The embodiments disclosed herein relate generally to nonwoven filtration media. In preferred forms, the nonwoven filtration media comprises a low density fibrous web (e.g., less than about 0.45 g/cm3) which exhibits high dry and wet burst strength (e.g., greater than about 10 bar) and relatively small (e.g., less than about 40 μm and, in some embodiments, less than about 25 μm) mean flow pore size that is especially suitable for use as a filtration media for gases and liquids.
Spunbond nonwovens are now widely used for air filtration, such as dust collector filters, gas turbine intake air filters, powder coating filters and blasting filters, and for liquid filters such as pool and spa filters, waste-water filters, coolant filters since such applications require high dry and wet burst strength more than 10 bar. Such a high burst strength requirement can be met by the use of spunbond nonwovens as the filtration media but typically cannot be met by other types of filtration media, e.g., media formed of cellulosic fibers wet-laid nonwoven media and meltblown media.
However, spunbond media cannot meet the current requirements for high filtration efficiency and long life time. In this regard, spunbond media has an inherent limit on filtration efficiency because its fiber diameters are in the range of 15˜18 μm which are relatively thick thereby preventing conventional spunbond media from overcoming the efficiency standards of M-class filters according to the EN779:2012 standard.
In addition, conventional spunbond media have lower dust holding capacity due to point bonding in the fibrous web. Normally, spunbond media for high dry and wet burst strength applications are treated by hot point-calendering in order to ensure fiber interbonding within the web. Such point bonding causes about 20% of the entire spunbond filtration media area to be essentially “dead space” due to the fiber-to-fiber point bonds (i.e., since the spunbond media is comprised entirely of thermoplastic fibers that melt under the conditions of the point-calendering). As a result, therefore, conventional spunbond media has a lower dust holding capacity compared to other types of filtration media.
To overcome the low efficiency of conventional spunbond media, other technologies such as nanofiber coating or laminating with ePTFE membrane can be added to the spunbond media. However, these additional processing requirements necessarily increase the costs of filter media and/or lead to very short life time of filters.
Wet-laid nonwoven filter media normally possess higher filtration efficiency and dust holding capacity than the typical spunbond media. Because wet-laid nonwoven media may be formed from a wide range of possible fiber diameters by virtue of the wet-laid process, substantially finer diameter fibers, for example, 0.8 denier fiber (which has a diameter of about 9 μm), 0.3 denier fiber (which has a diameter of about 5.5 μm), and 0.06 dtex fiber (which has a diameter of about 2.6 μm) than those forming conventional spunbond media may be employed. However, the typical wet-laid nonwoven filter media are not known to be useable for those filtration applications that require high dry and wet burst strength because the dry and wet burst strength of conventional wet-laid filter media is less than 10 bar, even though wet-laid filter media can be saturated with a binder resin and/or provided with binder fibers.
It would therefore be highly desirable if fibrous wet-laid filtration media was provided which possesses a high dry and wet burst strength (i.e., greater than 10 bar) so it could be used in applications that are traditionally served by spunbond media. It is towards fulfilling such needs that the embodiments disclosed herein are directed.
The filtration media in accordance with the embodiments disclosed herein includes a area-calendered wet-laid nonwoven fibrous web which possesses a high dry and wet burst strength of greater than 10 bar, usually greater than 12 bar, for example greater than about 15 bar. The calendered wet-laid nonwoven fibrous web will also exhibit high filtration efficiency and dust holding capacity that cannot be achieved by conventional spunbond filtration media.
The embodiments disclosed herein are realized by providing a wet-laid nonwoven fibrous web comprising between about 20 to about 80 wt. %, based on the total weight of the fibrous web, of symmetrical sheath-core type bicomponent staple fibers with the balance being other synthetic staple fibers, with the nonwoven web being subject to hot area calender bonding. The presence of more than 20 wt. % sheath-core type bi-component fibers permit area bonding to be practiced so as to achieve substantially less filtration “dead space” as compared to the point-calender bonding which is typically used for spunbond media. A higher proportion of sheath-core type bi-component fibers and the homogenous dispersion of such fibers throughout the nonwoven wet-laid mat allows the filtration media of the embodiments disclosed herein to achieve at least comparable, and usually better, dry and wet burst strength than that of spunbond media which is composed of continuous filaments, even though the fibrous web of the present invention contains a mass of relatively short cut (e.g., 1-24 mm) staple fibers with no continuous filaments.
