[go: up one dir, main page]
More Web Proxy on the site http://driver.im/

CN1891325A - Nanofiber filter media - Google Patents

Nanofiber filter media Download PDF

Info

Publication number
CN1891325A
CN1891325A CN 200610004748 CN200610004748A CN1891325A CN 1891325 A CN1891325 A CN 1891325A CN 200610004748 CN200610004748 CN 200610004748 CN 200610004748 A CN200610004748 A CN 200610004748A CN 1891325 A CN1891325 A CN 1891325A
Authority
CN
China
Prior art keywords
filter medium
nanofiber
fiber
fibrillation
poly
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
CN 200610004748
Other languages
Chinese (zh)
Other versions
CN100423807C (en
Inventor
E·E·科斯洛
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
KX Technologies LLC
Original Assignee
Koslow Technologies Corp
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Koslow Technologies Corp filed Critical Koslow Technologies Corp
Publication of CN1891325A publication Critical patent/CN1891325A/en
Application granted granted Critical
Publication of CN100423807C publication Critical patent/CN100423807C/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Landscapes

  • Filtering Materials (AREA)

Abstract

The present invention is directed to an air filter medium comprising nanofibers, the filter medium having a thickness of less than 0.25 millimeters, a Figure of Merit of greater than about 0.075, and an efficiency of greater than about 99.9 % when capturing aerosol particles of about 0.18 microns in size and a pressure drop of less than about 40 millimeters water column at a flow rate of about 32 liters/minute through a sample 100 cm <2> in size. A coating of the nanofibers may also be used to enhance performance of existing filter media by increasing the FOM of the existing filter media. Preferably, the nanofibers are fibrillated.

