JP5021846B2 - Support ring of guide device having shut-off air passage - Google Patents

Description

The present invention relates to the field of guide devices for fluid machines, in particular for exhaust gas turbocharger turbines for supercharged internal combustion engines.
The present invention relates to a fluid comprising a support ring of a guide device having a plurality of adjustable guide blades, a guide device having such a support ring, and such a guide device having such a support ring. Related to machinery.

  An exhaust gas turbocharger is used to increase the output of an internal combustion engine (reciprocating engine). The exhaust gas turbocharger includes an exhaust gas turbine provided in an exhaust gas flow of the internal combustion engine and a compressor provided in an intake passage (Ansaugtrakt) of the internal combustion engine. The turbine wheel of the exhaust gas turbine is rotated by the exhaust gas flow of the internal combustion engine, and the rotating wheel of the compressor is driven by the shaft. The compressor increases the pressure in the intake passage of the internal combustion engine. Therefore, during intake, a larger amount of air reaches the combustion chamber than in an internal combustion engine without a compressor. Exhaust gas turbochargers are also used as power turbines. In this case, the exhaust gas turbocharger does not drive the compressor of the exhaust gas turbocharger via the shaft, and another mechanical power supply unit drives the generator via the coupling.

  Recent developments in modern reciprocating engines are facilitated by reduced exhaust, cost and fuel consumption. In this case, the engine supercharging system contributes particularly to the achievement of the development goals. In the past, exhaust gas turbochargers with turbine components and compressor components having a fixed geometry were used in the case of large engines. These geometries were designed for individual engines and adapted to engine standards. However, the geometry does not change during engine operation. In the future, the use of adjustable (or variable) turbine geometry (VTG) during operation will be increasingly discussed to allow a better adaptation of the exhaust gas turbocharger to the operating engine. .

  In this case, the opening of the guide blade of the guide device of the exhaust gas turbine is changed by the rotation of the guide plate. The use of adjustable turbine geometry has become widespread in the prior art and in particular in the area of small engines used, for example, in passenger cars. For large engines, already today, variable turbine geometries are used for gas engines that require precise control of the fuel to air ratio. In the future, the use of variable turbine geometries is expected for large engines.

  In an exhaust gas turbocharger having a variable turbine geometry, to prevent exhaust gas from the internal combustion engine from entering the mounting location of the guide blade of the guide device and to eliminate leakage of exhaust gas to the environment Therefore, it is necessary to supply shut-off air to the guide device.

  In the conventional guide device, the shut-off air is guided into an annular passage provided in the cross-sectional profile of a supporting housing ring of the guide device, hereinafter referred to as a support ring. In the case of casting of the support ring, a casting core is necessary because of this annular passage. This increases the cost of the casting process. Furthermore, the cross section of the shut-off air passage is relatively small due to the limited space conditions inside the support ring profile. In order to achieve a uniform supply of shut-off air, air must therefore be supplied to several locations. For this purpose, other special tubes are required in addition to the guide device.

  An object of the present invention is to provide a support ring manufactured at low cost for a guide device of a liquid machine.

  This is because, according to the present invention, the shut-off air passage for preventing gas from entering the mounting position of the guide plate of the guide device from the flow path is designed as a groove that opens outward and extends in the circumferential direction. This is achieved by means of a support ring which has been made.

  In the support ring for the guide device through which the exhaust gas flows in the axial direction, the groove is in this case formed in the axial end face of the support ring. In the guide device through which exhaust gas flows in the radial direction, the groove is formed on a circumferential surface on the outer side or the inner side in the radial direction. When the shut-off air passage is formed in the support ring as an open groove, this allows the support ring to be cast without a core for the shut-off air passage.

  According to the invention, the shut-off air passage formed in the axial end face or circumferential surface of the support ring is sealed by a gas inlet housing and / or other housing parts, such as a cover ring, on the open side of the passage.

The shut-off air passage of the support ring formed in accordance with the invention is so large that it can supply all the shut-off air to only one location along the circumference because of the outer region in the cross-sectional profile Has a surface. This makes it possible to dispense with distribution pipes and requires a smaller number of mechanical processing of the support ring.
Other advantages are apparent from the dependent claims.

1 shows an overall view of an exhaust gas turbocharger based on the prior art. 1 shows a cross-sectional view of an exhaust gas turbine having an adjustable guide device through which exhaust gas flows axially according to the prior art. 1 shows a cross-sectional view of an exhaust gas turbine with a guide device with an axially extending exhaust gas having a support ring formed according to the invention and adjustable; FIG. Fig. 4 shows an axial view of the support ring formed according to the invention and shown in Fig. 3; FIG. 5 shows a cross-sectional view of the support ring shown in FIG. 4 extending along VV. FIG. 3 shows a cross-sectional view of a support ring formed according to the invention of a guide device through which exhaust gas flows in the radial direction.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 shows a conventional exhaust gas turbocharger having an exhaust gas turbine 20 and a compressor 10 and a bearing housing 50 provided therebetween. The exhaust gas turbine 20 has a gas inflow housing 21. Through this gas inlet housing, hot exhaust gas flows towards the turbine wheel and drives the turbine wheel. The exhaust gas is then supplied to the exhaust system through the gas outlet housing 22. The turbine wheel is provided at one end of a shaft that can rotate about the axis A, and this shaft is rotatably attached to the bearing housing 50. At the other end of the shaft is a compressor wheel. The compressor wheel compresses air drawn through the air inflow housing 11. Air is then collected in an air outlet housing and supplied to the combustion chamber of the internal combustion engine.

