Exhaust gas filter apparatus capable of regeneration of a particulate filter and method
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B01D-046/00
F01N-003/027
F01N-003/023
출원번호
UP-0257846
(2005-10-24)
등록번호
US-7513921
(2009-07-01)
발명자
/ 주소
Phelps, Amanda C.
Kirby, Kevin W.
Gregoire, Daniel
출원인 / 주소
HRL Laboratories, LLC
대리인 / 주소
Balzan, Christopher R.
인용정보
피인용 횟수 :
8인용 특허 :
12
초록
An exhaust gas filter apparatus includes a particulate filter for collecting a particulate from an exhaust gas. The exhaust gas filter also includes a electromagnetic radiation resonator to heat a portion of the particulate to ignite the particulate and regenerate the particulate filter.
대표청구항▼
What is claimed is: 1. A particulate filter apparatus comprising: a) a first filter portion configured to collect a particulate; b) a reflector configured to inhibit electromagnetic radiation from propagating through the first filter portion; c) an absorber configured to heat to a temperature suffi
What is claimed is: 1. A particulate filter apparatus comprising: a) a first filter portion configured to collect a particulate; b) a reflector configured to inhibit electromagnetic radiation from propagating through the first filter portion; c) an absorber configured to heat to a temperature sufficient to ignite the particulate in response to the electromagnetic radiation; and d) a second filter portion between the reflector and the absorber. 2. The particulate filter apparatus of claim 1, wherein the reflector is adjacent to the first and second filter portions. 3. The particulate filter apparatus of claim 2, wherein the absorber is adjacent to the second filter portion reflector. 4. The particulate filter apparatus of claim 1, wherein the first filter portion and the second filter portion form a unitary filter, and wherein the unitary filter comprises the reflector. 5. The particulate filter apparatus of claim 4, wherein the absorber is adjacent to the second filter portion. 6. The particulate filter apparatus of claim 1, further comprising an electromagnetic resonant cavity adjacent the second filter portion, wherein the reflector partially defines the electromagnetic resonant cavity, the absorber and the second filter portion being located within the electromagnetic resonant cavity. 7. The particulate filter apparatus of claim 1, wherein the reflector is configured to inhibit microwave radiation from propagating through the first filter portion, and wherein the absorber is configured to heat to a temperature sufficient to ignite the particulate in response to the microwave radiation. 8. The particulate filter apparatus of claim 7 further comprising a microwave resonant cavity adjacent the first filter portion, wherein the reflector partially defines the microwave resonant cavity, the absorber being located within the microwave resonant cavity. 9. A particulate filter apparatus comprising: a) a particulate filter comprising an absorber and a reflector both near an RF source end of the particulate filter, the absorber being spaced apart from the reflector of the particulate filter; and b) an electromagnetic radiation resonator at the end, the electromagnetic radiation resonator extending to the reflector such that the absorber is in the electromagnetic radiation resonator. 10. The particulate filter apparatus of claim 9, wherein the absorber is separated from the reflector by a distance approximately equal to an integer multiple of one-quarter of the wavelength of electromagnetic radiation in the electromagnetic radiation resonator. 11. The particulate filter apparatus of claim 9, wherein the absorber is capable of absorbing a magnetic field component of an electromagnetic radiation. 12. The particulate filter apparatus of claim 11, wherein the electromagnetic radiation resonator comprises a RF choke opposing the reflector. 13. The particulate filter apparatus of claim 12, wherein the absorber is composed of a ferrite material. 14. The particulate filter apparatus of claim 12, wherein the absorber comprises a nonmetallic magnetic material disbursed in a binder. 15. The particulate filter apparatus of claim 12, wherein the absorber comprises a metallic magnetic material disbursed in a binder. 16. The particulate filter apparatus of claim 9, wherein the absorber is capable of absorbing an electric field portion of an electromagnetic radiation. 17. The particulate filter apparatus of claim 16, wherein the particulate filter comprises a first filter portion and a second filter portion, the first filter portion located in the electromagnetic radiation resonator, and wherein the volume of the first filter portion is less than the volume of the second filter portion. 18. The particulate filter apparatus of claim 9, wherein the electromagnetic radiation resonator comprises a RF choke opposing the reflector, and wherein the RF choke is separated from the reflector by a distance approximately equal to an integral multiple of one-half of a wavelength of an electromagnetic radiation in the electromagnetic radiation resonator. 19. The particulate filter apparatus of claim 9, wherein the absorber is capable of absorbing a magnetic field component and an electric field portion of electromagnetic radiation. 20. The particulate filter apparatus of claim 9, further comprising an electromagnetic frequency source configured to generate electromagnetic radiation. 21. The particulate filter apparatus of claim 9, wherein the particulate filter is composed of a ceramic material. 22. The particulate filter apparatus of claim 9, wherein the absorber is selected from a group consisting of silicon carbide and indium tin oxide. 23. The particulate filter apparatus of claim 9, wherein the electromagnetic radiation resonator is a microwave resonator. 