These and other attributes of the various embodiments according to the invention will be better understood by reference to the following detailed descriptions thereof.
Reference will be made to the accompanying drawings, wherein:
As used herein and in the accompanying claims, the terms below are intended to have the definitions as follows.
“Fiber” is a fibrous or filamentary structure having a high aspect ratio of length to diameter.
“Filament” denotes a fiber of extreme or indefinite length.
“Staple fiber” means a fiber which naturally possesses or has been cut or further processed to definite, relatively short, segments of definite or individual lengths.
“Fibrous” means a material that is composed predominantly of fiber and/or staple fiber.
The terms “non-woven”, “web” or “mat” refer to a collection of fibers and/or staple fibers in a mass of such fibers which are randomly interlocked, entangled and/or bound to one another so as to form a self-supporting structural element.
The terms “synthetic fiber” and/or “man-made fiber” refer to fibers made from fiber-forming substances including polymers synthesized from chemical compounds, modified or transformed natural polymer and siliceous (glass) materials. Such fibers may be produced by conventional melt-spinning, solution-spinning, solvent-spinning and like filament production techniques.
A “cellulosic fiber” is a fiber composed of or derived from cellulose.
The term “thermoplastic” means a polymeric material which becomes pliable or moldable above a specific temperature and then returns to a solid state upon cooling.
The calendered nonwoven wet-laid media of the embodiments disclosed herein may be in the form of 100% synthetic staple fibers, for example, a fibrous media comprised entirely of synthetic polymeric fibers, optionally containing other synthetic staple fibers (e.g., glass or other inorganic fibers). Thus, in preferred forms, the nonwoven media of the embodiments disclosed herein will be substantially (if not entirely) free of cellulosic or other natural staple fibers. In especially preferred forms, the calendered media of the embodiments disclosed herein will comprise a wet-laid nonwoven web consisting of 20-80% of bicomponent staple fibers with the remainder being synthetic staple fibers, preferably synthetic polymeric staple fibers.
The nonwoven fibrous web according to the embodiments disclosed herein comprises a synthetic bicomponent staple fiber. As is known per se, the bicomponent staple fibers will have been formed by extruding polymer sources from separate extruders and spun together to form a single fiber. Typically, two separate polymers are extruded, although a bicomponent fiber may encompass extrusion of the same polymeric material from separate extruders with the polymeric material in each extruder having somewhat different properties (e.g., melting points). The extruded polymers are arranged in substantially constantly positioned distinct zones across the cross-section of the bicomponent fibers and extend substantially continuously along the length of the bicomponent fibers. The configuration of bicomponent fibers employed in the practice of the embodiments disclosed herein are preferably substantially symmetric sheath-core bicomponent fibers whereby the polymeric sheath completely surrounds and envelops the polymeric core at an area ratio of sheath to core of between about 25/75 to about 75/25, typically about between about 50/50 to about 70/30.
The bicomponent staple fibers which are preferably bicomponent polyethylene terephthalate (PET) staple fibers having a lower melting point PET sheath surrounding a higher melting point PET core. In preferred forms, the bicomponent PET staple fibers will include a PET sheath having a melting point of between about 120° C. to about 190° C., typically between about 140 to 190° C., more preferably between 150° C. to about 180° C., e.g., about 165° C. (+/−3° C.), and a PET core having a melting point that is at least about 50° C., typically at least about 75° C., e.g., about 100° C. (+/−5° C.) greater than the melting point of the PET sheath. The PET core of the bicomponent staple fibers may therefore have a melting point of between about 220° C. to about 280° C., typically between about 250° C. to about 270° C., e.g., about 260° C. (+/−5° C.). One preferred bicomponent staple fiber employed in the practice of the embodiments disclosed herein is LMF50 bicomponent staple fibers commercially available from Huvis Corporation having a denier of about 4 and a length of about 6 mm. The sheath portion of the bicomponent fiber may also be comprised of other thermoplastic polymeric material, including polyalkylenes (e.g., polyethylenes, polypropylenes and the like) and polyamides (nylons, for example, nylon-6, nylon 6,6, nylon-6,12, and the like).
