The present disclosure relates to an exhaust system for an engine. More particularly, the present disclosure relates to a muffler of an exhaust system for an engine.
An exhaust system for an internal combustion engine employs a muffler in order to dampen exhaust noise generated by the engine. In a multi-cylinder internal combustion engine, two different exhaust streams can be generated by two different banks of cylinders. The two exhaust streams can flow into the muffler from two different portions of an exhaust manifold through two different exhaust pipes. In many situations, the two exhaust streams can collide and mix within the muffler and can further exit the muffler in two different exhaust stream or a combined single exhaust stream. The collision and mixing of the two exhaust streams can result in an undesired backpressure within the muffler. In some situations, the collision and mixing of the two exhaust streams can result in an increased exhaust noise within the muffler. Hence, there is a need for an improved muffler for such applications.
Given description covers one or more above mentioned problems and discloses a method and a system to solve the problems.
In an aspect of the present disclosure, a muffler for use with an internal combustion engine is provided. The muffler includes a first tube. The first tube includes a first inlet portion defining a first inlet configured to receive a first exhaust stream. The first inlet portion is disposed along a first axial plane. The first tube also includes a first outlet portion defining a first outlet and disposed along a second axial plane. The second axial plane is vertically spaced from the first axial plane. The first tube further includes a first intermediate portion extending from the first inlet portion to the first outlet portion. The first intermediate portion is fluidly coupled to the first inlet portion and the first outlet portion. The muffler also includes a second tube. The second tube includes a second inlet portion defining a second inlet configured to receive a second exhaust stream. The second inlet portion is spaced apart from the first inlet portion and disposed along a third axial plane. The second tube also includes a second outlet portion spaced apart from the first outlet portion and defining a second outlet. The second outlet portion is disposed along a fourth axial plane that is vertically spaced from the third axial plane. The second tube further includes a second intermediate portion extending from the second inlet portion to the second outlet portion. The second intermediate portion is fluidly coupled to the second inlet portion, the second outlet portion and the first intermediate portion. The first intermediate portion and the second intermediate portion cross each other and are at least partially stacked on each other.
In another aspect of the present disclosure, a muffler for use with an internal combustion engine is provided. The muffler includes a first tube configured to receive a first exhaust stream. The first tube includes a first inlet portion, a first outlet portion spaced apart from the first inlet portion, and a first intermediate portion extending between the first inlet portion and the first outlet portion. The muffler also includes a second tube configured to receive a second exhaust stream. The second tube includes a second inlet portion, a second outlet portion spaced apart from the second inlet portion, and a second intermediate portion extending between the second inlet portion and the second outlet portion. The first intermediate portion and the second intermediate portion cross each other, are at least partially stacked on each other, and are in fluid communication with each other.
In yet another aspect of the present disclosure, an exhaust system for use with an internal combustion engine having a first row of cylinders and a second row of cylinders is provided. The exhaust system includes a first pipe adapted to receive a first exhaust stream from the first row of cylinders. The exhaust system also includes a second pipe adapted to receive a second exhaust stream from the second row of cylinders. The exhaust system further includes a muffler. The muffler includes a first tube fluidly coupled to the first pipe. The first tube includes a first inlet portion defining a first inlet configured to receive the first exhaust stream. The first inlet portion is disposed along a first axial plane. The first tube also includes a first outlet portion defining a first outlet and disposed along a second axial plane. The second axial plane is vertically spaced from the first axial plane. The first tube further includes a first intermediate portion extending from the first inlet portion to the first outlet portion. The first intermediate portion is fluidly coupled to the first inlet portion and the first outlet portion. The muffler also includes a second tube fluidly coupled to the second pipe. The second tube includes a second inlet portion defining a second inlet configured to receive the second exhaust stream. The second inlet portion is spaced apart from the first inlet portion and disposed along a third axial plane. The second tube also includes a second outlet portion spaced apart from the first outlet portion and defining a second outlet. The second outlet portion is disposed along a fourth axial plane that is vertically spaced from the third axial plane. The second tube further includes a second intermediate portion extending from the second inlet portion to the second outlet portion. The second intermediate portion is fluidly coupled to the second inlet portion, the second outlet portion and the first intermediate portion. The first intermediate portion and the second intermediate portion cross each other and are at least partially stacked on each other.
Other features and aspects of this disclosure will be apparent from the following description and the accompanying drawings.