Description

Nanofiber filter media
The application is that application number is 03803015.2 divides an application.
The application requires the priority of the U.S. Provisional Application sequence No.60/354062 of application on January 31st, 2002.
Summary of the invention
The present invention relates to filter medium, it comprises: the fibrillating fibre of Canadian Standard Freeness (CanadianStandard Freeness) less than about 45, and this filter medium has following performance indications: thickness is less than or equal to about 0.25mm and the factor of quality greater than about 0.075; With when holding back when being of a size of about 0.18 micron aerosol particle, efficient is greater than about 99.9%; And process is of a size of 100cm under the flow of about 32L/min 2Sample the time, pressure drop is less than about 40mm water column; Wherein if filter medium is thinner than 0.25mm, then when the efficient of regulating thin filter medium and pressure drop reach the thick thickness difference of 0.25mm with compensation, can provides and satisfy or above the filter medium of these performance indications.
On the other hand, the present invention relates to filter medium, it comprises: little glass fibre and Canadian Standard Freeness are less than the mixture of about 45 fibrillation Lyocell fiber, and this filter medium has following performance indications: thickness is less than or equal to about 0.25mm and the factor of quality greater than about 0.075; With when holding back when being of a size of about 0.18 micron aerosol particle, efficient is greater than about 99.9%; And process is of a size of 100cm under the flow of about 32L/min 2Sample the time, pressure drop is less than about 40mm water column; Wherein if filter medium is thinner than 0.25mm, then when the efficient of regulating thin filter medium and pressure drop reach the thick thickness difference of 0.25mm with compensation, can provides and satisfy or above the filter medium of these performance indications.
On the one hand, the present invention relates to filter medium again, it comprises; Canadian Standard Freeness is less than about 10 fibrillation Lyocell fiber, and this filter medium has following performance indications: thickness is less than or equal to about 0.25mm and the factor of quality greater than about 0.075; With when holding back when being of a size of about 0.18 micron aerosol particle, efficient greater than about 99.9% and under the flow of about 32L/min through being of a size of 100cm 2Sample the time, pressure drop is less than about 40mm water column; Wherein if filter medium is thinner than 0.25mm, then when the efficient of regulating thin filter medium and pressure drop reach the thick thickness difference of 0.25mm with compensation, can provides and satisfy or above the filter medium of these performance indications.
The present invention includes the filtration system of introducing common aforesaid filter medium.
Again on the one hand, the present invention relates to prepare the method for air filtration media, it comprises step: disperse fibrillating fibre; With form the fibrillating fibre layer of thickness less than about 0.25mm so that filter medium has following performance indications: the factor of quality is greater than about 0.075 with when holding back when being of a size of about 0.18 micron aerosol particle, and efficient is greater than about 99.9%; And process is of a size of 100cm under the flow of about 32L/min 2Sample the time, pressure drop is less than about 40mm water column; Wherein if filter medium is thinner than 0.25mm, then when the efficient of regulating thin filter medium and pressure drop reach the thick thickness difference of 0.25mm with compensation, can provides and satisfy or above the filter medium of these performance indications.
Another aspect the present invention relates to improve the method that has filtering medium property, and it comprises step: many nanofibers are provided; Wet shop nanofiber on existing filter medium, wherein nanofiber is with about 0.5g/m 2To about 11.0g/m 2Ratio load on the existing filter medium; Increase at least about 100% with the factor of quality that makes existing filter medium.Preferably in the step of the nanofiber that many fibrillation are provided, described nanofiber comprises little glass fibre, Lyocell nanofiber, acrylate/nano fiber or its combination.This method can further comprise step: solid binder is provided, wherein is layered on the existing filter medium and the activating solid binding agent with fibrillation nanofiber and solid binder are wet.
Brief description of drawings
Think that characteristics of the present invention and sub-feature of the present invention with novelty provide especially in appended claims.Accompanying drawing only is used for explanation and does not draw in proportion.But the present invention itself (in tissue and method of operating on the two) can also obtain best understanding in conjunction with the accompanying drawings with reference to the explanation to following embodiment preferred, wherein:
Fig. 1 is the chart of explanation particle interception when the air velocity through filter medium changes.
Detailed description of preferred embodiments
Definition
" binding agent " is meant and is mainly used in the material that other material is bonded together.
" Canadian Standard Freeness " or " CSF " is meant paper pulp freedom or the mass rate of emission value that the speed that may be discharged according to pulp suspension is measured.This method is that the personnel of skilled field of papermaking are known.
" DOP " is meant dioctyl phthalate (dioctyl phanthalate).Granularity is that the single DOP of dispersion drop of 0.18 micron is used to test filter medium of the present invention.
" fiber " be meant be characterised in that high length-diameter ratio for example hundreds of than one solid.Any discussion of relevant fiber comprises whisker.
" filter medium " is meant the material that carries out filtering flow.
" FOM " or " factor of quality " be meant [log (1-FE)]/Δ P wherein FE be under specific flow and for specific granularity, the interception efficient mark of filter medium.Δ P be under specific flow by the pressure reduction of filter medium, be also referred to as pressure drop or pressure drag.In this manual, the standard aerosol is through 100cm under the flow of 32L/min 2Filter area the time 0.18 micron DOP carrying.Be to be understood that, the FOM value of anisotropic medium is a constant, so that pressure drop and filter medium thickness changes in direct ratioly and log (1-FE) also changes with the thickness of medium in direct ratioly, so that for given filter medium, FOM is a constant, and is irrelevant with the thickness of final filter medium.
" fluid " is meant liquid, gas or its combination.
" shaping " is meant loose destructuring material changed into interior poly-homogeneous texture.For example, loose fibres is changed into paper.
" HEPA " filter or filter medium are meant that can remove at least 99.97% diameter is granular air cleaner or the filter medium that 0.3 micron and all bigger gas carry particulate matter.
" interception (intercept) " or " interception (interception) " be meant to intervene or stop and flow through, with realize changing, remove, deactivation or influence.
" nanofiber " is meant the fiber of diameter less than about 3.0mm.
" nonwoven " is meant net or fabric or has mutually other medium of the structure of each fiber that stacks (but not in the height systematism mode in knitting or the Woven fabric).Nonwoven web generally can be made by method well known in the art.The example of these methods includes but not limited to (only being the mode that exemplifies) melt-blown, and is spunbond, combing and air-laid.