The bicomponent staple fibers will be present in the filtration media in an amount of 20 wt. % to about 80 wt. %, for example between about 25 wt. % to about 60 wt. %, or even about 30 wt. % to 50 wt % (+/−0.5 wt. %), based on the total weight of the fibers in the fibrous web.
The nonwoven fibrous web of the embodiments described herein will also comprise synthetic fibers which include between about 20 wt. % to about 80 wt. %, for example between about 40 wt. % to about 75 wt. %, based on total weight of fibrous web, of thermoplastic staple fibers. Preferably, the thermoplastic staple fibers will be less than about 20 μm in average diameter, for example between about 2.5 μm to about 15 μm, with lengths between about 1 mm to about 24 mm, for example, between about 3 mm to about 12 mm.
The synthetic staple fibers employed in the practice of the embodiments disclosed herein can be virtually any staple fiber formed of a thermoplastic polymeric material. Exemplary thermoplastic staple fibers therefore include polyesters (e.g., polyalkylene terephthalates such as polyethylene terephthalate (PET), polybutylene terephthalate (PBT) and the like), polyalkylenes (e.g., polyethylenes, polypropylenes and the like), poyacrylonitriles (PAN), and polyamides (nylons, for example, nylon-6, nylon 6,6, nylon-6,12, and the like). Preferred are PET fibers which exhibit good chemical and thermal resistance suitable for filtration end use applications.
In certain preferred forms, the nonwoven fibrous web will comprise a mixture of differently sized synthetic fibers. In this regard, the media may comprise a mixture of between about 20 wt. % to about 80 wt. %, based on total weight of the fibrous web, of at least one type of synthetic polymeric fibers having an average diameter of between about 2.5 μm to about 10 μm, and between about 30 wt. % to about 60 wt. %, based on total weight of the fibrous web, of a second type of synthetic polymer fibers having an average diameter of between about 10 μm to about 20 μm. The first type of synthetic fibers may have an average length of between about 1 mm to about 6 mm, while the second type of synthetic fibers may have an average length of between about 5 mm to about 24 mm.
The synthetic staple fibers employed in the wet-laid fibrous media may also include between about 5 wt. % to about 30 wt. %, typically between 10 wt. % to about 20 wt. %, based on total weight of the fibrous web, of a regenerated cellulosic fiber, preferably lyocell staple fibers. The lyocell staple fibers may have an average diameter of about 25 μm or less, typically 15 μm or less, e.g., between about 10 μm to about 15 μm. The average length of the lyocell staple fibers is typically between about 1 mm to about 8 mm, or between about 2 mm to about 6 mm, or about 3 mm to about 4 mm. Preferred lyocell fibers are commercially available from Engineered Fibers Technology, LLC of Shelton, Conn. under the tradename TENCEL® lyocell fibers which have about 1.7 denier and about 4 mm staple length.
Glass microfibers may also optionally be present in admixture with the other synthetic fibers as previously described in amounts sufficient to improve efficiency of the fibrous media as a filter. Typically, the glass microfibers, if present, will be employed in amounts of 0-20 wt. %, typically less than about 10 wt. %, based on total weight of the fibrous web. Glass microfibers having an average fiber diameter of between about 0.2 μm to about 5 μm, typically between about 0.5 μm to about 2.5 μm±about 0.1 μm, may be employed. Preferred glass microfibers for the fibrous media of the embodiments described herein may be commercially obtained as C04 glass fibers (average fiber diameter of 0.5 μm), C06 glass fibers (average fiber diameter of 0.65 μm) and C26 glass fibers (average fiber diameter of 2.6 μm) from Lauscha Fiber International of Summerville, S.C.