Aspects of the disclosure generally relate to a muffler that provides a simple, efficient, and cost-effective method of reducing exhaust noise downstream of the muffler. The muffler includes first and second tubes that provide substantially separate flow paths for multiple exhaust streams. The first and second tubes reduce direct collision between the multiple exhaust streams, which in turn reduces drag and backpressure within the muffler. Also, as the multiple exhaust streams cross each other in a common chamber located between the first and second tubes, the common chamber provides limited interaction and mixing of the multiple exhaust streams. This results in cancelling half engine order noise generated in each of first and second pipes, which reduces fluid noise within the muffler. As a result, overall exhaust noise is reduced downstream of the muffler relative to a conventional muffler having substantial interaction and mixing of different exhaust streams.
Wherever possible, the same reference numbers will be used throughout the drawings to refer to same or like parts. Referring to
The exhaust system 102 includes a first exhaust manifold 110 and a second exhaust manifold 112. The first exhaust manifold 110 is coupled to the first row of cylinders 106. Accordingly, the first exhaust manifold 110 is adapted to receive a first exhaust stream “E1” from the first row of cylinders 106. The second exhaust manifold 112 is coupled to the second row of cylinders 108. Accordingly, the second exhaust manifold 112 is adapted to receive a second exhaust stream “E2” from the second row of cylinders 108. Additionally, the engine 104 can include components and/or systems not described herein, such as an engine block, a cylinder head, a valve assembly, an intake manifold, a cooling system, a lubrication system, an air delivery system, a turbocharger, a supercharger, or other peripherals based on application requirements.
The exhaust system 102 also includes a muffler 114. The muffler 114 is coupled to each of the first exhaust manifold 110 and the second exhaust manifold 112. More specifically, the muffler 114 is coupled to the first exhaust manifold 110 via a first pipe 116. The first pipe 116 is adapted to provide flow of the first exhaust stream “E1” from the first exhaust manifold 110 to the muffler 114. Also, the muffler 114 is coupled to the second exhaust manifold 112 via a second pipe 118. The second pipe 118 is adapted to provide flow of the second exhaust stream “E2” from the second exhaust manifold 112 to the muffler 114. The muffler 114 is adapted to reduce exhaust noise downstream of each of the first pipe 116 and the second pipe 118.
The exhaust system 102 also includes a number of downstream components coupled to the muffler 114, such as a first auxiliary muffler 120 and a second auxiliary muffler 122. The first auxiliary muffler 120 is adapted to receive the first exhaust stream “E1” from the muffler 114. The second auxiliary muffler 122 is adapted to receive the second exhaust stream “E2” from the muffler 114. Additionally, the exhaust system 102 can include one or more aftertreatment components/systems (not shown), such as a Diesel Particulate Filter (DPF) unit, a Diesel Oxidation Catalyst (DOC) unit, a Diesel Exhaust Fluid (DEF) unit, a Selective Catalytic Reduction (SCR) unit, a tailpipe, or other components based on application requirements.
Referring to
The muffler 114 also includes a first plate 206 and a second plate 208. In the illustrated embodiment, each of the first plate 206 and the second plate 208 has a substantially flat and trapezoidal configuration. In other embodiments, one or more of the first plate 206 and the second plate 208 can have any other configuration, such as a bent configuration, an angled configuration, a stepped configuration, a circular configuration, an elliptical configuration, a rectangular configuration, or other configuration based on application requirements. Each of the first plate 206 and the second plate 208 can be manufactured using any process, such as stamping, forging, casting, additive manufacturing, or other manufacturing process based on application requirements. Each of the first casing 202, the second casing 204, the first plate 206, and the second plate 208 is coupled to one other to form a housing 210 (shown in
The muffler 114 further includes a first inner section 212 and a second inner section 214. The second inner section 214 has a configuration substantially similar to a configuration of the first inner section 212. Each of the first inner section 212 and the second inner section 214 has a substantially curved and X-shaped configuration. In the illustrated embodiment, each of the first inner section 212 and the second inner section 214 is manufactured by stamping process, rather than by a traditional casting method. In traditional cross-pipe muffler applications, the cast part was die-locked, which prevented the muffler pipes from being stamped. One of the issues solved by the present disclosure is that the present disclosure allows the muffler pipes to be stamped as two halves (i.e. first inner section 212 and second inner section 214) and later assembled. That said, it is possible that in other embodiments, each of the first inner section 212 and the second inner section 214 can be manufactured using any other process, such as forging, additive manufacturing, or other manufacturing process based on application requirements.