" paper " or " paper shape " is meant flat usually fibrage or the material cushion that forms by wet laying method.
From colloid to naked eyes as seen " particle " be meant size range, and shape is not particularly limited but generally has the solid of limited length/width ratio.
" sheet material " be meant length and width significantly greater than its thickness roughly the two dimension structure.
" whisker " is meant to have limited draw ratio and a kind of long filament between the draw ratio of particle and fiber.Any discussion of relevant fiber comprises whisker.
The feature of filter medium
Granular air of the present invention (HEPA) filter medium comprises many nanofibers and binding agent, it is configured as the layer of thickness less than about 0.25mm, with when under about 20 ℃ and atmospheric pressure and under pressure drop less than about 45mm water column, air flows through 100cm with the flow of about 32L/min 2The diameter disk of filter medium the time, be that the efficient of the about 0.18 micron described layer of aerosol particle is greater than about 99.9% for diameter.Filter medium of the present invention makes can increase the filter medium amount that is incorporated in the final filter design, and this is because it is thin and collapsible, thereby improves strainability.Existing filtration system can upgrade with significantly more filter medium of the present invention, and this is because each layer is that the conventional H EPA material of 0.38-0.457mm is much thin than thickness, and has similar or improved aerosol interception function under medium pressure drop.
The air cleaner that comprises filter medium of the present invention can be used for such as at building, automobile, the occasion of the air circulation system in the especially airtight automobile, vacuum cleaner, breathing circuit filter and so on or require other occasion of filtered air.
The coating nanofiber also can be used for improving the performance that has filter medium and the factor of quality (FOM) that can provide existing filter increase greater than about 100% on the filter medium having.
But filter medium also static electrification so that the strainability of enhancing to be provided.Thereby the further processing of filter medium can be provided at the bactericidal property of microbiological interception available in the respirator is used for nuclear, biological, and chemical (NBC) defence.
Produce improved air filtration media two kinds of fundamental method are arranged.First kind is to produce to have raising " factor of quality " material (FOM), and wherein the factor of quality approximates the logarithm of particle interception divided by the pressure reduction by filter medium.Although have a variation in that FOM is conceptive, basic equation is:
FOM=[-log (1-FE)]/Δ P wherein FE be under specific flow and for specific granularity, the interception efficient mark of filter medium and Δ P are the pressure drops of also measuring under specific flow.
When the degree of depth of filter medium is an isotropism and when operating with laminar condition, for this filter medium, FOM is constant basically, and irrelevant with any variation of the basic weight of the filter medium of different samples.When more various filter medium, this is very useful instrument.For example, by applying electrostatic charge on air filtration media, or for the material that uses the nanofibres of operating down at " sliding (slip) " state, FOM is improved usually widely.
Yet, when two kinds of filter mediums have identical FOM, but one obviously people will use thin filter medium during than another thick manyfold, this is that the space almost always is popular because of in the design of filter product.When pleated filter media, the thickness of filter medium is realizing playing the part of key effect on the maximum filtering device area.If the filter paper of as many as twice can be stacked in the filter, then to compare with basic situation, the speed that air flows through filter paper reduces by half.In addition, the particle of air cleaner interception efficient flows through the decline of filter paper speed along with air and improves.This is even more important for the granule that must be diffused on the filter surfaces.Fig. 1 shows the particle interception when the air velocity through filter medium changes.After adjusted thickness, best nanometer HEPA is a HEPA material of the present invention.Provide significant advantage by adding any decline that more filter medium causes in the filter design (more fold) air to flow (this is by using the thin material possibility that becomes).Extra fold allows filtration system to have lower pressure drop and improved particle interception efficient, and this is because when playing pleat, due to it is operated under lower air mass flow.The thickness of filter medium so remote-effects filter efficiency and fold in the filter pressure drop these two pile up because its changes the best of fold.
The invention provides and have good FOM value and effective plain film filter medium as thin as a wafer.Can produce the filter medium that has with the identical FOM of modern expoxy glass filter paper, but its thickness only is the part of glass medium and has similar global stiffness and tensile property.The invention provides the air cleaner that the method for optimizing preparation folds.
Nanofiber
Filter medium of the present invention is made up of nanofiber, described nanofiber can be the organic or inorganic material, comprising but be not limited to polymer, engineering resin, pottery, cellulose, artificial silk, glass, metal, activated alumina, carbon or active carbon, silica, zeolite or its combination.The combination of organic and inorfil and/or whisker can be considered and, for example glass, pottery or metallic fiber and polymer fiber can be used together in scope illiteracy of the present invention.
When by wet laying method, when producing filter medium by cellulosic nanofiber or polymer fiber, the Canadian Standard Freeness of this fiber also should be less than or equal to 45 and can be less than or equal to about 2.Preferably, significantly the diameter of the fiber of ratio should be less than or equal to about 1000 nanometers, is more preferably less than or equals the fiber that about 400 nanometers and most preferred diameters are less than or equal to about 200 nanometers.The length of preferred cut staple to about 1mm to about 8mm, preferably about 2mm is about 6mm and 3mm about 4mm extremely more preferably from about extremely.Fibrillating fibre most preferably, this is because their especially little sizes and potential low cost.
Preferably, the fibrillation synthetic cellulose or the acrylic fiber of processing can produce ultrafiltration medium of the present invention according to the present invention.Can prepare this fibrillating fibre cellulose fiber by direct dissolving and spinning wood pulp in organic solvent such as amine oxide, and be called as the Lyocell fiber.The advantage of Lyocell fiber is to produce in the mode of consistent and uniform, thereby produces repeatably result, and situation may be not like this for native cellulose fibre for example for this.In addition, the fibril of Lyocell usually curls.The fiber that curling provides a large amount of twines, thereby causes having the final filter medium of high dry strength and significantly residual wet strength.In addition, can use the equipment production fibrillation in large quantities Lyocell fiber of medium cost of investment.Be appreciated that the fiber except cellulose can be by fibrillation to produce superfine fibril, as artificial fiber, especially acrylic acid or nylon fiber or other cellulosic material.