Additives conventionally employed in wet-laid filtration media, such as for example, wet strength additives, optical brighteners, fiber retention agents, colorants, separation aides (e.g., silicone additives and associated catalyzers), fire or flame retardants (e.g., in the form of particulates or fibers) and the like may also be present in the fibrous web. If present, these additives may be included in amounts of up to about 30 wt. %, preferably up to about 20 wt. %, for example between about 1 wt. % to about 20 wt. %, based on total weight of the fibrous web. If flame retardant fibers are incorporated into the fibrous web, the flame retardant fibers can be used between about 40 to about 80 wt %, based on the total weight of the fibrous web.
The nonwoven fibrous web described herein may be made by any conventional “wet-laid” paper-making technology. Thus, for example, predetermined amounts of the synthetic fibers and the sheath-core bicomponent staple fibers (along with any optional components, such as the glass fibers, basic thermoplastic fibers and/or additives) and water may be placed in a pulper or beater. The fibers are mixed and dispersed by the pulper or beater evenly in the water to form a slurry batch. Some mechanical work can also be performed on the fibers to affect physical parameters, such as permeability, surface properties and fiber structure. The slurry batch may thereafter be transferred to a mixing chest where additional water is added and the fibers are homogenously blended. The blended slurry may then be transferred to a machine chest where one or more slurry batches can be combined, allowing for a transfer from a batch to a continuous process. Slurry consistency is defined and maintained by agitation to assure even dispersion of fibers. In this regard, the slurry may optionally be passed through a refiner to adjust physical parameters.
The slurry is then transferred to a moving wire screen where water is removed by means of gravity and suction. As water is removed, the fibers form into a nonwoven fibrous web or sheet having characteristics determined by a number of process variables, including for example, the slurry flow rate, machine speed, and drainage parameters. The formed web may optionally be compressed while still wet so as to compact the paper and/or modify its surface characteristics. The wet fibrous web is then moved through a drying section comprised of heated rollers (or “cans” in art parlance) where most of the remaining entrained water is removed. The dried fibrous web may then have a binder resin applied by any conventional means, such as dipping, spray coating, roller (gravure) application and the like. Heat may then subsequently be applied to dry the web.
The nonwoven fibrous web may then be taken up on a roll for further processing into finished sheet or passed directly to a calendering section comprised of at least one pair, preferably a series of two pairs, of opposed calendering rolls as shown in
The calendering rolls do not point bond the nonwoven fibrous web. Instead, the calendering rolls impart substantially uniform pressure and temperature across the entire surface area of the web in the manner described hereinabove so as to evenly calender the web (i.e., area-calendering). Such hot area-calendering thereby causes a substantial (if not the entire) part of the lower melting sheath polymer of the bicomponent staple fibers in the nonwoven web to melt and thereby bond the remaining thermoplastic core component of the bicomponent staple fibers with one another and with the other synthetic staple fibers in the web.
The resulting nonwoven fibrous web may be employed as is in the form of filtration media or may be plied with additional fibrous media, for example pre-formed fibrous layers or a web formed of multiple layers in the wet-laid process. When the multiple fibrous web layers provide the filtration media, then the hot area calendered fibrous web layer of the embodiments disclosed herein is preferably positioned so as to be the outmost layer of the filtration media. By way of example, the fibrous web can be laminated to a membrane formed of expanded polytetrafluoroethylene (ePTFE) having a basis weight of, e.g., about 1 to about 50 g/m2, or a multiple-layer (e.g., two or three fibrous web layers) filtration media could be provided whereby one of such multiple layers is a hot area calendered fibrous web layer according to the embodiments disclosed herein.
The resulting hot area-calendered fibrous web will exhibit a high dry and wet burst strength of greater than 10 bar, typically greater than 12 bar, for example, greater than 15 bar. These high dry and wet burst strengths are achievable by virtue of the hot area calendering as herein described melting the sheaths of the bicomponent staple fibers through the web so as to cause the remaining core component of the bicomponent staple fibers and the synthetic staple fibers to bond one to another throughout the fibrous web.
The density of the fibrous web will typically be less than about 0.45 g/cm3, for example less than about 0.40 g/cm3.
