High capacity hybrid multi-layer automotive air filter
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B01D-029/01
B01D-039/04
B01D-046/12
출원번호
US-0286383
(2002-11-01)
발명자
/ 주소
Niakin, Shahriar Nick
출원인 / 주소
Advanced Flow Engineering, Inc.
대리인 / 주소
Crockett, Esq. K David
인용정보
피인용 횟수 :
22인용 특허 :
19
초록▼
An automotive air filter including natural fiber filter media region, having piteous, absorbent, wickable natural fibers, a synthetic fiber filter media region including, absorbent spunbond polyester filters. The natural fiber region receives an influent fluid stream containing particles, trapping s
An automotive air filter including natural fiber filter media region, having piteous, absorbent, wickable natural fibers, a synthetic fiber filter media region including, absorbent spunbond polyester filters. The natural fiber region receives an influent fluid stream containing particles, trapping some particles. The manufactured fiber region removes residual particles, producing a filtered effluent stream. The fluid stream passes unimpaired through the fiber pores. Two structural mesh layers sandwich natural and manufactured fiber regions. Oil is disposed in the oleophilic cotton mesh. Fiber regions have layers disposed in gradient density arrangement.
대표청구항▼
1. A fluid filter media, comprising:a. a natural fiber filter media region receiving an influent fluid stream containing particles, the natural fiber filter media having pores therethrough and being formed from a pileous, absorbent, and wickable natural fiber, the natural fiber filter media region t
1. A fluid filter media, comprising:a. a natural fiber filter media region receiving an influent fluid stream containing particles, the natural fiber filter media having pores therethrough and being formed from a pileous, absorbent, and wickable natural fiber, the natural fiber filter media region trapping therein a first portion of the particles in the influent fluid stream while the influent fluid stream passes substantially unimpaired through the pores, and creating a filtered fluid stream having therein a second portion of the particles thereby; andb. a manufactured fiber filter media region in proximate contact with, and in fluid communication with, the natural fiber filter media region and receiving the filtered fluid stream therefrom, the manufactured fiber filter media region having pores therethrough and being formed from a pre-selected pileous and absorbent manufactured fiber, the manufactured fiber filter media region trapping therein a substantial amount of the particles of the second portion in the filtered fluid stream while the filtered fluid stream passes substantially unimpaired through the pores, and releasing a filtered effluent fluid stream thereby. 2. The fluid filter media of claim 1, wherein the natural fiber is a cotton fiber. 3. The fluid filter media of claim 2, wherein the manufactured fiber is a spunbond polyester fiber. 4. The fluid filter media of claim 3, wherein the manufactured fiber filter media region further comprises spunbound polyester fiber layers. 5. The fluid filter media of claim 4, wherein the manufactured fiber filter media region comprises a first spunbond polyester fiber layer having a first polyester fiber density, and a second spunbond polyester fiber layer having a second polyester fiber density, with the first polyester fiber density being less than the second polyester fiber density, and wherein the first spunbond polyester fiber layer is disposed closer to the receiving of the influent fluid stream and the second spunbond polyester fiber layer is disposed closer to the filtered effluent fluid stream. 6. The fluid filter media of claim 2 wherein the natural fiber filter media region further comprises cotton mesh layers. 7. The fluid filter media of claim 6, wherein at least one of the cotton mesh layers is plain-woven cotton gauze. 8. The fluid filter media of claim 7, wherein the manufactured fiber is a spunbond polyester fiber and the manufactured fiber filter media region comprises spunbond polyester fiber layers. 9. The fluid filter media of claim 6, wherein the manufactured fiber is a spunbond polyester fiber and the manufactured fiber filter media region comprises spunbond polyester fiber layers. 10. The fluid filter media of claim 9, wherein the cotton fiber is oleophilic and further comprising an efficacious amount of oil disposed in the natural fiber filter media region, the oil wetting the cotton fibers, thereby increasing particle trapping by the natural fiber filter media region. 11. The fluid filter media of claim 6, wherein at least one of the cotton mesh layers is a non-woven hydroentangled cotton fabric. 12. The fluid filter media of claim 11, wherein the manufactured fiber is a spunbond polyester fiber and the manufactured fiber filter media region comprises spunbond polyester fiber layers. 13. The fluid filter media of claim 6, wherein the natural fiber filter media region comprises a first cotton mesh layer having a first cotton mesh density, and a second cotton mesh layer having a second cotton mesh density, with the first cotton mesh density being less than the second cotton mesh density, and wherein the first cotton mesh layer is disposed closer to the influent fluid stream and the second cotton mesh layer is disposed closer to the filtered effluent fluid stream. 14. The fluid filter media of claim 13, wherein the manufactured fiber filter media region comprises a first spunbond polyester fiber layer having a first polyester fiber density, and a second s punbond polyester fiber layer having a second polyester fiber density, with the first polyester fiber density being less than the second polyester fiber density, and wherein the first spunbond polyester fiber layer is disposed closer to the second cotton mesh layer, and the second spunbond polyester fiber layer is disposed closer to the filtered effluent fluid stream. 