Can use the combination of fibrillation and nonfibrillated fiber in the present invention.For example, little glass fibre can mix with the fibrillation polymer fiber, with cost and the aid dispersion that reduces whole fibre blends, keeps the performance of gained simultaneously.Preferably, the diameter of little glass fibre is about 0.25 micron to about 1 micron and preferred about 0.5 micron to about 0.75 micron and more preferably from about 0.65 micron.The amount of little glass fibre can be maximum about 90% of filter medium weight.
The most preferred embodiment comprises the Lyocell nanofiber of average diameter less than the fibrillation of the chopped strand length of about 200 nanometers and about 3 to about 5mm.Fibrillation Lyocell fiber can mix with the cheap little glass fibre of a part, reducing cost, but still keeps required efficient under acceptable pressure drop.
Strengthen the mechanical strength of filter medium
Can be by flowing at not obvious obstruction air through forming the mechanical strength that filter medium improves filter medium on the supporting layer of filter medium.Supporting layer can be any ventilative matrix, and condition is that the aperture of supporting layer is not pulled by ventilative matrix to nanofiber under vacuum pressure greatly.Supporting layer can be the material by fabric, nonwoven, spunbond, melt-blown, cellulose and the preparation of other fibrous material.The example of this matrix is spunbond polyester, as available from OldHickory, and the BBA Nonwovens Reemay of Tennessee, the REEMAY of Inc TM2004 or REEMAY TM2275.Supporting layer also can be processed or by the material preparation of anti-mildew, mould, fungi or bacterium.
The another way of giving the filter medium mechanical strength is to mix a part of binding agent and nanofiber.Known in this field, add the wet strength that epoxy, acrylic acid or other resin can provide enhancing in the paper technology, but the resin of these aqueous dispersions usually causes lower permeability at the final products Gu, especially when fiber size descends.Although these resins and resin system can use in the present invention, preferably use the thermoplasticity or the thermosets of powder known in the art, particle or fibers form.Select binding agent, so that the fusing point of binder material fully is lower than the fusing point of nanofiber, but so that the heating and filtering medium activates binding agent, filter medium can not melt and and then forfeiture porosity simultaneously.Binding agent preferably is distributed on the whole filter medium full and uniformly, so that subsequently when when activation, binding agent will be held back or be bonded to basically on all nanofibers.
Available binder material includes but not limited to polyolefin, polyvinylhalide, polyvinyl ester, polyvinylether, the polyvinyl sulfuric acid ester, polyethylene phosphate, polyvinylamine, polyamide, polyimides , polyoxadiazole, polytriazoles, polycarbodiimide, polysulfones, Merlon, polyethers, poly (arylene ether) oxygen, polyester, polyacrylate, phenolic resins, melamine-formaldehyde resin, formaldehyde-urea, ethyl-vinyl acetate co-polymer, its copolymer and block copolymer and its combination.The variant of above material and other useful polymer comprises group such as hydroxyl, halogen, low alkyl group, lower alkoxy, the replacement of monocycle shape aryl and analog.Other potential available material comprises polymer such as polystyrene and acrylonitritrile-styrene resin, SB and other amorphous or amorphous polymer and structure.
Can be used for more itemizing of binder material of the present invention and comprise polyalkenes, polyethers, polyvinyl ester, polyvinylether, ethyl-vinyl acetate co-polymer, the end-blocking polyacetals, as polyformaldehyde, poly-(trichloroacetaldehyde), poly-(valeraldehyde), poly-(acetaldehyde) and poly-(propionic aldehyde) etc.; Acrylate copolymer such as polyacrylamide, poly-(acrylic acid), poly-(methacrylic acid), poly-(ethyl acrylate) and poly-(methyl methacrylate) etc.; Fluorocarbon polymer, as poly-(tetrafluoroethene), perfluorinate ethylene-propylene copolymer, ethylene-tetrafluoroethylene copolymer, poly-(chlorotrifluoroethylene), ethylene-chlorotrifluoro-ethylene copolymer, poly-(vinylidene fluoride) and poly-(PVF) etc.; Polyamide is as poly-(6-aminocaprolc acid) or poly-(ε-own from acid amides), poly-(hexylidene adipamide), poly-(hexylidene decanedioyl amine) and poly-(11-aminoundecanoic acid) etc.; Nomex is as poly-(imino group-1, the different phthalyl of 3-phenylene imino group) or poly-(-the different phthalic amide of phenylene) etc.; Parylene is as poly--right-xylylene and poly-(chloro-right-xylylene) etc.; Polyaryl ether is as poly-(oxygen base-2,6-dimethyl-1,4-phenylene) or poly-(p-phenylene) etc.; Polyarylsufone, as poly-(Oxy-1,4-phenylene sulfonyl-1,4-phenylene Oxy-1,4-phenylene isopropylidene-1,4-phenylene) and gather (sulfonyl-1,4-phenylene Oxy-1,4-phenylene sulfonyl-4,4 '-biphenylene) etc.; Merlon is as poly-(bisphenol-A) or poly-(carbonylic dioxo base-1,4-phenylene isopropylidene-1,4-phenylene) etc.; Polyester, as poly-(PETP), poly-(butylene terephthalate), poly-(cyclohexylidene-1,4-dimethylene terephthalate) or poly-(formaldehyde-1,4-cyclohexylene methylene oxygen base paraphenylene terephthalamide) etc.; Poly-aromatic yl sulfide is as poly-(to diphenyl sulfide) or poly-(sulfo--1,4-phenylene) etc.; Polyimides is as poly-(all benzene four imino groups-1,4-phenylene) etc.; Polyolefin, as polyethylene, polypropylene, poly-(1-butylene), poly-(2-butylene), poly-(1-amylene), poly-(2-amylene), poly-(3-Methyl-1-pentene) and poly-(4-methyl-1-pentene) etc.; Polyvinyl, as poly-(vinylacetate), poly-(vinylidene chloride) and poly-(vinyl chloride) etc.; Diene polymer, as 1,2-gathers-1,3-butadiene, and 1,4-gathers-1,3-butadiene, polyisoprene and polychlorobutadiene etc.; Polystyrene; Aforesaid copolymer is as acrylonitrile-butadiene-styrene (ABS) (ABS) copolymer etc. and composition thereof.
Can use a series of binder fibers, comprising polyethylene, polypropylene, acrylic acid or polyester-polypropylene or polypropylene-polyethylene bicomponent fibres or other.Preferred fiber binder material can comprise FYBREL  synthetic fibers and/or SHORT STUFF  EST-8, and these two all is polyolefin-based materials.FYBREL  is a kind of polyolefin-based synthetic paper-pulp, and it is a kind of fiber of height fibrillation and the Mitsui Chemical Company that is available commercially from Japan.FYBREL  has good hot-die plasticity and provides smooth surface to filter medium.SHORT STUFF  EST-8 is available commercially from MiniFibers, Inc., Pittsburgh, Pennsylvania and be a kind of high density polyethylene (HDPE) of height fibrillation.Same preferred low density polyethylene (LDPE) (LDPE) adhesive particle, as by Tuscola, the Equistar Chemicals of Illinois, the MICROTHENE  Grade FN 510 of L.P. preparation.Polyvinyl acetate (PVA) also can be used as binding agent.Preferred PVA is available commercially from Kuraray Company, Ltd., Osaka, the KURALON of Japan TMVPB071.
Preferably, the consumption of binding agent is about 1% to about 35% weight, and more preferably from about 3% to about 10%, most preferably from about 5% to about 7%.
Additive
