sensitive antimicrobial agent may be produced that includes many of the physical properties that are commonly associated with polyethylene terephthalate. In addition, the polyethylene sheath provides a reduced friction release surface from which the collected debris may be more readily removed from the filter medium by rinsing. A further benefit of a first polymer component comprising polyethylene is that it will more readily remove body oils that accumulate in spas and hot tubs since these oils have an affinity to polyethylene. When polypropylene is used as the core component, the filaments can be extruded at a lower temperature than with polyethylene terephthalate, providing processing advantages, while benefiting from the strength, toughness, stiffness and heat resistance of the polypropylene and the protection of the surrounding polyethylene sheath.
As discussed above, an antimicrobial agent is blended with the resin of the first polymer component. Preferably, the antimicrobial agent is present in the first component at a concentration of from 0.01% to 5% by weight, based on the weight of the first polymer component. The specific concentration employed is dictated by the type of antimicrobial agent used and the target organisms, and can be readily determined without undue experimentation using routine screening tests. In one alternative embodiment, the first polymer component may include two or more antimicrobial agents, which may have the same or different functionality.
Various organic antimicrobial and antifungal agents, such as triclosan antimicrobial melt additive available from Microban® can be suitably employed. For example, an antimicrobial agent such as 2,4,4′-trichloro-2′-hydroxydiphenol ether, or 5-chloro-2-phenol (2,4-dichlorophenoxy) compounds commonly sold under the trademark MICROBAN® B by Microban Products Company, Huntersville, N.C. may be used. The antimicrobial agent is a broad spectrum antimicrobial agent that is effective against the majority of harmful bacteria encountered in water. Some organic antimicrobial agents, including those just mentioned, can be thermally degraded at temperatures that are required to extrude many fiber forming polymers. For instance, many organic melt additives, such as triclosan generally cannot be incorporated into PET fibers because they may volatilize or decompose at the temperatures necessary for the melt extrusion of PET polyester fibers. However, these melt additives may be incorporated into the first polymer component without degradation because the first polymer component may be extruded at temperatures below the degradation temperature of the organic additives. Preferably, the first polymer component has a melting temperature that is less than about 170° C.
The density and composition of the first polymer component may be selected to control the rate at which the antimicrobial agent migrates to the surface of the fibers of the nonwoven fabric. In general, many antimicrobial agents have some degree of mobility in polyolefin polymers. The density and/or composition of the first polymer component may be selected so that the antimicrobial agent diffuses through the polymer at a desired rate. For example, the first polymer component may comprise a blend of polymers, such as polyethylene, polypropylene, polybutylene, and copolymers thereof, wherein the composition of the blend, and proportions of each polymer in the blend, is selected so that the antimicrobial agent diffuses at a desired rate. In addition, the antimicrobial agent typically has little to no affinity for polyesters, such as polyethylene terephthalate. As a result, a nonwoven fabric may be prepared in which the antimicrobial agent diffuses to the surface of each fiber at a desired rate without significant migration of the antimicrobial agent into the core of the fiber. Nonwoven fabrics may thus be prepared wherein the first polymer component serves as a reservoir for controlled diffusion and release of the antimicrobial agent.
The presence of the antimicrobial agent in the first polymer component effectively inhibits the grown of microorganisms on the surface of the filter element during the filtration operation and even after repeated cleanings of the filter cartridge. Because the antimicrobial agent is dispersed throughout the thickness of the first polymer component, it provides antimicrobial activity to the surface of every fiber. The first polymer component serves as a reservoir for sustained diffusion and release of the antimicrobial agent. The nonwoven fabric of the invention may be able to sustain a desired antimicrobial activity for a relatively longer period of time in comparison to a nonwoven fabric that has been dye-treated with an antimicrobial agent.
For spa and pool filter applications, the nonwoven fabric is preferably designed to meet certain desired levels stiffness, thickness, and permeability. For instance, the nonwoven fabric preferably has a thickness, basis weight and stiffness that allows for pleating using commercially available pleating processes and machinery, such as rotary, blade, and push-bar type pleaters. The nonwoven fabric is preferably capable of being formed into sharp creases or folds without loss of strength, and of maintaining its shape in the creased or pleated condition. The basis weight is desirably about 12 to 204 grams per square meter. The filaments typically have a weight per unit length of from about 2 to 6 denier per filament (2.2 to 6.6 dtex per filament).