15. The fluid filter media of claim 1, wherein the natural fiber is oleophilic and further comprising an efficacious amount of oil disposed in the natural fiber filter media region, the oil wetting the natural fibers, thereby increasing particle trapping by the natural fiber filter media region. 16. The fluid filter media of claim 1, further comprising two structural mesh layers with the natural fiber filter media region and the manufactured fiber filter media region being interposed in a supported relationship therebetween. 17. A fluid filter comprising:a. a natural fiber filter media region receiving an influent fluid stream containing particles, the natural fiber filter media having pores therethrough and being formed from a pileous, absorbent, and wickable cotton mesh, the natural fiber filter media region trapping therein a first portion of the particles in the influent fluid stream while the influent fluid stream passes substantially unimpaired through the pores, and creating a filtered fluid stream having therein a second portion of the particles thereby;b. a manufactured fiber filter media region in proximate contact with, and in fluid communication with, the natural fiber filter media region and receiving the filtered fluid stream therefrom, the manufactured fiber filter media region having pares therethrough and being formed from a pre-selected pileous and absorbent spunbond polyester fiber, the manufactured fiber filter media region trapping therein a substantial amount of the particles of the second portion in the filtered fluid stream while the filtered fluid stream passes substantially unimpaired through the pores, and releasing a filtered effluent fluid stream thereby; andc. two structural mesh layers with the natural fiber filter media region and the manufactured fiber filter media region being interposed in a supported relationship therebetween;wherein the cotton mesh is oleophilic and further comprising an efficacious amount of oil disposed in the natural fiber filter media region, the oil wetting the cotton mesh, thereby increasing particle trapping by natural fiber filter media region. 18. The fluid filter of claim 17, wherein the wickable cotton mesh of the natural fiber filter media region further comprises cotton mesh layers and the spunbond polyester of the manufactured fiber filter media region further comprises spunbond polyester fiber layers. 19. The fluid filter of claim 18:a. wherein the natural fiber filter media region comprises a first cotton mesh layer having a first cotton mesh density, and a second cotton mesh layer having a second cotton mesh density, with the first cotton mesh density being less than the second cotton mesh density; and wherein the first cotton mesh layer is disposed closer to the receiving of the influent fluid stream and the second cotton mesh layer is disposed closer to the filtered effluent fluid stream; andb. wherein the manufactured fiber filter media region comprises a first spunbond polyester fiber layer having a first polyester fiber density, and a second spunbond polyester fiber layer having a second polyester fiber density, with the first polyester fiber density being less than the second polyester fiber density, and wherein the first spunbond polyester fiber layer is disposed closer to the second cotton mesh layer, and the second spunbond polyester fiber layer is disposed closer to the filtered effluent fluid stream. 20. An air filter for an internal combustion engine, comprising:a. a natural fiber filter media region receiving air stream containing particles, the natural fiber filter media having p ores therethrough and being formed from a pileous, absorbent, and wickable cotton mesh layers, the natural fiber filter media region trapping therein a first portion of the particles in the influent air stream while the influent air stream passes substantially unimpaired through the pores, and creating a filtered air stream having therein a second portion of the particles thereby;b. a manufactured fiber filter media region in proximate contact with, and in fluid communication with, the natural fiber filter media region and receiving the filtered air stream therefrom, the manufactured fiber filter media region having pores therethrough and being formed from a pre-selected pileous and absorbent spunbond polyester fiber layers, the manufactured fiber filter media region trapping therein a substantial amount of the particles of the second portion in the filtered air stream while the filtered air stream passes substantially unimpaired through the pores, and releasing a filtered effluent air stream to the internal combustion engine thereby; andc. two structural mesh layers with the natural fiber filter media region and the manufactured fiber filter media region being interposed in a supported relationship therebetween;wherein the cotton mesh layers are oleophilic and further comprising an efficacious amount of oil disposed in the natural fiber filter media region, the oil wetting the cotton mesh layers, thereby increasing particle trapping by natural fiber filter media region. 21. The air filter of claim 20:a. wherein the natural fiber filter media region comprises a first cotton mesh layer having a first cotton mesh density, and a second cotton mesh layer having a second cotton mesh density, with the first cotton mesh density being less than the second cotton mesh density; and wherein the first cotton mesh layer is disposed closer to the receiving of the influent air stream and the second cotton mesh layer is disposed closer to the filtered effluent air stream; andb. wherein the manufactured fiber filter media region comprises a first spunbond polyester fiber layer having a first polyester fiber density, and a second spunbond polyester fiber layer having a second polyester fiber density, with the first polyester fiber density being less than the second polyester fiber density, and wherein the first spunbond polyester fiber layer is disposed closer to the second cotton mesh layer, and the second spunbond polyester fiber layer is disposed closer to the filtered effluent air stream.
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