  In the illustrated embodiment, the turbine is an axial turbine that is axially exposed to the exhaust gas flow. Instead, the exhaust gas could be sent to the turbine wheel in a strictly radial direction or in a slightly inclined direction with respect to the radial direction. In this case, a radial turbine or a mixed flow turbine is mentioned.

  FIG. 2 is a sectional view of an axial turbine of a conventional exhaust gas turbocharger. The turbine wheel 25 is provided on a shaft 30 attached to the bearing housing 50 so as to be rotatable about the axis A. The turbine wheel 25 has a large number of rotating blades 26. These rotating blades are provided along the periphery of the turbine wheel at the radially outer edge of the turbine wheel. The exhaust gas flow in the flow path from the gas inlet housing 21 to the gas outlet housing 22 is indicated by arrows in each figure. The rotating blades of the turbine wheel are exposed to the exhaust gas flow in the axial direction.

  An adjustable guide device (adjustable turbine geometry) is provided upstream of the rotating blade 26. This adjustable guide device comprises a number of guide blades 41 each having one shaft 42. Each shaft 42 of each guide blade 41 is attached to the housing so as to be rotatable about the axis B. The housing of the guide device has a support ring 40 surrounding the flow path in an annular shape. The support ring 40 can surround the cover ring 45 toward the flow path. The shaft 42 of the guide blade 41 is provided in and attached to the support ring 40 in a hole provided for attachment purposes. These attachment points extend substantially in the radial direction like the shaft 42 of the guide blade 41. The support ring 40 is usually fixed to the gas outflow housing 22 and / or the gas inflow housing 21 by fixing means. As the fixing means, a bolt, a screw, or a seam plate is used.

  The adjustable guide device further comprises an adjustment ring 43 and one adjustment lever 44 per guide blade. Each adjustment lever extends to the shaft 42 through an opening 49 in the support ring. In order to adjust the guide device, the adjustment ring 43 is moved in the circumferential direction. The adjusting lever 44 transmits the rotational movement to the shaft 42 of the guide blade. In order to prevent the exhaust gas from flowing into the mounting position of the guide blade 41 and to prevent the exhaust gas from leaking to the environment, the support ring 40 is provided with a shut-off air passage 46. In that case, the shut-off air is supplied at one or more points in the shut-off air passage 46 which extends annularly inside the profile of the support ring 40 and passes through the opening for the shaft of the guide blade. To flow.

  In the case of the support ring formed according to the invention and shown in FIG. 3, the openings 48 for holding and mounting the shaft 42 of the guide blade 41 are likewise connected via a shut-off air passage 46. , The cutoff air is supplied. The shut-off air passage 46 is sealed with a sealing element 47 with respect to the opening 49 through which the adjustment lever 44 is passed. Therefore, no shut-off air leaks along the guide blade shaft in this direction. According to the present invention, the shut-off air passage 46 is a groove formed in the axial end face of the support ring 40 as shown in the schematic view of the guide device shown in FIGS. 4 and 5 through which exhaust gas flows in the axial direction. It is designed as.

  In the assembled state, the shut-off air passage 46 is defined by the housing part 22 adjacent to the axial end face. Thus, because of the shut-off air passage 46 formed in the support ring 40 as a groove, an annular cavity is created in the assembled state. In order to expand the cross section of the shut-off air passage, an axially open groove 23 may be formed on the housing side. In this case, the cutoff air passage is constituted by a cutoff air passage 46 on the support ring side and a groove 23 on the housing side.

  The contact surface between the support ring and the adjacent housing part may be flat, diagonal or stepped in the area of the shut-off air passage.

  As an option, a groove 23 extending the shut-off air passage extends to the area of the cover ring 45 on the housing side. This further expands the cross section.

  As an option, the shut-off air passage can be sealed by a sealing element 47 provided radially inside and / or outside the shut-off air passage. Accordingly, the shut-off air supplied to the shut-off air passage 46 due to the overpressure is prevented from escaping through the connection point between the gas outflow housing 22 and the support ring 40.

  As an option, the groove forming the shut-off air passage 46 may be formed on the end face of the support ring 40 facing the gas inflow housing 21.