The stiffness of the filtration medium may be quantified using industry standard test instruments, such as the Handle-O-Meter which measures flexibility (or conversely for the purposes of the present invention, stiffness) of sheet materials such as nonwovens in accordance with ASTM D 2923 or the Association of the Nonwovens Fabrics Industry (INDA) standard test method IST 90.3. Handle-O-Meter measurements are made on an instrument by the Thwing-Albert Instrument Co. of West Berlin, N.J. The measurements are the force in grams to push a 100 mm wide fabric into a slot which is 100 mm wide. In conducting the Handle-O-Meter measurements, the fabric is tested from both the top and the bottom and in both the machine direction and the cross direction and the results are averaged. The filtration medium 20 preferably has a Handle-O-Meter stiffness of at least 35 grams, and more desirably at least 70 grams, and for certain applications more desirably at least 110 grams.
In one advantageous embodiment, the nonwoven fabric has a thickness of from 10 to 40 mils (0.2 to 1 mm). The thickness of the nonwoven fabric affects both its filtration characteristics and its pleatability. Too thin a fabric will result in the filtration taking place primarily at the fabric surface. The filter will be easier to clean, but it will clog much more quickly. Thicker materials provide some depth filtration along with surface filtration, which will extend the time required between cleanings. Thickness also affects the pleating and the quality of the final pleat (e.g. pleat shape and sharpness of the pleat), since fabric thickness is directly related to stiffness. Overly thin materials will not have sufficient stiffness to retain a pleat, and the pleats will tend to collapse upon themselves. Overly thick materials are so stiff that they will form poor pleats or will tend to return to the original unpleated configuration. Overly thick materials may also result in fewer pleats for a given area which may result in reducing the number of square feet of surface area in a filter element. This typically does not reduce filter efficiency, but it may result in the filter needing to be cleaned more frequently. Consequently, for pool and spa filtration applications, it is particularly important that the filtration medium have a thickness within the above-noted range.
Fabric thickness may also affect the performance of the fabric as a filtration medium. One important performance characteristic of a filtration medium is turbidity reduction. This measures filtration efficiency in terms of the number of tank or volume turnovers required to reach a desired level of turbidity or water clarity. The NSF/ANSI Standard 50 outlines a turbidity reduction test in Annex B.5. A second performance characteristic of filtration media is plug time. This measures the time interval between required filter cleanings. An effective filter medium must balance these two countervailing characteristics in order to provide filtration efficiency with a reasonable rate of filtering while also providing a suitable time interval between the need to clean or replace the filter. The thickness and permeability of the nonwoven fabric directly affect these properties. For example, a fabric with a relatively high permeability will take longer to remove particulate matter from the water but the interval between cleanings will be greater. Conversely, if the permeability of the fabric is relatively low, filtering efficiency will be high but the time between required cleanings will be too short. However, if permeability is too large, smaller particles may never be captured and the water will be more turbid than desired.
The permeability of the nonwoven fabric may be conveniently evaluated by measuring its air permeability using a commercially available air permeability instrument, such as the Textest air permeability instrument, in accordance with the air permeability test procedures outlined in ASTM test method D-1117. Preferably, the nonwoven fabric should have an air permeability, as measured by this procedure, of from 150 to 270 cfm/ft2/min.
If additional stiffness is desired for the nonwoven fabric beyond that obtained from the initial nonwoven manufacturing operation, a stiffening coating (not shown) may be applied to one or both surfaces of the nonwoven fabric. More particularly, at least one of the exposed surfaces may be provided with a resin coating for imparting additional stiffness to the nonwoven fabric so that the fabric may be pleated by conventional pleating equipment. By varying the amount of resin coating applied, the air permeability of the nonwoven fabric may also be controlled as required for specific filtration applications. The resin coating may be applied to the nonwoven fabric using conventional coating techniques such as spraying, knife coating, reverse roll coating, or the like. Exemplary resins include acrylic resin, polyesters, nylons or the like. The resin may be supplied in the form of an aqueous or solvent-based high viscosity liquid or paste, applied to the nonwoven fabric, e.g. by knife coating, and then dried by heating.
In other advantageous embodiments, additional stiffness, thickness or other desirable attributes can be obtained by making the nonwoven fabric filtration media of a multilayer construction. At least one of the layers comprises a nonwoven fabric as described above comprising multicomponent filaments formed from a lower melting temperature first polymer component and a higher melting temperature second polymer component, wherein an organic antimicrobial agent is incorporated in the lower melting first polymer component. This nonwoven fabric layer can be combined with one or more additional nonwoven layers of the same or of different construction. For example, a multi-layer composite nonwoven fabric filtration medium can be formed from 2 to 6 layers of nonwoven fabric. The additional nonwoven layer or layers can be prefabricated and the multiple preformed layers can be combined to form an integral unitary filtration medium by bonding under heat and pressure, for example with a calender. Alternatively, the additional layer or layers of can be produced in-line in a continuous operation by extruding the additional layers from one or more additional spin beams. If all of the nonwoven layers are of identical construction and composition, the individual layers will be indistinguishable in the final filtration medium product. However, producing the filtration medium from multiple layers provides flexibility in the manufacturing process and also improves the uniformity of the filtration medium. By combining multiple nonwoven layers of different construction and/or composition, various advantages are realized. For example, one of the layers can incorporate the organic anti-microbial agent triclosan in the polyethylene sheath component of the multicomponent filaments, and another of the layers can be a similar sheath-core bicomponent spunbond nonwoven, but wherein the polyethylene sheath contains a silver anti-microbial agent. In another embodiment, an optional additional nonwoven layer can include sheath-core multicomponent filaments in which a copper antimicrobial agent is present in the polyethylene sheath component. In another embodiment, one or more nonwoven layers of sheath-core multicomponent filaments containing an organic antimicrobial agent in the polyethylene sheath component, can be combined with another nonwoven layer of an entirely different construction, for example a layer of a Reemay® nonwoven fabric formed from polyethylene terephthalate filaments. This construction would provide added tensile properties and strength, with the composite filtration medium exhibiting different properties and appearance on its opposite surfaces.
