IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
UP-0337024
(2006-01-23)
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등록번호 |
US-7537083
(2009-07-01)
|
우선권정보 |
DK-2000 00475(2000-03-21); DK-2000 00954(2000-06-19) |
발명자
/ 주소 |
|
출원인 / 주소 |
|
대리인 / 주소 |
Birch, Stewart, Kolasch & Birch, LLP
|
인용정보 |
피인용 횟수 :
13 인용 특허 :
56 |
초록
▼
A silencer with a casing and at least one inlet passage for leading gas into said casing, and at least one outlet opening for leading gas out of said casing, said silencer containing at least one acoustic chamber contained in the casing, at least one porous body inside said chamber, the porous body
A silencer with a casing and at least one inlet passage for leading gas into said casing, and at least one outlet opening for leading gas out of said casing, said silencer containing at least one acoustic chamber contained in the casing, at least one porous body inside said chamber, the porous body comprising a through-flow filter occupying at least part of the chamber, where said at least one porous body is designed to retain particles contained in the gas, at least one connecting passage for leading gas from each one of the at least one acoustic chamber to another of the at least one acoustic chamber or to an exterior environment or an exterior chamber, wherein at least part of at least one of said connecting passages extends along an outer surface of the porous body, so as to lead gas along a helical flow path.
대표청구항
▼
What is claimed is: 1. A silencer with a casing and at least one inlet passage for leading gas into said casing, and at least one outlet opening for leading gas out of said casing, said silencer containing: at least two acoustic chambers contained in the casing; at least one porous body inside at l
What is claimed is: 1. A silencer with a casing and at least one inlet passage for leading gas into said casing, and at least one outlet opening for leading gas out of said casing, said silencer containing: at least two acoustic chambers contained in the casing; at least one porous body inside at least one of said chambers, said at least one porous body comprising a through-flow filter occupying at least part of the chamber, wherein said at least one porous body is designed to retain particles contained in the gas, or said at least one porous body having interior surface parts which are adapted to be in contact with the gas, the interior surface parts carrying a catalytic material promoting one or more chemical reactions reducing noxious components of said gas; and two or more connecting passages for leading gas from one of the at least two acoustic chambers to another of the at least two acoustic chambers, wherein at least part of at least one of said connecting passages extends along an outer surface of the porous body, so as to lead gas along a helical flow path and cover at least 50% of the surface area of said outer surface area of the porous body, wherein said two or more passages lead gas in two or more parallel flows, and are created by insertion of one or more division members or walls inside an annular spacing. 2. A silencer according to claim 1 in which said at least one filter porous body comprises a ceramic monolith. 3. A silencer according to claim 1 in which said at least one porous body carries catalytic material promoting catalytic conversion of NOx. 4. A silencer according to claim 3 in which the at least one porous body which has surfaces carrying a catalytic material comprises a through-flow monolith. 5. A silencer according to claim 1 in which at least one of said at least one porous body comprises a heat exchanger in which the gas exchanges heat energy with a second fluid which passes through said heat exchanger. 6. A silencer according to claim 1 in which at least one of said at least one porous body combines: filtering with catalysis; and filtering with heat exchange, or filtering with both catalysis and heat exchange. 7. A silencer according to claim 1, containing at least two trough-flowed porous bodies, the at least two through-flowed porous bodies being arranged in series. 8. A silencer according to claim 7, in which one of the through-flowed porous bodies comprises a catalytic converter, and the other one comprises a filter which is designed to retain particles contained in the gas. 9. A silencer according to claim 8, wherein the filter is arranged downstream of the catalytic converter. 10. A silencer according to claim 9, wherein the catalytic converter is adapted to generate NO2 to enhance combustion of particles accumulated in the filter. 11. A silencer according to claim 10, wherein the filter comprises a particulate filter. 12. A silencer according to claim 10, wherein the filter is made essentially from SiC. 13. A silencer according to claim 10, wherein the filter is made essentially from cordierite. 14. A silencer according to claim 1 in which at least one of said at least one porous body comprises two or more monoliths arranged to be through-flowed by parallel gas flows and arranged adjacent to each other or with a distance between each monolith. 