One or more additives of particle, fiber, whisker or powder type also can mix with nanofiber, tackle other pollutant or remove moisture and/or stink helping.Useful additive can include but not limited to metallic particles, activated alumina, active carbon; silica, polymer powder and fiber, glass beads or fiber; cellulose fibre, ion exchange resin, engineering resin; pottery, zeolite, diatomite; activated bauxite, bleaching earth, calcium sulfate; super-absorbent polymer (SAP), or its combination.Also can be according to the application-specific chemical treatment additive, to give antimicrobial or sterilizing ability.These additives are preferred, and uncrossed basically q.s exists so that the air in use in the gained filter medium flows.The amount of additive depends on the specific function of filtration system.
The method for preparing HEPA filter medium of the present invention
Can prepare HEPA filter medium of the present invention according to the procedure known to those skilled in the art.Do shop technology and comprises spunbond, electrostatic spinning, island spinning (spinningislands-in-sea) technology, fibrillating film, melt-blown and other known dried shop technology of those skilled in the art.The dried shop technology that exemplifies begins with chopped strand, and described chopped strand can separate by being carded to single fiber, is layered on one by Pneumatic method then and plays desired thickness, forms unbonded fibre sheet material.Then this non-binder fibre is carried out water-jet, make fiber fibrillation and waterpower twine (hydroentangle).Can on some plastic foils, carry out similar technology, when described plastic foil is exposed to high-pressure water jet, change into the fibrillating fibre net.
In preferred wet lay-up technique, fibre bundle is cut into particular length, control and especially in about 3mm about 4mm scope district extremely to about 8mm scope at about 1mm usually.In having the equipment that is similar to the blender feature, or on fairly large, often be called in the machine of " hi-low ", " beater " or " refiner " the fibrillation chopped strand.Make fiber experience stress repeatedly, further cut off and make simultaneously the decline minimum of fibre length.When fiber experienced these stress, owing to cause the fiber splitting a little less than the active force between the amorphous and crystal region, and Canadian Standard Freeness (CSF) began to descend, and wherein said Canadian Standard Freeness is measured by means commonly known in the art.But the compartment of terrain is taken out the gained pulp sample and CSF be can be used as the indirect measurement of original fiber degree.Although the CSF value is sensitive to fibre length slightly, its stronger original fiber degree that is sensitive to fiber.Therefore, CSF is the suitable method of monitoring fiber original fiber degree, and CSF is measuring of the easy degree that dewaters from paper pulp.If surface area is very high, then considerably less water is discharged from paper pulp and along with fiber fibrillation more in depth, CSF value general is step-down gradually under the time of specified rate.The fibrillating fibre of given CSF value can be directly used in to be produced paper or goes up dehydration at various equipment (comprising dehydrating press or driving-belt), produces dehydration paper pulp.The paper pulp that dewatered can be used to prepare wet shop paper subsequently.Usually, for application of the present invention, use CSF to be lower than 45 paper pulp and preferred CSF and should be less than or equal to about 2.Fiber can directly be sent in the pulp preparation system, is suitable for the batching of papermaking with production.The final weight of filter medium preferably about 21 is to about 65g/m 2, preferred about 32 to about 48g/m 2, based on the gross weight of filter medium.The fiber of fibrillation comprises paracrystalline acrylic acid, nylon or other synthetic fibers of Lyocell and selection different brackets in this way.
Can be before or after forming wet shop or doing the shop paper, according to methods known in the art, Corona discharge Treatment or chemical treatment as nanofiber make the filter medium static electrification.Also can in the mixture of the mixture of nanofibers of fiber such as acrylic acid and nylon fiber, produce electrostatic charge by triboelectric effect.Electrostatic charge can provide the particulate interception of enhancing by electronic interception.
The wet lay-up technique that exemplifies is included in that to disperse CSF in the blender under mixing in water be about 2 fibrillation Lyocell fibre pulp, forms to have about 1% batching to about 2% denseness.Can in this dispersion liquid, add other fiber and binding agent or composition.After this, can in the production of wet shop filter medium, directly use the complete mixture of each composition.
Use nanofiber coating to improve the FOM of existing filter medium
In another embodiment of the present invention, show that local coating nanofiber can improve the FOM of existing filter medium at least about 100% on the filter medium as having in matrix.Use wet lay-up technique, with about 0.5g/m 2To about 11.0g/m 2And preferably about 1.08g/m 2Speed with nano-fibre supported on existing filter medium.The nanofiber strong adhesion can use nanofiber by serving as main binder other fiber or composition to be sticked on the matrix on matrix too.The conventional binder material of solid form can be used for improving the adhesion to matrix, but this is not necessarily in all occasions.
Preferably, acrylate/nano fiber or fibrillation Lyocell fiber (separately and with the combination of little glass fibre) significantly improve the FOM of existing filter medium.Can in the initial production process of filter medium, apply nanofiber or under the given nominal cost of required a small amount of nanofiber, produce after be coated with thereon.Can use Canadian Standard Freeness less than about 45, preferably less than about 10 and preferred about 2 and chopped strand length for about 3mm extremely about 8mm the acrylate/nano fiber.According to this acrylic fiber of methods known in the art fibrillation.Can be with trade names RES-25 from Sterling Fibers, Inc., Pace, Florida, with trade name CASHMILON TMFrom AsahiKasei Corporation, Tokyo Japan and/or from Mitsubishi RayonAmerica, but New York obtains preferred acrylic acid chopped strand with the fibrillation chopped strand form of 3mm length.
Exemplifying in the processing of the existing air filtration media that adopts nanofiber coating, the cut staple tow arrives about 3 to about 4mm length and fibrillation as mentioned above.The nanofiber of the shop fibrillation that wets on the sheet material of existing filter medium or other support matrix then is comprising little glass fibre (if words of using).
Embodiment
Following examples explanation the present invention is provided, and should not be construed as limiting the scope of the invention.
Use is available from Air Techniques, International of Owings Mill, and the Model TDA-100 of Maryland carries out aerosol interception and gas-flow resistance measurement.In this research, use monodispersed 0.18 micron oil gas sol particle.Flow is 32slpm.Utilize Tinius Olsen Testing Machine Company, Inc.of Horsham, hot strength is measured at the mechanical test station of Pennsylvania.The thickness of HEPA filter medium or the nanofiber coating on supporting layer as follows is not considered the thickness of any support matrix.