The pore size range of the fibrous web will typically be 25 μm or less, more typically 22 μm or less, usually 20 μm or less, with the minimum pore size being typically also 25 μm or less, or more typically 22 μm or less. The mean flow pore size can be 40 μm or less, typically 35 μm or less, for example 30 μm or less and the maximum pore size being 50 μm or less, typically 45 μm or less, for example, 40 μm or less.
The filtration media is capable of being classified as an F7 filter media according to EN779:2012 standard, i.e., filtration media having an average filtration efficiency of 60-80% and a minimum filtration efficiency of at least 35% for 0.4 μm particles.
The present invention will be further illustrated by the following non-limiting examples thereof.
The following test methods were employed to obtain the data reported in the Table below.
Pore Size: Pore size (μm) was determined by the American Society of Testing and Materials (ASTM) Standard 316-03 (2011) (incorporated fully by reference herein). The minimum, maximum and mean flow pore sizes, and the number of pores of the media examples below were measured with Porometer 3G produced by Quantachrome Instruments (1900 Corporate Drive Boynton Beach, Fla. 33426 USA) with the reported pore size and pore number data being an average of two samples, one tested on each side of the media. (i.e. wire side and felt side in the case of wet-laid media).
The pore size and pore number data are measured using a technique known as capillary flow porometry. The sample is first wetted with a wetting fluid such that all the pores in the sample are filled. A nonreacting gas of increasing pressure is applied to one side of the wet sample to displace the liquid from the pores. The gas pressure and gas flowrate downstream of the sample are measured and plotted for the wet sample. After the sample is dry, the test is repeated to plot a gas flow vs. the applied pressure curve for the dry sample. Using such capillary porometry technique, the “maximum pore size”, “minimum pore size” and “mean flow pore size” can be determined.
Maximum Pore Size: The gas pressure using the capillary flow porometry technique described hereinabove at which air flow through the media is first detected (i.e. the pressure at which the bubbles first begin to flow) is used to calculate the maximum pore size.
Minimum Pore Size is determined from the pressure at which the wet flow rate curve merges with dry curve using the capillary flow porometry technique described hereinabove.
Mean Flow Pore Size is the pore diameter at which the flow through a wetted medium is 50% of the flow through the dry medium at the same pressure drop using the capillary flow porometry technique described hereinabove.
Pore Size Range is defined as the difference between the Maximum Pore Size and the Minimum Pore Size (i.e. Pore Size Range=Maximum Pore Size−Minimum Pore Size).
Caliper: The caliper (thickness) of the media was measured according to the International Organization for Standardization (ISO) Standard ISO 534(2011), “Paper and board-Determination of thickness, density and specific volume” (incorporated fully by reference herein).
Air Permeability: Air Permeability of the media was measured at 125 Pa water pressure differential, according ASTM Standard D737: Standard Test Method for Air Permeability of Textile Fabrics (incorporated fully by reference herein). The air flow through the media is reported in cubic foot per minute per square foot of sample (cfm/sf or cfm).
Burst Strength: The pressure required to rupture a media sample when either dry (“dry burst strength”) or wet (“wet burst strength”) was measured according to ISO Standard 2758 (2014), “Paper-Determination of bursting strength” (incorporated fully by reference herein). Results are reported in kilogram force per square meter at media rupture and then converted to the units of bar.
Void Ratio: The void ratio was determined by the following procedure: A 40 mm×40 mm dry test piece of the media having an initial weight (w1) was placed in a beaker with 200 cc of n-butyl alcohol and thereafter positioned in a desiccator which is evacuated until no bubbles emanating from the test piece were visibly observed. The test piece was removed from the n-butyl alcohol in the beaker and weighed immediately upon removal to obtain an initial weight (w2) and the reweighed after 30 seconds of removal to obtain a final wet weight (w3). The void ratio (%) was then calculated by the following formula: void ratio (%)=(w3−w1)/(w3−w2)×100.