24. A particulate filter apparatus comprising: a) a filter for collecting a particulate; and b) a microwave resonator extending part way into the filter, the microwave resonator comprising: (i) a microwave reflector configured to inhibit microwave radiation from propagating all the way through the filter, wherein the microwave reflector is within the filter; and (ii) an absorber in the electromagnetic resonator capable of heating to a temperature sufficient to ignite the particulate at the absorber in response to the microwave radiation, wherein the absorber is spaced apart from the microwave reflector. 25. A method of manufacturing a particulate filter comprising: depositing a microwave reflective coating at an end of a filter; and depositing an absorptive coating adjacent the microwave reflective coating, the absorptive coating being capable of absorbing a magnetic field component of microwave radiation. 26. The method of claim 25, wherein depositing the absorptive coating adjacent the reflecting coating comprises depositing the absorptive coating over at least a portion of the microwave reflective coating. 27. A method of manufacturing a particulate filter comprising: depositing a microwave reflective coating over a portion of a particulate filter; and depositing an absorptive coating over a portion of the particulate filter, the absorptive coating being capable of absorbing an electric field component of microwave radiation. 28. A method of manufacturing a particulate filter comprising: depositing an absorptive coating over an end of a first filter portion, the absorptive coating capable of absorbing an electric field component of microwave radiation; depositing a microwave reflective coating over an end of a second filter portion; and mounting the first filter portion to the second filter portion with the microwave reflective coating being located between the first filter portion and the second filter portion. 29. The method of claim 28, wherein mounting the first filter portion to the second filter portion comprises performing a thermal consolidation process. 30. A method of manufacturing a particulate filter comprising: depositing an absorptive coating over a first end of a first filter portion, the absorptive coating capable of absorbing an electric field component of microwave radiation; depositing a microwave reflective coating over a second end of the first filter portion; and mounting the first filter portion to a second filter portion with the microwave reflective coating being located between the first filter portion and the second filter portion. 31. The method of claim 30, wherein mounting the first filter portion to the second filter portion comprises performing a thermal consolidation process. 32. The particulate filter apparatus of claim 4, wherein the unitary filter further comprises the absorber. 33. The particulate filter apparatus of claim 32, wherein the absorber is composed of a ferrite material. 34. The particulate filter apparatus of claim 32, wherein the absorber comprises a nonmetallic magnetic material disbursed in a binder. 35. The particulate filter apparatus of claim 32, wherein the absorber comprises a metallic magnetic material disbursed in a binder. 36. The particulate filter apparatus of claim 9, further comprising an enclosure containing the particulate filter, the enclosure having input and output gas flow openings, the input gas flow opening comprising an input reflector associated therewith. 37. A particulate filter apparatus comprising: a) a filter portion configured to collect a particulate; b) a reflector configured to inhibit electromagnetic radiation from propagating through the filter portion; c) an absorber configured to heat to a temperature sufficient to ignite the particulate in response to the electromagnetic radiation; and d) an electromagnetic supply spaced apart from the reflector such that electromagnetic radiation is introduced into an area of the resonating chamber away from the reflector. 38. The particulate filter apparatus of claim 37, wherein the reflector is adjacent to the filter portion. 39. The particulate filter apparatus of claim 38, wherein the absorber is adjacent to the reflector. 40. A particulate filter apparatus comprising: a) an enclosure having input and output gas flow openings, the input gas flow opening comprising an input reflector associated therewith; b) a particulate filter comprising an absorber and a filter reflector both adjacent to an electromagnetic source end of the particulate filter; c) an electromagnetic radiation resonator adjacent to the electromagnetic source end, the electromagnetic radiation resonator extending to the reflector such that the absorber is in the electromagnetic radiation resonator; and d) an electromagnetic supply adjacent to the input gas flow opening and spaced apart from the filter reflector such that electromagnetic radiation is inserted into an area of the resonator away from the filter reflector. 41. The particulate filter apparatus of claim 40, wherein the filter reflector is adjacent to the filter portion. 42. The particulate filter apparatus of claim 41, wherein the absorber is adjacent to the filter reflector.
Puschner Herbert A. (Schwanenwede DEX) Frtauer Johann (Neuhofen ATX), Device and process for separating soot or other impurities from the exhaust gases of an internal-combustion engine.
Allie, Mark C.; Verdegan, Barry M.; Schukar, Murray R.; Haberkamp, William C.; Cheng, C. Raymond; Henrichsen, Matthew P., Regenerable filter with localized and efficient heating.
Fischer Edward M. (White Bear Lake MN) Bloom Richard L. (Woodville WI) Sanocki Stephen M. (Stillwater MN) Sabean Joel H. (Hudson WI), Self supporting hot gas filter assembly.
Nakao, Kenji; Suzuki, Kimihito; Fujimoto, Kenichiro; Taira, Hatsuo, Hybrid adsorbent method of capturing carbon dioxide in gas and apparatus for capturing carbon dioxide in gas.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.