The hand sheet (handsheet) for preparing HEPA filter medium of the present invention according to following general step.Take by weighing material and in stainless steel Wei Lin Shi blender with 2.0L deionized water blend at least 3 minutes.When using little glass fibre, with nanofiber and binding agent (if the words that exist) mixes before blend independently they about 3 minutes.Be poured over 30.5 * 30.5cm at fibre blend 2Stainless steel FORMAX TMIn the papermaking frame (deckle), be used in the REEMAY that tiles on the basic screen cloth of 100 purposes TM2004 nonwoven fabric sheets are as supporting layer.Fill described frame to total total about 12L water that contains different fibers.Use and have the 30.5 * 30.5cm of 60 diameters as the hole of 2cm 2Stainless steel agitator sheet spins upside down fibre blend about 8-10 time from the top to the bottom.From fibre blend, remove and anhydrate by below frame, applying slight underpressure, cause that fiber is at REEMAY TMForm on the nonwoven.In case big water gaging is removed, and then adopts vavuum pump to replenish dehydration, to remove extra excessive moisture and to produce relative smooth, smooth, very thin paper shape sheet material.Resulting sheet separated from screen cloth and on top and bottom be stained with suctions (blotter) sheet material and make up.Roll roller roll-in combined sheet with the 2.27kg marble lightly, to remove excessive water and to make the top surface of sheet material level and smooth.Then this sheet material being placed on two fresh and dry being stained with inhales between the sheet material and had been placed under about 120 ℃ on the FORMAX  sheet drying device about 10 to about 15 minutes.With the filter medium of drying be stained with inhale sheet separation and on FORMAX  sheet drying device direct about 5 minutes of each side of heating, any binding agent that exists with activation.
Nanofiber is coated among the embodiment on filter medium or other the coarse matrix therein, with the filter medium or matrix rather than the REEMAY that select TMNonwoven is done substrate and wet as previously mentioned shop nanofiber thereon to frame.
Embodiment 1 and 2: HEPA filter medium with fibrillation Lyocell and little glass nano-fibre
These embodiment illustrated with Canadian Standard Freeness be about 8 fibrillation Lyocell nanofiber with aqueous dispersion that little glass fibre mixes in the performance of the HEPA filter medium for preparing, the fibre diameter of wherein said little glass fibre is 0.65 micron, with trade names FIBREGLASS TM#106 is available from Johns Manville Company of Denver, Colorado.Table I and II show the composition and the feature of filter medium.
Table I
Embodiment number Lyocell(wt%) Sheet material weight (g) Thickness (mm) Efficient (%) ΔP (mmH 2O) Hot strength (@50in/min)
Power (kg/ft) Elongation (mm)
1 30 2.8 0.2159 99.963 29.8 1.110 2.340
2 25 4.5 0.2921 100 48.9 1.150 1.930
Embodiment 3-7: HEPA filter medium with fibrillation Lyocell and little glass nano-fibre
To adopt Canadian Standard Freeness be about 2 fibrillation Lyocell nanofiber with FIBREGLASS TMPreparation embodiment 3-7 in the aqueous dispersion that the little glass fibre of #106 mixes.In these and following embodiment, will be available commercially from Kuraray Company, Ltd., Osaka, the KURALON of Japan TMPolyvinyl acetate (PVA) is as binding agent.Embodiment 3 comprises that further MICROTHENE  Grade FN510 is as binding agent.MICROTHENE  contains the unbodied precipitated silica of 0.5wt%.Table II shows composition.Table III shows the feature of filter medium.
Table II
Embodiment number Lyocell(wt%) Glass (wt%) PVA(wt%) FN510(wt%)
3 5 85 7.5 7.5
4 2.5 90 7.5 -
5 2.5 92.5 5 -
6 2 95 3 -
7 2 95 3 -
Table III
Embodiment number Lyocell(wt%) Sheet material weight (g/ft 2) Thickness (mm) Efficient (%) ΔP (mmH 2O) Hot strength (@50in/min)
Power (kg/ft) Elongation (mm)
3 5 4.0 0.2413 99.969 36.7 1.170 1.025
4 2.5 4.5 0.2540 99.966 35.57 2.938 1.943
5 2.5 4.5 0.2794 99.975 32.20 1.938 1.469
6 2 4.5 0.2794 99.979 30.40 1.608 1.227
7 2 4.5 0.2540 99.9945 33.57 1.073 0.973
The HEPA filter medium of embodiment 1-7 thickness significantly less than conventional H EPA material under, in holding back 0.18 micron aerosol particle, demonstrate good efficient.
Embodiment 8-20: have CSF and be 2 the fibrillation Lyocell and the HEPA filter medium of little glass nano-fibre
These embodiment further show not to be had binding agent and is having under the situation of the different amounts binding agent shown in the following table, uses the performance of the HEPA filter medium of the present invention of the little glass fibre preparation of fibrillation Lyocell nanofiber and FIBREGLASS #106.Employed binding agent is PVA and the MICROTHENE  Grade FN-510 that contains the unbodied precipitated silica of 0.5wt%, based on the gross weight of MICROTHENE  and silica.
Table IV
Embodiment number Lyocell(wt%) Glass (wt%) PVA(wt%) FN510(wt%)
8 2.5 90 7.5 -
9 2.5 92.5 5 -
10 2.5 90 7.5 -
11 10 65 - 25
12 10 75 - 15
13 10 80 - 10
14 7.5 85 - 7.5
15 5 80 7.5 7.5
16 2.5 90 7.5 -
17 2.5 92.5 5 -
18 2.5 95 2.5 -
19 2 95 3 -
20 30 70 - -
Table V
Embodiment number Sheet material weight (g/ft 2) Thickness (mm) Efficient (%) ΔP (mmH 2O) Hot strength (@50in/min)
Power (kg/ft) Elongation (mm)
8 4.5 0.2413 99.9988 34.30 0.143 1.210
9 4.5 0.2413 99.9983 35.00 0.562 1.625
10 4.23 0.2413 99.9906 37.00 0.3195 0.835
11 5.0 0.2667 99.9945 37.30 0.4770 1.150
12 5.0 0.3302 99.9994 37.60 0.298 1.278
13 5.0 0.3175 99.9996 37.00 0.398 1.645
14 5.0 0.3302 99.9998 38.40 0.2795 1.442
15 4.0 0.2159 99.9810 27.30 0.208 1.310
16 4.0 0.2540 99.9880 29.40 0.251 0.978
17 4.0 0.2413 99.9929 32.80 0.211 0.733
18 4.0 0.2540 99.9870 32.00 0.252 0.735
19 4.0 0.2540 99.9850 33.80 0.446 0.883
20 3.0 0.1397 99.938 27.50 0.727 1.795
All embodiment show and are holding back 0.18 micron excellent efficiency in the aerosol particle, therefore will surpass the performance of the HEPA material of routine.
Embodiment 21-35: have CSF and be 2 the fibrillation Lyocell and the HEPA filter medium of little glass nano-fibre and different amount PVA binding agents
These embodiment have illustrated when the different performance of measuring the HEPA filter medium of PVA adhesive preparation with difference.Composition and Table VII that Table VI shows filter medium show results of property.
Table VI
Embodiment number Lyocell(wt%) Glass (wt%) PVA(wt%)
21 2.5 90 7.5
22 2.5 90 7.5
23 2.5 92.5 5
24 2.5 92.5 5
25 2.5 95 2.5
26 2.5 95 2.5
27 2 95 3
28 2 95 3
29 2.5 90 7.5
30 2.5 92.5 5
31 2.5 95 2.5
32 2 95 3
33 29 70 1
34 29 70 1
35 28.5 70 1.5
Table VII
Embodiment number Sheet material weight (g/ft 2) Thickness (mm) Efficient (%) ΔP (mmH 2O) Hot strength (@50in/min)
Power (kg/ft) Elongation (mm)
21 4.0 0.3302 99.9270 31.40 0.896 0.868
22 4.0 0.2159 99.9958 29.60 0.176 0.980
23 4.0 0.3429 99.970 32.85 1.043 1.208
24 4.0 0.2159 99.9976 32.00 0.234 1.195
25 4.0 0.2540 99.9900 32.20 0.407 0.628
26 4.0 0.3175 99.9860 32.50 0.876 1.173
27 4.0 0.3048 99.9903 34.90 0.322 0.705
28 4.0 0.2159 99.9961 34.85 0.547 1.730
29 4.5 0.3683 99.9710 36.45 1.561 1.300
30 4.5 0.3810 99.9870 33.25 1.402 1.453
31 4.5 0.3429 99.9956 36.10 0.441 0.778
32 4.5 0.4064 99.9956 37.60 1.011 1.055
33 3.0 0.1778 99.9805 35.63 0.8705 1.158
34 3.0 0.1651 99.9880 35.23 0.629 1.083
35 3.0 0.1829 99.9880 35.23 0.793 1.203
Embodiment in the Table VII shows interception efficient good to 0.18 micron aerosol particle under medium pressure drop.
Embodiment 36-38: have CSF and be folding (pleated) and the comparison of non-inverted pleat (unpleated) HEPA filter medium of 2 fibrillation Lyocell and little glass nano-fibre and different amount PVA binding agents