Air Filter Classification: Air filtration performance was determined according to Test Standard EN779:2012, “Particulate air filters for general ventilation” (incorporated fully by reference herein). According to this standard, the performance of air filtration media is rated for nine classes of filters in three groups: coarse filters: “G1-G4”, medium filters: “M5-M6” and fine filters: “F7-F9”. The rating for M and F class filters is based on the average efficiency for 0.4 μm particles (i.e. the number fraction of 0.4 μm particles retained on the filter). F-class filters also need to meet an additional minimum efficiency criterion that the minimum efficiency is the lowest of any of the following three values: initial efficiency, discharged efficiency or efficiency throughout the test's loading procedure.
Air Filtration Performance: The air filtration performance was determined by the International Organization for Standardization (ISO) 16890, “Air filters for general ventilation” (incorporated fully by reference herein).
Pulsejet Cleanability: The cleanability of a cleanable filter media was determined by ISO 11057:2011, “Air quality—Test method for filtration characterization of cleanable filter media” (incorporated fully by reference herein).
The following materials were employed:
LMF50: 4 denier, 6 mm length (4De*6 mm) staple bicomponent low melting fibers commercially available from Huvis Corporation.
PET: Polyethylene terephthalate fibers were employed having 1.4 denier, 12 mm length (1.4De*12 mm) commercially available from Toray Industries, 0.5 denier, 5 mm length (0.5De*5 mm) commercially available from Huvis corporation, and 0.3 dtex, 5 mm (0.3Dt*5 mm) commercially available from Teijin Ltd.
The samples of Examples 1 and 2 below were produced by a wet-laid process noted above, with the sample of Example 2 having been subject to area-calendering.
Example 1: A base substrate was prepared by the method described above to form a 100% synthetic fiber wet-laid nonwoven media comprising 30 wt. % LMF50 4De*6 mm bicomponent staple fibers and a mixture of PET staple fibers consisting of 30 wt. % PET 0.5De*5 mm staple fibers (Huvis), 20 wt. % PET 1.4De*12 mm (Toray), and 20 wt. % PET 0.3dt*5 mm (Teijen). The substrate has a basis weight of 210 g/m2, a flat sheet caliper of 0.94 mm, and an air permeability of 80 cfm.
Example 2: The base substrate of media Example 1 was calendered at a calendering nip pressure of 75 kN/m and a calendering temperature of 210° C. to obtain a calendered wet-laid nonwoven media having a basis weight of 210 g/m2, a flat sheet caliper of 0.60 mm, and an air permeability of 26 cfm.
Comparative Example 1 (Kolon Finon L2270NW): The comparative media of comparative example 1 is a commercially available PET spunbond media which is conventionally used for APC (Air Pollution Control) filter media as produced by Kolon Industries (KOLON Tower, 11, Kolon-ro, Gwacheon-si, Gyeonggi-do, South Korea) having a basis weight of 277 g/m2, a caliper of 0.61 mm, and an air permeability of 25 cfm.
Comparative Example 2 (Toray FSE21602A): The comparative media of comparative example 2 is another commercially available PET spunbond media which is conventionally used for APC (Air Pollution Control) filter media as produced by Toray Advanced Materials Korea Inc. (FKI Tower 35, 36 Fl., 24 Yeoui-daero, Yeongdeungpo-gu, Seoul, South Korea) having a basis weight of 204 g/m2, a caliper of 0.48 mm, and an air permeability of 28 cfm.
The media examples described above were tested to determine pore size data (minimum, mean flow and maximum pore sizes) and to determine the number of pores. In addition each of the media examples were tested for dry and wet burst strengths. The data appear in Table 1 below.
The above data show that the inventive media (Example 2) has much smaller maximum and mean flow pore sizes as compared to those of the standard wet-laid substrate (Example 1) and the comparative spunbond media examples. The inventive media (Example 2) also exhibited a greater number of pores per unit area than either the standard wet-laid sample or a typical spunbond media. The inventive media (Example 2) possessed an increased number of pores as compared to the standard wet-laid substrate (Example 1) which is believe to be caused by the consolidation of several sub-regions near the media surface due to the pressing of the hot calendering rolls. The inventive media (Example 2) additionally possessed a much greater number of pores as compared to the typical spunbond media (Comparative Examples 1 and 2) which is believed to be the result of area bonding achieved by hot calendering of the former instead of point bonding of the fibers in the latter. The inventive media (Example 2) also exhibited a greater void ratio, indicating that the inventive media is more porous than the typical spunbond media (Comparative Examples 1 and 2).