15. A silencer according to claim 1, comprising two acoustic chambers in said casing, and wherein one and only one passage interconnects the two chambers. 16. A silencer according to claim 1, comprising two acoustic chamber in said casing, and wherein more than one passage interconnects the two chambers, the passages leading gas from one chamber to the other one in two or more parallel flows. 17. A silencer according to claim 1, in which the two or more passage covers substantially the entire surface area of said outer surface area of the porous body. 18. A silencer according to claim 1 in which the at least two or more connecting passage is mechanically connected to the at least one porous body along the outer surface of which the connecting passages extends. 19. A silencer according to claim 1 in which there is a distance between said two or more connecting passage and said at least one porous body. 20. A silencer according to claim 19 in which there is a spacing between said two or more connecting passage and said at least one porous body, said spacing being adapted in such a way that sound essentially does not by-pass said passage. 21. A silencer according to claim 1 in which the radial extension of said two or more connecting passage is substantially constant throughout the length of the passage. 22. A silencer according to claim 1 in which at least part of one of said connecting passages is designed in such a way that the flow area increases in the flow direction. 23. A silencer according to claim 22 in which said flow area increase is attained by gradual and/or abrupt increase of the radial extension of said two or more connecting passage in the flow direction. 24. A silencer according to claim 22 in which a said flow area increase is attained or increased by gradual or abrupt increase of the passage width in the flow direction. 25. A silencer according to claim 1 in which said two or more connecting passage extends on an envelope which is substantially circular cylindrical. 26. A silencer according to claim 1 in which said two or more connecting passage extends on an envelope which is oval. 27. A silencer according to claim 1 in which said two or more connecting passage extends on an envelope with a cross-section which defines a closed figure composed by curved sections only or by partly curved and partly straight sections, in such a way that abrupt turnings in flow direction within said passages are avoided. 28. A silencer according to claim 1, in which the passages are shaped as winding pipes. 29. A silencer according to claim 28, in which the individual windings of the winding pipes are arranged adjacent to each other. 30. A silencer according to claim 29 in which the individual windings are separated by common division walls. 31. A silencer according to claim 28, in which the winding pipes are wound with such a pitch that there is an axial spacing between the windings. 32. A silencer according to claim 1 in which said division members only extend in a part of said annular spacing. 33. A silencer according to claim 1 in which at least part of one of said connecting passages is designed in such a way that the flow area increases in the flow direction, and in which a width of at least part of at least one of said division members decreases in the flow direction so as to cause increased width(s) of helical passage(s) in flow direction. 34. A silencer according claim 1 in which at least part of one of said connecting passages is designed in such a way that the flow area increases in the flow direction, and in which said division members or walls are shaped such that gas enters said annular spacing in a combined axial and peripheral direction and leaves said spacing in a direction which is closer to axial direction, in such a way that flow velocity decreases inside said passages. 35. A silencer according to claim 1 in which all flows in passages created by division members or walls are substantially identical. 36. A silencer according to claim 1, in which said two or more connecting passage comprises a first and a second connecting passage, and in which the first connecting passage extends along an outer surface of the second connecting passage. 37. A silencer according to claim 1 in which at least one of said at least one porous body is penetrated by an extension into the silencer of at least one external pipe or external passage or by at least one of said two or more connecting passage which leads gas through said porous body. 38. A silencer according to claim 1 in which the outflow from said two or more passage leaves said passage at a plurality of locations along the periphery of said at least one porous body, thereby forming an inlet to a flow field upstream of said porous body, in which flow field gas molecules are distributed across the inlet cross-section of said porous body. 39. A silencer according to claim 1 in which the inflow to said two or more passage enters said passage at a plurality of locations along the periphery of at least one of said at least one said porous body, thereby forming an outlet flow field downstream of said porous body, in which the flow field gas molecules are distributed across the outlet cross-section of said porous body. 40. A silencer according claim 38 in which the flow turns inside a cavity when passing from said two or more passage to said porous body, or vice versa, said cavity containing flow guiding means. 