These embodiment have illustrated that HEPA filter medium of the present invention keeps its initial non-performance that folds when pleat folds (representing with alphabetical P) in Table I X.The use Canadian Standard Freeness is 2 Lyocell nanofiber in the preparation filter medium.The binding agent of PVA for using.
Table VIII
Embodiment number Lyocell(wt%) Glass (wt%) PVA(wt%)
36 29.5 70 0.5
37 30 70 -
38 25 70 5
Table I X
Embodiment number Sheet material weight (g/ft 2) Thickness (mm) Efficient (%) ΔP (mmH 2O) Hot strength (@50in/min)
Power (kg/ft) Elongation (mm)
36 3.0 0.1651 99.985 34.95 0.741 1.053
36P 99.985 34.90
37 3.0 0.1651 99.990 36.05 0.756 1.168
37P 99.988 35.3
38 3.0 0.1651 99.988 33.20 0.704 1.965
38P 99.988 33.40
Embodiment 39-66: have CSF and be 2 the fibrillation Lyocell and the HEPA filter medium of little glass nano-fibre and different amount EST-8 binding agents
These embodiment have illustrated the different performance of HEPA filter medium when different amount EST-8 polyethylene fibres are used as binding agent.
Table X
Embodiment number Lyocell (wt%) EST-8 (wt%) Glass (wt%) Embodiment number Lyocell (wt%) EST-8 (wt%) Glass (wt%)
39 10 15 75 53 10 15 75
40 10 10 80 54 10 10 80
41 15 15 70 55 15 15 70
42 5 25 70 56 5 25 70
43 10 20 70 57 10 20 70
44 10 25 65 58 10 25 65
45 15 25 60 59 15 25 60
46 25 15 60 60 25 15 60
47 20 20 60 61 20 20 60
48 20 20 60 62 20 20 60
49 20 20 60 63 20 20 60
50 10 30 60 64 10 30 60
51 30 10 60 65 30 10 60
52 30 10 60 66 30 10 60
Table X I
Embodiment number Sheet material weight (g/ft 2) Thickness (mm) Efficient (%) ΔP (mmH 2O) Hot strength (@50in/min)
Power (kg/ft) Elongation (mm)
39 4.0 0.2667 99.9934 38.40 0.713 1.905
40 4.0 0.2540 99.9972 38.15 0.587 1.430
41 3.5 0.2286 99.9710 32.80 1.010 1.993
42 3.5 0.2032 99.9640 31.20 0.461 1.265
43 3.5 0.1905 99.9710 33.05 0.674 1.803
44 3.5 0.2032 99.9380 32.55 0.926 2.268
45 4.0 0.2032 99.9600 36.60 1.073 2.000
46 3.0 0.1778 99.890 32.60 1.041 1.745
47 3.5 0.2159 99.9630 38.25 1.136 1.740
48 3.0 0.1778 99.880 32.30 1.363 2.070
49 3.25 0.1829 99.890 32.90 1.427 2.216
50 3.5 0.2032 99.880 30.50 0.642 1.598
51 3.25 0.1829 99.964 39.05 1.394 2.055
52 3.0 0.1829 99.944 36.65 1.319 2.090
53 4.0 0.2667 99.9934 38.4 0.713 1.905
54 4.0 0.2540 99.9972 38.15 0.587 1.430
55 3.5 0.2286 99.971 32.80 1.010 1.993
56 3.5 0.2032 99.964 31.2 0.461 1.265
57 3.5 0.1905 99.971 33.05 0.674 1.803
58 3.5 0.2032 99.938 32.55 0.926 2.268
59 4.0 0.2032 99.960 36.60 1.073 2.000
60 3.0 0.1778 99.890 32.60 1.041 1.745
61 3.5 0.2159 99.963 38.25 1.136 1.740
62 3.0 0.1778 99.880 32.3 1.363 2.070
63 3.25 0.1829 99.890 32.90 1.427 2.216
64 3.5 0.2032 99.880 30.5 0.642 1.598
65 3.25 0.1829 99.964 39.05 1.394 2.055
66 3.0 0.1829 99.944 36.65 1.319 2.090
Embodiment 67-71: have CSF and be folding and the comparison of the non-HEPA of folding filter medium of 2 fibrillation Lyocell and little glass nano-fibre and different amount EST-8 binding agents
Following embodiment relatively uses 30wt%Lyocell nanofiber, 60wt% glass microfiber (FIBREGLASS #106) and 10wt%EST-8 folding and the performance of the non-HEPA of folding filter medium as adhesive preparation.
Table X II
Embodiment number Sheet material weight (g/ft 2) Thickness (mm) Efficient (%) ΔP (mmH 2O) Hot strength (@50in/min)
Power (kg/ft) Elongation (mm)
67 3.25 0.1905 99.960 39.45 1.254 1.655
67P 99.963 39.00
68 3.0 0.1651 99.959 38.45 1.348 2.375
68P 99.959 38.70
69 3.25 0.1905 99.960 39.5 1.254 1.655
69P 99.963 39.00
70 3.25 0.1905 99.967 39.65 1.282 1.521
70P 99.971 41.00
71 3.0 0.1651 99.959 38.45 1.348 2.375
71P 99.959 38.65
Equally, the filter that folds demonstrates and the substantially the same performance characteristic of the non-filter that folds.All all have the good interdiction capability to submicron particles, because the efficient of test described herein is to adopt 0.18 micron aerosol particle to carry out.Hot strength also is best for pleating.The advantage that obtains in interception efficient has remedied higher slightly resistance.
Embodiment 72-74: the improvement of FOM with existing filter medium of nanofiber coating
Following embodiment has illustrated the increase of FOM, and and then explanation load 0.15g/ft 2The increase of the strainability of the existing filter medium of (dry weight) nanofiber.Adopt 0.18 micron aerosol particle, with the flow of 32slpm at 100cm 2Jig (jig) on carry out all measurements.Represent that with FM initial filter medium also defines with its aerosol infiltration mark, gas-flow resistance and FOM.FM1 and FM2 are nonwoven.In embodiment 72, use above-described wet lay-up technique, with 25% Canadian Standard Freeness about 2 acrylate/nano fiber and the little glass fibre coating of 75%FIBREGLASS#106 inceptive filtering medium FM1.Acrylic fiber among the embodiment 72 is available from Mitsuibishi Rayon America.In embodiment 73, be the little glass fibre coating of about 2 Lyocell fiber and 75%FIBREGLASS #106 inceptive filtering medium with 25% Canadian Standard Freeness.In embodiment 74, be about 2 fibrillation Lyocell nanofiber coating inceptive filtering medium FM1 with 25% Canadian Standard Freeness.In embodiment 75, with being coated with inceptive filtering medium FM2 available from 100% acrylate/nano fiber equally in Mitsuibishi Rayon America.Can find out according to Table VIII, in existing filter medium, add a small amount of nanofiber and significantly improve FOM, and then improve the performance of filter medium.
Table X III
Embodiment number The infiltration mark ΔP(mmH 2O) FOM The improvement of FOM
FM1 0.953 0.5 0.0397
72 0.592 2.7 0.0843 112%
73 0.636 1.95 0.1008 154%
74 0.472 2.25 0.1449 265%
FM2 0.950 0.1 0.2328
75 0.736 0.2 0.6656 186%
Embodiment 76-79: the improvement of FOM with engine filter paper of nanofiber coating
Following embodiment has illustrated the increase of FOM, and and then explanation load 1.6g/m 2The increase of the strainability of the existing filter medium of (dry weight) nanofiber.Inceptive filtering medium (being expressed as FM3) is the bonding cellulose filter medium of normal resin that uses in the air intake filter device of the automobile engine of standard.Adopt 0.18 micron aerosol particle with the flow of 32slpm at 100cm 2Jig in the test permeability.Embodiment 76 usefulness Canadian Standard Freenesses are about 2 fibrillation Lyocell nanofiber coating.The little glass fibre coating of the about 25% fibrillation Lyocell nanofiber of embodiment 77 and 78 usefulness and about 75%FIBREGLASS #106.About 25% Canadian Standard Freeness of embodiment 79 usefulness is about 2 acrylate/nano fiber and the little glass fibre coating of about 75%FIBREGLASS #106.Embodiment 79 uses the length that changes into 3mm available from acrylate/nano fiber and fibril in Mitusibishi Rayon America.As shown in Table IX, under the situation of adding coating a small amount of nanofiber thereon, obtain the remarkable improvement of FOM.For filter cheaply, this nanofiber in a small amount is the economized form that improves filter capability.
Table X IV
Embodiment number The infiltration mark ΔP(mmH 2O) FOM The improvement of FOM
FM3 0.906 4.1 0.0105
76 0.525 11.9 0.0235 124%
77 0.420 8.25 0.0457 335%
78 0.742 7.85 0.0476 353%
79 0.405 8.2 0.0478 355%
Although specifically described the present invention in conjunction with certain preferred embodiment, obviously according to above describing, many replacements, modifications and variations are conspicuous to those skilled in the art.Therefore think that appended claims comprises that any of these that falls in true scope of the present invention and the purport is replaced, modifications and variations.