In some embodiments, stabilizers and antioxidants may also be added to the polymer components. Other additives may also be added in accordance with the present invention. For example inorganic additives such as titanium dioxide, talc, fumed silica or carbon black. The polymer resin may also contain other additives, such as other polymers, diluents, compatibilizers, antiblocking agents, impact modifiers, plasticizers, UV stabilizers, pigments, delusterants, lubricants, wetting agents, antistatic agents, nucleating agents, rheology modifiers, water and alcohol repellents, and the like. It is also anticipated that additive materials which have an affect on processing or product properties, such as extrusion, quenching, drawing, laydown, static and/or electrical properties, bonding, wetting properties or repellency properties may also be used in combination with the polymer components. In particular, polymeric additives may also be used that impart specific benefits to either processing and/or end use.
In one alternative embodiment, the filtration medium may also include one or more colorants, such as a pigments and/or dyes, that are incorporated into the nonwoven fabric and that controllably fade in color during the life-span of the filter element. The amount and rate of color loss of the colorant may be used to help determine the remaining life of the filter element and its expiration. In this regard,
As discussed above, the colorant fades during use of the filter element. As a result, the filtration medium will produce a change in color that is visible to a user. In one particularly advantageous embodiment, the amount of colorant that is incorporated into the filtration medium may be selectively controlled so that the change in color is correlated with the diffusion of the antimicrobial agent out of the filtration medium. The change in color may be controlled to indicate when the amount of antimicrobial agent in the fabric has decreased below a desired level and the filter element should be replaced. In one alternative embodiment, the filter may be packaged with, or include a reference scale which may be used by a person to determine the remaining life of the filter element. The colorant which is susceptible to fading can be incorporated in the sheath component of the sheath-core core bicomponent filament only, or in both the sheath and core components. In another alternative embodiment, the core component of the sheath-core bicomponent filament can be colored with a non-fading permanent colorant or pigment of one color, for example red, and the sheath component can be colored with a colorant or pigment which is susceptible to fading, for example a blue pigment. Thus, the filter element can be caused to completely change color, e.g. from blue to red, indicating that the filter element should replaced.
The following examples are included to exemplify the invention and should not be considered as limiting the scope of the invention.
In the description above and in the examples that follow, the following test methods were employed to determine various reported characteristics and properties. ASTM refers to the American Society for Testing and Materials.
Basis Weight is a measure of the mass per unit area of a fabric or sheet and was determined by ASTM D-3776-96, which is hereby incorporated by reference, and is reported in units of g/m2.
Grab Tensile Strength is a measure of the breaking strength of a fabric or sheet and was conducted according to ASTM D 4632-96, which is hereby incorporated by reference, and is reported in Newtons or pounds. Grab tensile strength is reported in the examples for the machine direction (MD) and for the cross-direction (XD).
Percent Elongation is measured at the point where the sample initially fails and is the elongation at which the load peaks during the grab tensile measurement. Percent elongation is reported in the examples for the machine direction (MD) and for the cross-direction (XD).
Frazier Air Permeability is a measure of air flow passing through a sheet under at a stated pressure differential between the surfaces of the sheet and was conducted according to ASTM D 737, which is hereby incorporated by reference, and is reported in (m3/min)/m2.
Mullen is a measure of the force required for a blunt object to rupture a fabric or sheet and was determined by ASTM D 1117, which is hereby incorporated by reference, and is reported in (lbs/in2).
Thickness of the fabric or sheet was determined according to ASTM D 1777-96, which is hereby incorporated by reference, and is reported in mils (1 mil=0.001 inch).
Stiffness was measured by the Handle-O-Meter in accordance with ASTM D-2923, which measures the combined effects of substrate flexibility and surface friction. The resistance to push a substrate into a slot is measured and reported in grams. The stiffer the material the greater the resistance.