Each of the first inner section 212 and the second inner section 214 is coupled to one other to form a first tube 216 (shown in
Referring to
The housing 210 includes the first plate 206 and the second plate 208. The second plate 208 is spaced apart from the first plate 206 along the first longitudinal axis A-A′ and the second longitudinal axis B-B′. More specifically, the first plate 206 is disposed on the first end 220 of the housing 210 and the second plate 208 is disposed on the second end 222 of the housing 210. In the illustrated embodiment, the first plate 206 and the second plate 208 are disposed parallel to one another and perpendicular to the first longitudinal axis A-A′ and the second longitudinal axis B-B′. In other embodiments, one or more of the first plate 206 and the second plate 208 can be inclined relative to the first longitudinal axis A-A′ and the second longitudinal axis B-B′. The housing 210 also includes the first casing 202 and the second casing 204. Each of the first casing 202 and the second casing 204 extends between the first plate 206 and the second plate 208. Each of the first casing 202 and the second casing 204 is adapted to at least partly enclose the first tube 216 and the second tube 218.
The muffler 114 will now be explained with combined reference to
In the illustrated embodiment, the first inlet portion 224 has a substantially straight configuration. In other embodiments, the first inlet portion 224 can have any other configuration, such as a curved configuration or an angled configuration. The first inlet portion 224 is disposed along a first axial plane “P1”. In the illustrated embodiment, the first axial plane “P1” is disposed along the first longitudinal axis A-A′. As such, in the illustrated embodiment, the first axial plane “P1” is substantially parallel to the first longitudinal axis A-A′. In other embodiments, the first axial plane “P1” can be inclined relative to the first longitudinal axis A-A′. Also, in other embodiments, the first axial plane “P1” can be spaced apart from the first longitudinal axis A-A′.
The first tube 216 also includes a first outlet portion 228. The first outlet portion 228 is disposed within an aperture 260 (shown in
The first outlet portion 228 is disposed along a second axial plane “P2”. In the illustrated embodiment, the second axial plane “P2” is disposed along the second longitudinal axis B-B′. As such, in the illustrated embodiment, the second axial plane “P2” is substantially parallel to the second longitudinal axis B-B′ and the first axial plane “P1”. In other embodiments, the second axial plane “P2” can be inclined relative to the second longitudinal axis B-B′. Also, in other embodiments, the second axial plane “P2” can be spaced apart from the second longitudinal axis B-B′. Additionally, in the illustrated embodiment, the second axial plane “P2” is vertically spaced from the first axial plane “P1” by a distance “D1”. In other embodiments, the second axial plane “P2” and the first axial plane “P1” can be coplanar, based on application requirements.
The first tube 216 further includes a first intermediate portion 232. The first intermediate portion 232 extends from the first inlet portion 224 to the first outlet portion 228. As such, the first intermediate portion 232 is fluidly coupled to the first inlet portion 224 and the first outlet portion 228. The first intermediate portion 232 is adapted to allow flow of the first exhaust stream “E1” from the first inlet portion 224 to the first outlet portion 228. In the illustrated embodiment, the first intermediate portion 232 has a substantially curved configuration. More specifically, the first intermediate portion 232 extends away from the first inlet portion 224, such that the first intermediate portion 232 bends perpendicularly relative to the first axial plane “P1′ and the first longitudinal axis A-A′, and also laterally relative to the first axial plane “P1′ and the first longitudinal axis A-A′ in order to align with the second longitudinal axis B-B′. Further, the first intermediate portion 232 bends toward the second longitudinal axis B-B′ and the second axial plane “P2” in order to align with the first outlet portion 228. Accordingly, the first intermediate portion 232 extends between the first axial plane “P1” and the second axial plane “P2” vertically spaced by the distance “D1”. In other embodiments, the first intermediate portion 232 can have any other configuration, such as an angled configuration, a straight configuration, or other configuration based on application requirements.
The muffler 114 also includes the second tube 218. The second tube 218 is adapted to be fluidly coupled to the second pipe 118. The second tube 218 includes a second inlet portion 234. The second inlet portion 234 is disposed within an aperture 262 (shown in
In the illustrated embodiment, the third axial plane “P3” and the first axial plane “P1” are coplanar. Accordingly, the third axial plane “P3” is vertically spaced from the second axial plane “P2” by the distance “D1”. In other embodiments, the third axial plane “P3” can be spaced apart from the first axial plane “P1”. Also, in the illustrated embodiment, the third axial plane “P3” is parallel to each of the first axial plane “P1” and the second axial plane “P2”. In other embodiments, the third axial plane “P3” can be inclined relative to one or more of the first axial plane “P1” and the second axial plane “P2”.
