JP2018025191A - Intake port sound absorber - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an intake port sound absorber for a compressor for an exhaust gas supercharger and the exhaust gas supercharger.SOLUTION: An intake port sound absorber 10 comprises a cylindrical housing 12 provided with exterior walls 13, 14 arranged at opposite sides to each other and an outer shell wall 15; a main flow inlet 16 formed in an area of the outer shell wall; and a main flow outlet 17 formed in an area of the exterior wall 14. When first medium flows between the main flow inlet and the main flow outlet through the intake port sound absorber, a first medium is deflected from an orientation in which it flows in a substantial radial direction and flows out in a substantial axial direction. The intake port sound absorber is further provided with a flow guide element 18 for a second medium and further a flow outlet 19 is arranged within the housing at a downstream side of a flow deflection point for the first medium flow. With this arrangement as above, the second medium is mixed with the first medium at a downstream side in a flow direction of the first medium within the housing 12.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an inlet silencer for a compressor of an exhaust gas supercharger, and an exhaust gas supercharger.

  Patent Document 1 discloses various embodiments of an inlet silencer for a compressor of an exhaust gas supercharger. The patent document is an air inlet silencer including a cylindrical housing, and the housing extends between these outer walls and a circular outer wall disposed on the opposite side of each other. An inlet silencer is disclosed having a tubular outer shell wall. A main flow inlet for the main flow made of the first medium is formed in the region of the outer shell wall, and a main flow outlet for the main flow made of the first medium is formed in the region of the outer wall. Is formed. When the first medium flows through the inlet silencer between the main flow inlet and the main flow outlet, the first medium is deflected from the direction of flowing in the substantially radial direction to the direction of flowing out in the substantially axial direction. It flows toward the compressor disposed downstream. The first medium is an air supply to be compressed.

  In addition, US Pat. No. 6,057,059 discloses mixing the main stream of the first medium with the further stream of the second medium in the region of the inlet silencer. Here, the second medium of the further flow is compressor bypass air or air / fuel mixture. In this patent document, a further compressor housing, which is arranged between the inlet silencer and the compressor of the exhaust gas supercharger, is required to guide the further flow of the second medium. Here, the second medium of the further flow can be mixed with the first medium of the main flow upstream of the main flow deflection point.

  Inlet silencers known from the prior art literature have several drawbacks. For example, the additional compressor housing required in the prior art requires high design costs, extensive installation space, and high costs.

  In the case of a further embodiment of the inlet silencer known from the prior art document, the introduction from the radial direction is carried out downstream in the inlet silencer, so that the silencer The structure is easy to wake up. This has an adverse effect on the installation space and causes further drawbacks such as vibration excitation due to ground space and disturbed inflow, for example. The flow guidance and mixing of the first medium and the second medium in the region of the inlet silencer causes vibrations in the downstream where the compressor is connected, especially in the downstream where the compressor impeller is connected. Excited. This is the opposite of the ideal stable compressor operation.

European Patent Application No. 2386761

  From this point of view, the present invention is based on the object of creating a new type of suction silencer and exhaust gas supercharger.

  This object is solved through the inlet silencer according to claim 1. In the present invention, the inlet silencer comprises a further flow guiding element for the second medium, and a further flow outlet is arranged inside the housing downstream of the flow deflection point of the first medium. Thereby, the second medium flowing through the further flow guiding element is mixed with the first medium downstream of the flow direction of the first medium inside the housing. The flow of the first medium circulates around the further flow guiding element in the region of the further flow outlet.

  The inlet silencer in the present invention does not require an additional compressor housing. For this reason, design cost, cost, and installation space can be reduced. Furthermore, by utilizing a further compressor housing or pipe element comprising a radial gas supply pipe arranged between the compressor housing and the silencer, adverse effects on the vibratory behavior of the turbocharger attached to the internal combustion engine Can be eliminated. Furthermore, the operation of the compressor can be optimized.

  In a further advantageous embodiment of the invention, the further flow guiding element for the second medium is at the center of the housing such that the longitudinal central axis of the further flow guiding element coincides with the longitudinal central axis of the housing. It extends in the direction of the longitudinal central axis of the housing. Thereby, it is possible to realize an exhaust gas supercharger equipped with a particularly small intake silencer and by extension, the supply air silencer. Furthermore, the intake port silencer can be arranged at any angle based on the compressor of the exhaust gas supercharger.

  In a further advantageous further development of the invention, the further flow outlet of the further flow guide element comprises a second flow cross-sectional area for the second medium, and in the plane of the further flow outlet, an inlet silencer Has a channel cross-section of the first channel cross-sectional area in which no obstacle for the first medium exists, and the ratio of the second channel cross-sectional area to the first channel cross-sectional area is It is 0.02 to 0.09, preferably 0.03 to 0.08, and particularly preferably 0.035 to 0.075. Particularly advantageous is that the vibration excitation of the compressor can be avoided by mixing the first medium and the second medium based on the ratio of the flow path cross-sectional areas, and as a result, it is particularly advantageous. The operation of the compressor can be realized.