Significantly, the inventive media (Example 2) exhibited a very tight, narrow pore-size range as compared to the other examples (see
Filtration performance tests were conducted using Palas MFP 3000 produced by Palas GmbH (Greschbachstraße 3 b 76229 Karlsruhe Germany), according to EN779: 2012 test standard. The inventive media and the comparative examples were tested without IPA discharge and with IPA discharge based on the IPA discharging method in Annex A of Test Standard EN779:2012. The data is provided in Table 2 below.
The data in Table 2 above show that the inventive media of Example 2 possessed a much higher efficiency than the typical spunbond media of Comparative Examples 1 and 2. The efficiency of Example 2 is not affected after discharging the media with IPA. This is noticeably different, when compared to the spunbond media of Comparative Examples 1 and 2. The inventive media of Example 2 included short-cut synthetic fibers which are hydrophilic (due to the oils and surfactants used in the manufacturing process, which remain on the surface of the fibers). The fibers in the spunbond media however are not oiled and thus they possess a higher static charge and a much larger efficiency drop after IPA discharge than the inventive media of the embodiments disclosed herein.
As the data in Table 2 show, the Inventive Media in accordance with an embodiment of the invention disclosed herein exhibits an overall better average efficiency in addition to markedly better initial and discharge efficiencies for 0.4 μm particles and better dust holding capacity as compared to the conventional spunbond media of Comparative Examples 1 and 2. The Inventive Media therefore rated as a F7 filter media according to EN779:2012 standard whereas the conventional spunbond filtration media of Comparative Examples 1 and 2 can only achieve a lesser rating of M5 and M6, respectively.
The inventive media of Example 2 and the comparative media of Comparative Examples 1 and 2 were also tested for pulse jet cleaning using a FilTEq GmbH tester (Amthausstr. 14, D-76227 Karlsruhe, Germany), according to ISO 11057:2011 test standard. Each test consisted of the following 4 phases:
The data of the pulse jet cleaning tests appear in Table 3 below.
The data in Table 3 above show that the inventive media advantageously had approximately 2-5 fold longer cycle time at the 30th cycle than the comparative spunbond media of Comparative Examples 1 and 2. As can be seen from
An embodiment made from flame retardant PET fibers, without any additional chemical treatment, is disclosed below.
The fibrous web was made using the same method as disclosed for Example 2 and comprised 100% PET fibers, where about 65 wt. % of the fibers were flame-retardant PET fibers commercially available from Toray Industries. The fibrous web comprised 25 wt. % RM PET 4De*6 mm fibers (Huvis), 10 wt. % PET 0.3dt*5 mm fibers (Teijin), 45 wt. % FR PET 1.4D*6 mm fibers (Toray), and 20 wt. % FR PET 3D*12 mm fibers (Toray).
The resulting fibrous filtration media is an F1 class flame retardant as tested by the DIN 53 438 standard. The physical properties appear in Table 4 below.
In the following examples (Examples A to D), the nonwoven fibrous web of the invention was plied with additional fibrous media to provide multi-layer filtration media.
Example A: A multiple layer filtration media where the hot area calendered fibrous web was laminated to a thin aluminized spunbond layer. The resulting multiple layer filtration media had very low electric resistance, below 1000 ohms.
Example B: The fibrous web was coated with PVDF nanofibers.
Examples C and D: The fibrous web was laminated with an expanded polytetrafluoroethylene (ePTFE). The resulting two layer filtration has a high filtration efficiency and can be classified as an E12 or H13 class filter media, according to EN 1822-1 test standard.
The physical properties of Examples A to D appear in Table 5.
Embodiments of the invention include i.a. the following:
While the invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not to be limited to the disclosed embodiment, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope thereof.
Filing Document | Filing Date | Country | Kind |
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PCT/FI2019/050307 | 4/16/2019 | WO | 00 |
Number | Date | Country | |
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62658419 | Apr 2018 | US |