Three different spunbond nonwoven fabrics were prepared in accordance with the invention. The fabric samples comprised substantially continuous bicomponent filaments that were thermally bonded to one another. The bicomponent filaments had a sheath/core configuration wherein the weight ratio of the sheath component to the core component was about 30:70. The sheath comprised a high density polyethylene resin, which is available from Dow Plastics. The high density polyethylene resin had a density of 0.95 g/cm3 and a melt index of 17 g/10 min. The core is comprised of polyethylene terephthalate, which is available from DuPont. The polyethylene terephthalate can have a density of 1.3 to 1.4 g/cm3 and an intrinsic viscosity of 0.58 to 0.72 DI./g. Samples 1 and 2 included an antimicrobial agent in the sheath in an amount from about 0.3 wt. %, based on the weight of the first polymer component. The antimicrobial agent is triclosan, which is available from Microban® under the product number CMPDTR 175-1.
The samples were prepared by extruding the two polymer components through separate extruders. The polyethylene component was melt extruded at a temperature of about 160° C. and the polyethylene terephthalate component was melt extruded at a temperature of about 280° C. The two separate polymer components were then introduced into a spinneret that is configured to combine the polymer components to produce sheath/core bicomponent fibers. The two polymer components were combined in the spinneret to form the bicomponent fibers. The bicomponent fibers were then quenched, drawn, and deposited as a fibrous web onto a moving belt. Two of the samples, Samples 1 and 2, were area bonded by passing the moving web through a heated calender nip comprised of two smooth steel rolls having a temperature of 200° C. The filaments of Sample 3 were thermally bonded together by passing the moving web through a heated patterned calender nip to produce a point bonded nonwoven fabric having about 20% of its area bonded together. The resulting samples have the properties described in Table 1. The results show that for a comparable basis weight, the product of the present invention (Sample 1) is stronger than Control 1 in Mullen and Grab tensile strength and it is stiffer.
The filtration efficiency as a function of particle diameter for Samples 1-3 were compared to the control sample (Control 1). Efficiency was measured by passing a liquid medium having latex particles through the samples at a flow rate of 1 L/min. The liquid medium contained 5,000 particles per mL. The filtration efficiencies of the samples are calculated with the following equation:
wherein: Feff=Efficiency;
The comparative results are shown graphically in
A spunbond nonwoven fabric with a basis weight of 34 grams per square meter (gsm) is formed from round cross-section sheath-core continuous bicomponent filaments. The sheath comprises a high density polyethylene resin (density of 0.95 g/cm3 and a melt index of 17 g/10 min) containing about 0.3 wt. % of the antimicrobial agent is triclosan, which is available from Microban®. The core component comprises polyethylene terephthalate. The filaments have a ratio of sheath to core by weight of 20/80. The fabric is prepared by extruding the two polymer components through separate extruders as in Example 1, followed by area bonding the nonwoven web in a through-air bonder.
Three layers of this fabric are combined and directed through a heated calender nip comprised of two smooth steel rolls having a temperature of 200° C. The resulting composite nonwoven fabric filtration medium has an overall basis weight of 102 gsm and a stiffness that allows it to be pleated to form crisp, shape-sustaining pleats.
Two layers of the fabric of Example 3 are combined with one layer of a 34 gsm spunbond polyester nonwoven fabric produced by BBA Fiberweb under the trademark Reemay® and the combined layers are bonded together by passing through a heated calender nip as in Example 3. The Reemay nonwoven fabric consists of an area bonded web of polyethylene terephthalate matrix filaments bonded together by binder filaments of a lower melting polyethylene isophthalate copolymer. The resulting composite nonwoven filtration medium exhibits excellent tensile strength and stiffness properties, with a low-friction release surface on the polyethylene-containing side of the composite and with the opposite side presenting a surface appearance similar to that of a Reemay® nonwoven fabric.
A fabric similar to that of Example 3 is produced except that the polyethylene sheath component contains 0.3 wt. % of a silver antimicrobial agent (Microban® Silver). Another fabric similar to that of Example 3 is produced except that the polyethylene sheath component contains 0.3 wt. % of a copper oxide antifungal agent such as Cupron™ supplied by Cupron, Inc.. These two fabrics and a layer of the fabric of Example 3 are combined and bonded together by passing through a heated calender nip as in Example 3. The resulting composite nonwoven filtration medium exhibits broad spectrum antimicrobial properties combined with effective antifungal properties.
Many modifications and other embodiments of the inventions set forth herein will come to mind to one skilled in the art to which these inventions pertain having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Therefore, it is to be understood that the inventions are not to be limited to the specific embodiments disclosed and that modifications and other embodiments are intended to be included within the scope of the appended claims. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.
This application is related to and claims priority from U.S. Provisional Patent Application No. 60/704,062 filed Jul. 29, 2005, the contents of which are hereby incorporated by reference.