  The exhaust gas supercharger according to the present invention is defined in claim 8.

  Preferred further developments of the invention can be understood from the dependent claims and the detailed description of the invention. Exemplary embodiments of the present invention will be described in greater detail through the accompanying drawings, but are not intended to limit the present invention.

1 is a schematic cross-sectional view of an inlet silencer according to the present invention. It is a cross-sectional perspective view of the air inlet silencer in the present invention.

  The present invention particularly relates to an inlet silencer for a compressor of an exhaust gas supercharger, and an exhaust gas supercharger including the inlet silencer.

  FIG. 1 is a very schematic cross-sectional view of an inlet silencer 10 according to the present invention. In FIG. 1, the compressor 11 of the exhaust gas supercharger is disposed downstream of the inlet silencer 10.

  The compressor 11 of the exhaust gas supercharger is configured to compress the supply air to be compressed supplied to the internal combustion engine. In a turbine of an exhaust gas supercharger (not shown), exhaust gas discharged to the internal combustion engine is expanded, and energy extracted in the process is used to drive the compressor 11. A compressor impeller 22 of the compressor 11 is shown.

  The inlet silencer 10 is disposed upstream of the compressor 11 and is configured to take in the air to be compressed and guide the air to be compressed that has been taken in toward the compressor 11. Has been.

  The air inlet silencer 10 includes a housing 12 that includes exterior walls 13 and 14 and an outer shell wall 15 that are disposed on opposite sides of each other. The outer shell wall 15 extends between the two exterior walls 13 and 14. The two exterior walls 13 and 14 are typically formed in a circular shape, and the outer shell wall 15 extending between the two exterior walls 13 and 14 is typically formed in a tubular shape. ing.

  A main flow inlet 16 for the main flow made of the first medium is formed in the region of the outer shell wall 15 of the housing 12 of the air inlet silencer 10. A main flow outlet 17 for the main flow made of the first medium is formed in the region of one exterior wall 14 of the housing 12.

  An arrow 20 shown in FIG. 1 indicates the main flow of the first medium between the main flow inlet 16 and the main flow outlet 17 of the housing 12 of the inlet silencer 10. In FIG. 1, when flowing through the housing 12 of the inlet silencer 10, that is, when flowing through the inlet silencer 10, the first medium 20, and thus the main flow, from the direction of flowing in the substantially radial direction to the approximately axial direction. It is deflected in the outflow direction. In order to realize such a flow deflection, a suitable flow direction deflection element is arranged inside the housing 12 of the inlet silencer 10.

  The first medium is an air supply to be compressed by the compressor 11.

  The inlet silencer 10 according to the invention comprises a further flow guide element 18 for the second medium, which extends in the axial direction with respect to the inlet silencer 10 and thus the housing 12. The further flow guide element 18 for the second medium is provided with a further flow outlet 19. Since the further flow outlet 19 is arranged inside the housing 12 downstream of the flow deflection point of the first medium 20, it flows through the further flow guide element 18 and in the region of the further flow outlet 19. The second medium discharged from the first medium is mixed with the first medium downstream of the main medium in the flow direction of the first medium inside the housing 20.

  Preferably, the second medium is bypass air or an air-fuel mixture.

  A further flow guiding element 18 extends through the housing 12 in the middle of the housing 12, ie from the exterior wall 13 towards the exterior wall 14 and comprises a main flow outlet 17. Here, the longitudinal central axis 24 of the cylindrical housing 12 coincides with the longitudinal central axis 25 of the further flow guide element 18.

  A further flow outlet 19 of the further flow guiding element 18 is arranged inside the housing 12 upstream of the main flow outlet 17, parallel to the main flow outlet 17. Accordingly, the first medium and the second medium are mixed downstream of the main flow in the flow direction of the first medium and upstream of the main flow outlet 17, so that the first medium and the second medium are formed. The mixture is discharged from the inlet silencer 10 via the main flow outlet 17.

  As described above, the second medium 21 of the further flow flows through the further flow guide element 18 and the first medium of the main stream 20 circulates around the further flow guide element 18 in the region of the further flow outlet 19. .

