CA2272387C

CA2272387C - A filter having hollow fibers impregnated with solid adsorbent particles

Info

Publication number: CA2272387C
Application number: CA002272387A
Authority: CA
Inventors: Ronald P. Rohrbach; Gordon W. Jones; Peter D. Unger; Daniel Bause; Lixin Xue; Russell A. Dondero
Original assignee: AlliedSignal Inc
Current assignee: Fram Group IP LLC
Priority date: 1996-11-27
Filing date: 1997-11-24
Publication date: 2006-03-14
Anticipated expiration: 2017-11-24
Also published as: JP2001506537A; EP0951333A1; US6398039B1; KR20000057260A; US5759394A; EP0951333B1; WO1998023358A1; DE69731552D1; KR100495733B1; JP4005641B2; CA2272387A1; DE69731552T2

Abstract

An air filtration or fluid treatment system includes a nonwoven filter media or mat (10) formed from a plurality of elongated generally hollow fibers (20) each having an internal cavity (22) which has an opening (24) to the fiber surface and each retaining within the internal cavity a large number of relatively small solid particles (18), which interact with the air or other fluid stream to be treated. The solid adsorbent particles (18), such as activated carbon, are permanently entrapped within the longitudinal cavities (22) of the fibers (20) without the use of an adhesive or without being embedded onto or within the polymer fiber.

Description

WO 983,358 PCT/US97!'21429 ' United States Patent Application For:
s A FILER HAVING HOLLOW FIBERS IM ~tiNS~D WITH SOLID
RENT PARTICLE
lo Background of the Invention I . Fold of the invention _ This invention relates to a filter system and more particularly to a t s system tnilizing a solid adsorbent, such as active carbon particles.

2. l~esotiption of Prior Art It is known in the prior art to use activated charcoal or a zeotite as as adsorptive odor removing element or media to pn:ify an air Zo stresm. U.S. Pit No: 4,130:487 shows a ilher for liquid or gases which includes activated cfor removing odors during air Sltruion. The acxivpted c~bon is in an additional layer which is added to the filter muerial.
Poor art f~tas have used the s~afacae coavag of a fiber media with p~oias sad have also used carbon fibers. The carton i5 fibers are formed from organic polymer fibers which are heated and carbonized. 'The ability to coat various powdered particulate material on a surtax of a fiber or other item has required as adbaive layer to be used to imanoi~li~e and hold the powder particles on the stnfaae. The very act of _ using as adhesive to hold the paaicks results in a portion of the surface of the 30 - po~vd~ panicles being contaminated by the adhesive and therefore becoming ineffective for filt~ion. A balance has to be rriet betureea the strength of the immobilization versus the maintaining of effectiveness of the powder layer. In order to tttiniraize this contamination larger particles are often used so that the point of contact between the surface adhesive and~powder particles is small.
In 35 typical gaseous applications using activated carbon the particles used are frequently 100 microns and larger; and, finely powdered activated carbon is basically only used in liquid decolorization applications despite the fact that fine powder activated carbon holds the potential of much more rapid kinetics.
Summary of ttte Invention The pn~ent invention provides a filter wherein a solid adsorbent, such as an activated carbon powder, is entrapped, without the ux of an adhesive.
within longiaidinal cavities formed in each of the fibers is a fiber filter media or mat. The solid adsorbent in such an application retains virtually the same adsorption capability or capacity as it had in the original virgin stock. This is to contrary to adhesive retention .of carbon patticdes w~,ein the particles retain only a fraction of their original capacity. The fibers have longitudinal extending internal cavities which have openings extending to the outer surface of the fibers. These fibers provide a way to meohamcally immobilize _ powdered activated carbon adsorbent part~l~ hut the use of an adhesive.
t s The fiber. the opea~ng size and the particles to be enuspped sit sel~ted so that whey the patti~des..~ f~to the longitudinal cavities they are permaneady Twined. The activated carbon poi mechanically trapped within the lotagitudinal cavities of the fibers and is basically irreversible boned. This approach can be eat ~ my p~,~ which one 2o would like to entrap within a fiber medium, including such agents as zeolites.
baking soda, cyclvdext:ins or any solid which has some property to either adsorb cataia gases of int~st or ~relase agents into s fluid stieam. _ This invention provides a filter m~ia gal con~riaing flexible fibers. each having a cross section with internal cavities. The internal cavities _. __ Zs extard loagitudi,aai along the lengthwise dic~axion of thd fiber and they are filled with a solid particulate tnatetial which can adsorb unwanted molecules.
The filter mat of the pnsectt invention stmuld have a significant cost savings ' over filters using_carbon fibers and should outperform filters using granular J activated carbon coatings. ' Hrrief Description of Drawlogs we 9sn33ss rcrrtrs~m4~