The second tube 218 also includes a second outlet portion 238. The second outlet portion 238 is disposed within an aperture 264 (shown in
The second outlet portion 238 is disposed along a fourth axial plane “P4”. In the illustrated embodiment, the fourth axial plane “P4” is disposed along the second longitudinal axis B-B′. Accordingly, the second outlet portion 238 is spaced apart from the first outlet portion 228 along the second longitudinal axis B-B′. Also, in the illustrated embodiment, the fourth axial plane “P4” is substantially parallel to the second longitudinal axis B-B′. In other embodiments, the fourth axial plane “P4” can be inclined relative to the second longitudinal axis B-B′. Also, in other embodiments, the fourth axial plane “P4” can be disposed spaced apart from the second longitudinal axis B-B′. Additionally, in the illustrated embodiment, the fourth axial plane “P4” is vertically spaced from the third axial plane “P3” by a distance “D2”. In the illustrated embodiment, the distance “D2” is approximately equal to the distance “D1” between the first axial plane “P1” and the second axial plane “P2”. In other embodiments, the fourth axial plane “P4” and the third axial plane “P3” can be coplanar, based on application requirements.
In the illustrated embodiment, the fourth axial plane “P4” and the second axial plane “P2” are coplanar. Accordingly, the fourth axial plane “P4” is vertically spaced from the first axial plane “P1” by the distance “D1”. In other embodiments, the fourth axial plane “P4” can be spaced apart from the second axial plane “P2”. Also, in the illustrated embodiment, the fourth axial plane “P4” is parallel to each of the first axial plane “P1”, the second axial plane “P2”, and the third axial plane “P3”. In other embodiments, the fourth axial plane “P4” can be inclined relative to one or more of the first axial plane “P1”, the second axial plane “P2”, and the third axial plane “P3”.
The second tube 218 further includes a second intermediate portion 242. The second intermediate portion 242 extends from the second inlet portion 234 to the second outlet portion 238. As such, the second intermediate portion 242 is fluidly coupled to the second inlet portion 234 and the second outlet portion 238. The second intermediate portion 242 is adapted to allow flow of the second exhaust stream “E2” from the second inlet portion 234 to the second outlet portion 238. In the illustrated embodiment, the second intermediate portion 242 has a substantially curved configuration. More specifically, the second intermediate portion 242 extends away from the second inlet portion 234, such that the second intermediate portion 242 bends perpendicularly relative to the third axial plane “P3′ and the first longitudinal axis A-A′, and also laterally relative to the third axial plane “P3′ and the first longitudinal axis A-A′ in order to align with the second longitudinal axis B-B′. Further, the second intermediate portion 242 bends toward the second longitudinal axis B-B′ and the fourth axial plane “P4” in order to align with the second outlet portion 238. Accordingly, the second intermediate portion 242 extends between the third axial plane “P3” and the fourth axial plane “P4” vertically spaced by the distance “D2”. In other embodiments, the second intermediate portion 242 can have any other configuration, such as an angled configuration, a straight configuration, or other configuration based on application requirements.
Additionally, the first intermediate portion 232 and the second intermediate portion 242 are disposed in manner such that the first intermediate portion 232 and the second intermediate portion 242 cross each other. Also, the first intermediate portion 232 and the second intermediate portion 242 are at least partially stacked on each other defining a substantially twisted X-shaped configuration of the first intermediate portion 232 and the second intermediate portion 242. As such, crossing and stacking of the first intermediate portion 232 and the second intermediate portion 242 provides a substantially separate flow path for each of the first exhaust stream “E1” and the second exhaust stream “E2” flowing in substantially opposite direction without complete interaction and mixing of the first exhaust stream “E1” with the second exhaust stream “E2” within the muffler 114. Further, the first intermediate portion 232 and the second intermediate portion 242 are fluidly coupled to each other. Accordingly, a common chamber 244 is defined within each of the first intermediate portion 232 and the second intermediate portion 242. The common chamber 244 is adapted to provide at least partial interaction and mixing of the first exhaust stream “E1” with the second exhaust stream “E2”.