  The further flow outlet 19 of the further flow guide element 18 comprises a flow path cross-sectional area D2 for the second medium of the further flow 21. In the plane of the further outlet 18, the inlet silencer 10 has a channel cross section free of obstacles with a first channel cross-sectional area D <b> 1 because of the main flow 20 consisting of the first medium. ing. In this embodiment, the ratio of the second channel cross-sectional area D2 to the first channel cross-sectional area D1 is preferably 0.02 to 0.09, preferably 0.03 to 0.08, particularly preferably. Is set to 0.035 to 0.075. Thereby, particularly advantageously, the two media of the main stream 20 and the further stream 21 can be mixed inside the inlet silencer 10.

  Accordingly, the first flow cross-sectional area D1 is significantly larger than the second flow cross-sectional area D2. Preferably, the flow cross-sectional area D2 of the further flow guide element 18 is constant along the direction in which the further flow guide element 18 extends inside the housing 12.

  The inlet silencer 10 according to the present invention eliminates the need for a further compressor housing. The inlet silencer 10 can be disposed at an angle to the compressor 11 of the exhaust gas supercharger.

  For this purpose, the vibrational behavior of a turbocharger attached to an internal combustion engine by utilizing a further compressor housing or pipe element with a radial gas supply pipe arranged between the compressor housing and the silencer. The adverse effect on can be eliminated. For this reason, the operation of the compressor can be optimized. Since there is no need to provide an additional compressor housing, the cost and installation space requirements are relaxed.

DESCRIPTION OF SYMBOLS 10 Inlet silencer 11 Compressor 12 Housing 13 Exterior wall 14 Exterior wall 15 Outer shell wall 16 Main flow inlet 17 Main flow outlet 18 Further flow guide element 19 Further flow outlet 20 First medium (main flow)
21 Second medium (further flow)
22 Compressor impeller 24 Longitudinal central axis (of housing 12) 25 Longitudinal central axis (of further flow guide element 18)

Claims (10)

A cylindrical housing (12) having an exterior wall (13, 14) disposed on the opposite side to each other and an outer shell wall (15) extending between the exterior walls (13, 14). ), A main flow inlet (16) formed in the region of the outer shell wall (15), and a main flow outlet (17) formed in the region of the exterior wall (14). A mouth silencer (10),
When the first medium flows between the main flow inlet (16) and the main flow outlet (17) through the inlet silencer (10), the first medium flows from the direction of flowing in the substantially radial direction to the substantially axial direction. In the inlet silencer (10), which is deflected in the outflow direction,
The inlet silencer (10) comprises a further flow guiding element (18) for the second medium;
A further flow outlet (19) is arranged inside the housing (12) downstream of the flow deflection point of the first medium, so that the second flow through the further flow guiding element (18). The medium is mixed with the first medium in the housing (12) downstream in the flow direction of the first medium.   The further flow guide element (18) for the second medium is arranged such that the longitudinal center axis of the further flow guide element (18) and the longitudinal center axis of the housing (12) coincide. The inlet silencer according to claim 1, characterized in that it extends in the direction of the longitudinal central axis of the housing (12) at the center of the housing (12).   3. Inlet silencer according to claim 1 or 2, characterized in that the flow of the first medium circulates around the further flow guiding element (18) in the region of the further flow outlet (19). The further flow outlet (19) of the further flow guiding element (18) comprises a second flow cross-sectional area (D2) for the second medium;
In the plane of the further outlet (18), the inlet silencer (10) is a channel cross section for the first medium free of obstructions, and has a first channel cross section (D1). ) Having the flow path cross section comprising
The ratio of the second channel cross-sectional area (D2) to the first channel cross-sectional area (D1) is 0.02 to 0.09. The inlet silencer according to one item.   The inlet according to claim 4, wherein a ratio of the second channel cross-sectional area (D2) to the first channel cross-sectional area (D1) is 0.03 to 0.08. Silencer.   The intake port according to claim 4, wherein a ratio of the second channel cross-sectional area (D2) to the first channel cross-sectional area (D1) is 0.035 to 0.075. Silencer.   The further flow outlet (19) is arranged in the housing (12) upstream of the main flow outlet (17) in a state parallel to the main flow outlet (17). The inlet silencer according to any one of claims 1 to 6. An inlet silencer comprising a compressor for compressing air supply and a turbine for expanding exhaust gas,
The energy extracted when expanding the exhaust gas inside the turbine is used to compress the intake air in the region of the compressor,
In the inlet silencer, wherein the supply air to be compressed is guided upstream of the compressor via the intake silencer for the supply air to be compressed,
The inlet silencer according to claim 1, wherein the inlet silencer is the inlet silencer according to claim 1.   The exhaust gas supercharger according to claim 8, wherein the first medium flowing between the main flow inlet (16) and the main flow outlet (17) is a supply air to be compressed.   10. An exhaust gas supercharger according to claim 8 or 9, characterized in that the second medium flowing through the further flow guide element (18) is compressor-bypass air or air / fuel mixture.

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