For a beaer understanding of the invention reference may be had to the - preferred embodiments exemplary of the inventions shown in the accompanying drawings in which: -FIG. 1 is an illustration of a portion of a nonwoven fiber mat utilizing fibers contaiuuag carbon particles according to the present invention;
FIG. 2 is an enluger view of a potvon of the fiber mat shown in Fig.l ufibers according to the gtesent invention;
FIG. 3 is a perspective view showing a fiber which is suitable for practicing the present invention: and.
FIG 4 is sitaplifted view of a filtration system using a fiber filter mat according to the Qrrxent invention.
D~aiiad D~tioo of the Prefen~ed Embodlmeots 1 s R~efaiing now to the drawings and Figtama 1 and 2 is particular there is shown a nonwoven fiber tnu 10 filter famed from a plurality of flatible fibers 20. Each fiber 20 include: an internal cavity 22 within which are disposed small dry active carbon paaeles 18. A longiardinal opening 24 ext~ds from each cavity 22 to the surface of each fiber 20. The multilobal 2o fibers 20 are relatively atoall having a diatne<er of 10 to 250 micarons or smaller. The size of opening 24 is sekaed so wixn particles 18 are disposed in cavity 22 they arc genaallY pa~ra:u~ly caaapped and camel daily be removed. The active carbon parocies ue selected to be substantially staaller thin opening 24 atsd getretally are vay small being ku than IO microns 2s across.
The small particles carbon particles 18 bane mechanically entia~ed noel within the fiber cavities 22 and g~aaily do not enter the space between the fibers 20: yet, through the longitudinal openings 24 the particles 18 are in communication with the air stream flowing past the -' 3o genitally hollow fibers 20.
The g~ adsatbing active carbon particles 18 whicfthave an affinity for the undesired gases to be removed from the air stream are selected and disposed within the internal channels or cavities 22 formed in the individual WO 98/3358 PCTIUS97r11429 generally hollow fibers 20 . The dry particles selected use adsorption rather than absorption as the mechanism to decontaminate or purify the air stream.
The particles 18 used are selected to adsorb the vapors of interest, to be non hazardous and to neutralize specific gases and odor vapors.
The fiber filter mat 10 can be used in an air filtration or odor removal system as illustrated in the simplified diagram of Figure 4. The filter system has a housing 12 with an air inlet 14 and an air outlet 16. The fiber that 10 is disposed across the housing so the sir stream entering through inlet 14 must flow through the fiber mat 10 to reach the outlet 1b. A mechanical device to such as a fan can be used to assist-with the air Row. The air filtration system can be constructed so the fiber filter mat 10 can be easily removed and replaced.
A generally hollow fiber 20 which is particularly suitable for practicing this inveation is disclosed in U.S. Patent No. 5,057,368 sad shown ih Figure 3.
z s This patent discloses a trilobal or quadrilobal fiber formed from tl>ertaoplasdc polymers wherein the fiber has a cross-secti~ with a xottai core aad brae or four T-shaped lobes 2b. The legs of the lobes intmsea at the cme 30 so that the angle between the legs of adjacent lobes is from about 80 degrees to 130 degreees. The tla~rtaoptastic polymer is typically a polyamide, a polyester, a 2o polyolefin or a combination thettof. The fiber 20 as illustrated in Fignre 3 is formed as an estrand having three hollow interior longitudinally e~ctending cavities 22 oath of which comramricates with the oeuec strand surface by way of lot~itudinai extending slots 24 which are defined between the outer ends of the T-shaped lobes.
25 As can be clearly sxn in Figures 1 and 2 the active carbotr particles 18 are >,ttstined within the individual cavities 22 without spilling out into the inter fiber voids. The fibers 20 strongly retain the active carbon particles 18 within the cavities 22 so that the particles 18 will not shake off and the fiber mat retains the particles 18 when touched or handled. in a filter mat 10 of such 3a- fibers 20 the area between the individual strands remains relatively free of the gas adsorbing active carbon particles l8 with which the internal cavities 2?