Claims (3)

1. one kind is improved the method that has filtering medium property, and it comprises the steps:
Many fibrillation nanofibers are provided;
Wet shop or coating are from the fibrillation nanofiber of fluid suspension on existing filter medium, and wherein the fibrillation nanofiber is with about 0.5g/m 2To about 11.0g/m 2Ratio load on the existing filter medium; With
The factor of quality of existing filter medium is increased at least about 100%.
2. the process of claim 1 wherein that in the step that many fibrillation nanofibers are provided described nanofiber comprises Lyocell nanofiber, acrylate/nano fiber, nylon nano fiber or its combination and further comprises little glass fibre.
3. the method for claim 1 further comprises the step that binding agent is provided, and wherein will or be coated on the existing filter medium from the fibrillation nanofiber of fluid suspension and the wet shop of binding agent.
CNB2006100047484A 2002-01-31 2003-01-18 Nanofiber filter media Expired - Lifetime CN100423807C (en)

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
US35406202P 2002-01-31 2002-01-31
US60/354,062 2002-01-31
US10/341,186 2003-01-13

Related Parent Applications (1)

Application Number Title Priority Date Filing Date
CNB038030152A Division CN1279997C (en) 2002-01-31 2003-01-18 Nanofiber filter media

Publications (2)

Publication Number Publication Date
CN1891325A true CN1891325A (en) 2007-01-10
CN100423807C CN100423807C (en) 2008-10-08

Family

ID=34115188

Family Applications (1)

Application Number Title Priority Date Filing Date
CNB2006100047484A Expired - Lifetime CN100423807C (en) 2002-01-31 2003-01-18 Nanofiber filter media

Country Status (2)

Country Link
CN (1) CN100423807C (en)
ZA (1) ZA200307532B (en)

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103328069A (en) * 2010-12-17 2013-09-25 霍林斯沃思和沃斯有限公司 Filter media with fibrillated fibers
CN103706182A (en) * 2013-12-12 2014-04-09 苏州大学 Spherical and linear combined compound fiber air filtering material and preparation method thereof
CN104114479A (en) * 2012-02-15 2014-10-22 北越纪州制纸株式会社 Porous body and process for manufacturing same
CN104420400A (en) * 2013-08-30 2015-03-18 珠海市红旌发展有限公司 Preparation method of air filtering paper containing nanocellulose
CN104582812A (en) * 2012-06-20 2015-04-29 霍林斯沃思和沃斯有限公司 Fiber webs including synthetic fibers
US9352267B2 (en) 2012-06-20 2016-05-31 Hollingsworth & Vose Company Absorbent and/or adsorptive filter media

Family Cites Families (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
ATE300990T1 (en) * 1997-06-26 2005-08-15 Asahi Medical Co FILTER MEDIUM FOR SEPARATING LEUKOCYTES
DE19920983C5 (en) * 1999-05-06 2004-11-18 Fibermark Gessner Gmbh & Co. Ohg Two-layer or multi-layer filter medium for air filtration and filter element made from it
CN2390670Y (en) * 1999-09-14 2000-08-09 天津市长城过滤设备厂 Coaxial multi-core layer high density compaction filtering hybridized compound core

Cited By (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103328069A (en) * 2010-12-17 2013-09-25 霍林斯沃思和沃斯有限公司 Filter media with fibrillated fibers
CN103328069B (en) * 2010-12-17 2016-01-20 霍林斯沃思和沃斯有限公司 There is the filter medium of fibrillating fibre
CN104114479A (en) * 2012-02-15 2014-10-22 北越纪州制纸株式会社 Porous body and process for manufacturing same
CN104114479B (en) * 2012-02-15 2016-04-27 北越纪州制纸株式会社 Porous media and manufacture method thereof
CN104582812A (en) * 2012-06-20 2015-04-29 霍林斯沃思和沃斯有限公司 Fiber webs including synthetic fibers
US9352267B2 (en) 2012-06-20 2016-05-31 Hollingsworth & Vose Company Absorbent and/or adsorptive filter media
CN104582812B (en) * 2012-06-20 2017-08-11 霍林斯沃思和沃斯有限公司 Web including synthetic fibers
CN104420400A (en) * 2013-08-30 2015-03-18 珠海市红旌发展有限公司 Preparation method of air filtering paper containing nanocellulose
CN103706182A (en) * 2013-12-12 2014-04-09 苏州大学 Spherical and linear combined compound fiber air filtering material and preparation method thereof

Also Published As

Publication number Publication date
ZA200307532B (en) 2004-09-14
CN100423807C (en) 2008-10-08

Similar Documents

Publication Publication Date Title
CN1279997C (en) Nanofiber filter media
AU2003210565A1 (en) Nanofiber filter media
KR101752922B1 (en) Multi-phase filter medium
JP3802839B2 (en) Nonwoven fabric for filters and filters for engines
JP2008518770A (en) Improved high strength, high capacity filter media and structure
EP2144684A2 (en) Filtration media having a slit-film layer
JP3138016B2 (en) Filter media
US20070128434A1 (en) Filler-affixed fiber, fiber structure, and fiber molded body, and method for producing the same
CN100423807C (en) Nanofiber filter media
JP2006061789A (en) Filter medium for liquid filtering
CN112004587B (en) High burst strength wet laid nonwoven filter media and method of producing same
JPH08196829A (en) Air cleaning filter medium and its production
CN1901986A (en) Fiber-fiber composites
JP2019166513A (en) Dust collection deodorizing filter material and dust collection deodorizing filter
JP2005058832A (en) Filter medium for filtering liquid
JP3014439B2 (en) Filter media
KR102485081B1 (en) Filter using mulberry bast fiber and its manufacturing method
JP2003129393A (en) Organic extra-superfine fiber sheet
KR102629885B1 (en) Support for muti-functional purifier filter and method for manufacturing the same
JP2006055735A (en) Filter material for liquid filtration
KR102331253B1 (en) Paper for air cleaner support and method for manufacturing the same
JP4634072B2 (en) Water purification material
JP7422576B2 (en) Filter medium, filter element, and method for manufacturing filter medium
TW200540309A (en) Filler-fixed fiber, fiber structure, molded fiber, and processes for producing these
KR20230067222A (en) Electrostatic nanocomposite nonwoven fabric for air purification and a manufacturing method thereof

Legal Events

Date Code Title Description
C06 Publication
PB01 Publication
C10 Entry into substantive examination
SE01 Entry into force of request for substantive examination
ASS Succession or assignment of patent right

Owner name: KX INDUSTRIAL MERGED COMPANY

Free format text: FORMER OWNER: KOSLOW TECHNOLOGY CORP.

Effective date: 20070720

C41 Transfer of patent application or patent right or utility model
TA01 Transfer of patent application right

Effective date of registration: 20070720

Address after: American Connecticut

Applicant after: KX Technologies, LLC

Address before: American Connecticut

Applicant before: KOSLOW TECHNOLOGIES Corp.

C14 Grant of patent or utility model
GR01 Patent grant
ASS Succession or assignment of patent right

Owner name: KX TECHNOLOGY CO., LTD.

Free format text: FORMER OWNER: KX INDUSTRIAL MERGED COMPANY

Effective date: 20090410

C41 Transfer of patent application or patent right or utility model
TR01 Transfer of patent right

Effective date of registration: 20090410

Address after: American Connecticut

Patentee after: KX TECHNOLOGIES LLC

Address before: American Connecticut

Patentee before: KX Technologies, LLC

CX01 Expiry of patent term

Granted publication date: 20081008

CX01 Expiry of patent term