Referring to
As the first exhaust stream “E1” and the second exhaust stream “E2” cross each other in the common chamber 244, the first intermediate portion 232 and the second intermediate portion 242 provide substantially separate flow paths for the first exhaust stream “E1” and the second exhaust stream “E2”. As such, due to flow of the first exhaust stream “E1” and the second exhaust stream “E2” in different axial planes complete interaction and mixing of the first exhaust stream “E1” and the second exhaust stream “E2” is limited, in turn, reducing drag and backpressure within the muffler 114. Also, as the first exhaust stream “E1” and the second exhaust stream “E2” cross each other in the common chamber 244, the common chamber 244 provides limited interaction and mixing of the first exhaust stream “E1” and the second exhaust stream “E2”, in turn, cancelling half engine order noise generated in each of the first pipe 116 and the second pipe 118 of the exhaust system 102 and reducing fluid noise within the muffler 114. As a result, an overall exhaust noise is reduced downstream of the muffler 114 relative to a conventional muffler having substantial interaction and mixing of different exhaust streams therein.
The muffler 114 provides a simple, efficient, and cost-effective method of reducing exhaust noise downstream of each of the first pipe 116 and the second pipe 118. The muffler 114 includes the first tube 216 and the second tube 218 providing substantially separate flow path for each of the first exhaust stream “E1” and the second exhaust stream “E2”. As such, direct collision between the first exhaust stream “E1” and the second exhaust stream “E2” is reduced, in turn, reducing drag and backpressure within the muffler 114. More specifically, the first intermediate portion 232 and the second intermediate portion 242 provide crossing of the first exhaust stream “E1” and the second exhaust stream “E2” via the common chamber 244 without direct collision of opposing flows of the first exhaust stream “E1” and the second exhaust stream “E2”.
Also, the curved configuration of each of the first intermediate portion 232 and the second intermediate portion 242 provides gradual change in flow direction of the first exhaust stream “E1” and the second exhaust stream “E2”, in turn, reducing drag and backpressure within the muffler 114. Additionally, the common chamber 244 provides limited and controlled interaction between portions of the first exhaust stream “E1” and the second exhaust stream “E2”, in turn, cancelling half order engine noise and reducing the overall exhaust noise. The muffler 114 can be manufactured using any process, such as stamping, casting, or any other process, in turn, providing ease of manufacturing and reducing costs. The muffler 114 can be retrofitted in any exhaust system, in turn, providing improved usability, flexibility, and compatibility.
While aspects of the present disclosure have been particularly shown and described with reference to the embodiments above, it will be understood by those skilled in the art that various additional embodiments can be contemplated by the modification of the disclosed machines, systems and methods without departing from the spirit and scope of what is disclosed. Such embodiments should be understood to fall within the scope of the present disclosure as determined based upon the claims and any equivalents thereof.
This application is a National Phase application of International Application No. PCT/US2020/036076, filed Jun. 4, 2020, which claims the benefit of U.S. Provisional Patent Application 62/858,546 filed Jun. 7, 2019, both of which are hereby incorporated by reference in their entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/US2020/036076 | 6/4/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2020/247597 | 12/10/2020 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
6478340 | Butler | Nov 2002 | B1 |
20040154289 | Schlossarczyk et al. | Aug 2004 | A1 |
20070045041 | Krueger | Mar 2007 | A1 |
20070068150 | Mueller | Mar 2007 | A1 |
20100146955 | Tuch | Jun 2010 | A1 |
20140166393 | Butler | Jun 2014 | A1 |
20160024989 | Eichmueller et al. | Jan 2016 | A1 |
20180202344 | Klemenc | Jul 2018 | A1 |
20190107019 | Ostromecki et al. | Apr 2019 | A1 |
Number | Date | Country |
---|---|---|
105164381 | Dec 2015 | CN |
108026807 | May 2018 | CN |
109630235 | Apr 2019 | CN |
110454264 | Nov 2019 | CN |
2000248947 | Sep 2000 | JP |
3740879 | Feb 2006 | JP |
1020070108584 | Nov 2007 | KR |
Entry |
---|
International Search Report and the Written Opinion of the International Searching Authority for Counterpart PCT/US2020/036076, dated Sep. 11, 2020, 13 pages. |
Chinese Office Action for Counterpart CN202080042097.6, dated Apr. 19, 2023, 8 Pages. |
Number | Date | Country | |
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20220220874 A1 | Jul 2022 | US |
Number | Date | Country | |
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62858546 | Jun 2019 | US |