of each fiber 20 are filled. The filter mat 10 fibers may be made of one or more WO 9&23358 PGT/US9'f/21429 types of material such as polyamides, polyesters, or polyolefins. The three T-Shaped cross-section segmcncs may have their outer surface 28 curved. as shown, or the outer surface may also be straight. While the fiber 20 is depicted as three lobed other number of lobar are suitable. In addition other s external or internal fibers with C~shapes or other cross sections may also be suitable for retaining the small gas adsorbing particles 18 provided the opening from the cavity is sized to retain the particles 18 within the fiber interior 22.
In fesming the fibar mat 10, the solid particles ara aggressively rubbed l o into the fibers 20. The procedure used for dry impregnation is to take the fibers 20 and liberally dust them with the t powder. The particles 18 of the adsorbent powder have a diameter of less the one half the fiber 20 cross ~~o~ . The powder particles 18 are rolled into the fiber 20 several The excess powder is physically removed by agitation aided by a t 5 strong air flow. 'Ibc powder particles 18 which remain within the cavities arc surprisingly stable and reaistaat to physical action. We believe it is a ~YtYpa ~ ~p~nt which tenacimrsly holds the particles 18 within the cavities 22. The particles 18 stem to engage one another and do not spill 5rnn the cavities 22 through opening 24. We triad impregnating trilobal 2o fiber in which the outer ends ~ caps of the lobes 26 were removed. Very little carbon parrides were rrxainead by such fibers.
Lt ot~da to dine the cause of the forets raponaible for this s,~Y interacticut baween the fibers 20 and the fine powder particles 18 we attempted to roduce the electrostatic bonding forces, if any.
25 which might have ea,raed this tenacious agglomeration. We first subjected the imps carbon 5bers to 10096 c~elative humidity and 40 meters per minute of air over the fibers 20 and cold any off dust. We found undetectable amounts. We further took the fiber filter mat 10 and submerged it into room tempemttme water with agitation and found the cartron particles 30 still remained securely in place. Then wt took the filter fiber mat 10 and added detergent to the water with agitation and found no futthrr loss.
Additionally the cart~oa impregnated fibers 20 withstood both an alcohol and w0 98J233S8 PCT/LTS97/21429 acetone wash without loss of carbon particles 18. Tlux tests clearly indicate that the forces responsible for this interaction are non electrostatic in nature and suggest a mechanical entrapment. These tests also iridieate the fibers 20 impregnated with activated carbon or other particles might have applications for various fluid media including gas and liquids.
' _ The disclosed approach can be extetrded to any powder which one would like to entrap within a fiber nxditaa; including such agents as zeolites, baking soda, cyclodextrins or any number_of other solid particle of interest.
~ fibers 20 have also been usad to arttap p>tticks of zinc oxide. zirconium oxide, silica, aluaaiaa is various plraxs, chJrs including kaolin and beatonite.
in the fibers 20- shown is Figures 1 and 2 the fiber diameter is around 30 microns. The size of the cavit~r 22 opening 24 is approximately i0 microns.
The carbon particles are around 1 to 2 micmaa a~ and stmlkr.
The material described in this invention can lx sut#aOe coated with ~ s virtually complete boa of the powder's and can be extended to be used with eu~edy fine powders. By so doing ono can sigaificaady improve the perforrmance and efficiency of the powder. la the case of activated carbon, typical gaseous applications ux gtaanlu carbon of 100 micxons and larger and finely powdered activased carbon is basically only used in liquid decol~izaeion applications despite the fact the powder activated carbon holds the potential of much m~a~e rapid kinetics. With this invention filters can be cooatnu~od utilizing finely po~rdexd activased carbon for gas phax applications. Additionally. this inre~on can also be used for liquid based applications.
Basically this invwuion provides a sitapiilud and low cost version of a filter mat using carbon fiber elements. Instead of forming the carbon filter fibers by starting with an organic polymer which is then ~d and carbonized we start with a generally hollow fiber and impregnate ii with powdered _ carbon. A few other examples of filter applications for this invention are: an 30 odor control carbon filter; a zeolite coatod odor control filter, and a metal sequestering water filter. This invention might also be used for removal of organic water pollutants from contaminated water supplies:

Claims

CLAIMS:

1. Apparatus for removing molecules from a fluid stream comprising:
a plurality of elongated fibers each having multiple lobes with a longitudinally extending internal cavity including an opening from the internal cavity to the outer fiber surface formed between adjacent lobes;
a fine powder, made from particles which can adsorb the molecules, disposed within the internal cavities of said plurality of elongated fibers;
a flow path for the fluid stream, containing the molecules to be removed, directed over a portion of said plurality of elongated fibers whereby the molecules to be removed are adsorbed by said fine powder; and, said fine powder particles being of such a size, shape and makeup that they are securely retained mechanically within the internal cavities.

2. Apparatus as claimed in claim 1 wherein each elongated fiber is less than microns in diameter and the majority of fine powder particles are less than 20 microns in size.

3. Apparatus as claimed in claim 1 wherein the fine powder particles are activated carbon and the fluid stream is air.

4. Apparatus as claimed in claim 1 wherein each lobe has a generally T-shaped cross section.

5. A filter for removing selected types of molecules comprising:
a plurality of elongated multilobal flexible fibers, each having at least one elongated open channel formed between adjacent lobes and extending into the interior of the fiber, disposed to form a nonwoven fiber filter mat; and, a plurality of solid particles which have an affinity for the selected type of molecules disposed and held mechanically within the channels for adsorbing the selected type of molecules as they pass through the filter.

6. A filter as claimed in claim 5 wherein the diameter of each elongated fiber is less than 250 microns and the average diameter of said plurality of solid particles is less than 10 microns.

7. A filter as claimed in claim 5 wherein each fiber includes a plurality of elongated open channels within which the plurality of solid particles which can adsorb the selected types of molecules are disposed.

8. A filter as claimed in claim 7 wherein the fibers are disposed in generally a parallel alignment in the nonwoven fiber filter mat.

9. A filter as claimed in claim 7 wherein the fibers are disposed in the nonwoven fiber filter mat in an orientation which is not parallel.

10. An air filtration system for removing gas phase contaminants comprising:
a plurality of multilobal fibers each having at least one longitudinally extending open channel projecting into the interior of the fiber, a fine powder, made from a plurality of small solid particles which can adsorb the gas phase contaminants disposed and mechanically held within the open channels in said plurality of fibers, and an air flow path containing the gas phase contaminants directed over a portion of said plurality of fibers whereby said plurality of small solid particles disposed in the open channels communicates with the air flow path and adsorbs the gas phase contaminants.

11. an air filtration system as claimed in claim 10 wherein the fine powder particles are activated carbon and the fluid stream is air and each fiber includes a plurality of longitudinally extending open channels projection into the fiber interior.