41. A silencer according to claim 1 in which said inlet passage is located at substantially one end of said casing, and in which said outlet opening is located at substantially the same end of the casing. 42. A silencer according to claim 1 in which said inlet passage is located at substantially one end of said casing, and in which said outlet opening is located at substantially the opposite end of the casing. 43. A silencer according to claim 1 in which said outlet opening comprises a pipe or passage. 44. A silencer according to claim 1 in which the effective distance between an inlet and an outlet of said two or more connecting passage is F times the direct distance between said inlet and said outlet, F being at least 1.1. 45. A silencer according to claim 44 in which F is at least 1.25. 46. A silencer according to claim 44 in which F is at least 1.5. 47. A silencer according to claim 44 in which F is at least 2.0. 48. A silencer according to claim 44 in which F is at least 3.0. 49. A silencer according to claim 44 in which F is at least 5.0. 50. A silencer according to claim 1 in which said two or more connecting passage defines a turning angle of the flow path of at least 180 degrees. 51. A silencer according to claim 50 wherein said turning angle is at least 360 degrees. 52. A silencer according to claim 50 wherein said turning angle is at least 600 degrees. 53. A silencer according to claim 1, wherein said at least one acoustic chamber comprises at least two acoustic chambers interconnected by said two or more connecting passage, the silencer being suited for installation in a piping system connected to a reciprocating machine or engine generating a prominent noise of frequency fpulse inside said piping system, the two or more connecting passage being such formed and sized that the Helmholtz natural frequency f' constituted by said connecting passage and said two acoustic chambers fulfils the criterion: f'=φfpulse, where φ<1. 54. A silencer according to claim 53, wherein φ<0.75. 55. A silencer according to claim 53, wherein φ<0.5. 56. A silencer according to claim 53, wherein φ<0.25. 57. A vehicle comprising a silencer with a casing and at least one inlet passage for leading gas into said casing, and at least one outlet opening for leading gas out of said casing, said silencer containing: at least one acoustic chamber contained in the casing; at least one porous body inside said chamber, the at least one porous body comprising a through-flow filter occupying at least part of the chamber, wherein said at least one porous body is designed to retain particles contained in the gas, or the at least one porous body having interior surface parts which are adapted to be in contact with the gas, the interior surface parts carrying a catalytic material promoting one or more chemical reactions reducing noxious components of said gas; and two or more connecting passages for leading gas from one of the at least two acoustic chambers to another of the at least two acoustic chambers, wherein at least part of two or more of said connecting passages extends along an outer surface of the porous body, so as to lead gas along a helical flow path and cover at least 50% of the surface area of said outer surface area of the porous body, wherein said two or more passages lead gas in two or more parallel flows, and are created by insertion of one or more division members or walls inside an annular spacing. 58. A stationary installation comprising a silencer with a casing and at least one inlet passage for leading gas into said casing, and at least one outlet opening for leading gas out of said casing, said silencer containing: at least two acoustic chambers contained in the casing, at least one porous body inside said chamber, the at least one porous body comprising a through-flow silencer occupying at least part of the chamber, wherein said at least one porous body is designed to retain particles contained in the gas, or the at least one porous body having interior surface parts which are adapted to be in contact with the gas, the interior surface parts carrying a catalytic material promoting one or more chemical reactions reducing noxious components of said gas; and two or more connecting passages for leading gas from one of the at least two acoustic chambers to another of the at least two acoustic chambers, wherein at least part of two or more of said connecting passages extends along an outer surface of the porous body, so as to lead gas along a helical flow path and cover at least 50% of the surface area of said outer surface area of the porous body, wherein said two or more passages lead gas in two or more parallel flows, and are created by insertion of one or more division members or walls inside an annular spacing.
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