  As an option, the plurality of grooves forming the shut-off air passages are formed as annular groove segments in the support ring and / or the adjacent housing, and thus may be divided into a plurality of parts along the circumferential surface. good. In this case, each annular groove segment can be individually supplied with shut-off air from the outside.

  FIG. 6 shows a cross section of a guide device through which exhaust gas flows in the radial direction and is used, for example, in a radial turbine or a mixed flow turbine. In this case, according to the present invention, the shut-off air passage 46 is formed in the support ring by a groove that opens radially outward or radially inward. This groove forming the shut-off air passage 46 is thus formed in the peripheral surface of the support ring 40. The limitation of the groove to the annular cavity is made by the adjacent housing part. In the case of an exhaust gas turbine, the housing part would be, for example, the gas inlet housing 21. Similarly, in order to extend the shut-off air passage 46 to the adjacent housing portion, the peripheral groove 23 may be formed.

  In the schematic views shown in FIGS. 4, 5 and 6, an adjustment lever for adjusting the guide blade is not drawn.

  The detailed embodiment shows a guide device having a support ring formed according to the invention as an adjustable guide device for an exhaust gas turbine. However, all features are intended to apply to general applications in any fluid engine, particularly compressors.

  DESCRIPTION OF SYMBOLS 10 ... Compressor, 11 ... Air inflow housing of compressor, 12 ... Air outflow housing of compressor, 20 ... Exhaust gas turbine, 21 ... Gas inflow housing of exhaust gas turbine, 22 ... Exhaust gas turbine gas outlet housing, 23 ... groove formed in exhaust gas turbine housing, 25 ... turbine wheel, 26 ... turbine wheel rotating blade, 30 ... exhaust gas turbocharger Shaft, 40 ... Guide device support ring, 41 ... Guide blade (adjustable), 42 ... Guide blade shaft, 43 ... Adjustment ring, 44 ... Adjustment lever, 45 ... Cover ring, 46 ... shut-off air passage formed in support ring, 47 ... sealing element, 48 ... guy An opening for holding and attaching the shaft of the blade, 49... An opening for passing the adjusting lever, 50... A bearing housing for attaching the shaft of the exhaust gas turbocharger, A.・ Axis of turbocharger shaft, B ... Axis of guide blade shaft.

Claims (14)

A support ring (40) of a guide device having a plurality of adjustable guide blades (41),
The support ring surrounds the flow path in an annular shape, and the support ring holds the shaft (42) of the guide blade provided in the flow path, and an opening (48) for rotatably mounting, A shut-off air passage (46) for supplying shut-off air to the guide device,
The shut-off air passage (46) is formed on the outer surface of the support ring (40) as a groove that opens outward and extends in the circumferential direction,
The blocking air passage (46) leads to an opening (48) for holding and rotatingly mounting the shaft (42) for the plate, so that blocking air is formed in the support ring. From the groove, it flows into the flow path through the opening (48) formed in the support ring (40) and for holding and rotatably mounting the shaft (42) for the blade. thing,
Support ring characterized by.   The support ring according to claim 1, wherein the shut-off air passage (46) is divided into a plurality of annular groove segments along a circumference. A guide device having a plurality of adjustable guide blades (41),
The guide blades (41) each have a shaft (42) which is rotatably mounted in an opening (48) of the support ring (40) according to claim 1 or 2, respectively. A guide device . The guide device according to claim 3,
The shut-off air passage (46) is formed in the axial end surface of the support ring (40) as a groove that is open in the axial direction and extends in the circumferential direction, and the guide device through which exhaust gas flows in the axial direction. . The guide device according to claim 3,
The guide air passage (46) is formed in a circumferential surface of the support ring (40) as a groove that is open in the radial direction and extends in the circumferential direction, and the exhaust gas flows through in the radial direction . A fluid machine comprising a housing (22) and a guide device according to claim 4, comprising:
An end surface of the support ring (40) having the shut-off air passage (46) is formed on the housing (22) of the fluid machine such that the housing (22) defines the shut-off air passage (46) in the axial direction. ) Fluid machinery.   The housing (22) in the region of the boundary in the axial direction of the shut-off air passage (46) is open in the axial direction and towards the shut-off air passage (46) of the support ring (40). 7. A fluid machine according to claim 6, wherein a directionally extending groove (23) is formed. A fluid machine comprising a housing (21) and a guide device according to claim 5,
The peripheral surface of the support ring (40) having the shut-off air passage (46) is arranged so that the housing (21) divides the shut-off air passage (46) in the radial direction. 21) Fluid machinery.   The housing (21) in the region of the boundary in the axial direction of the shut-off air passage (46) is open in a radial direction and toward the shut-off air passage (46) of the support ring (40). 9. A fluid machine according to claim 8, wherein a directionally extending groove (23) is formed.   A fluid machine comprising a housing (2) and a guide device according to claim 3, wherein the shut-off air passage (46) is sealed in a transition region between the support ring (40) and the housing of the fluid machine. In order to do so, a fluid machine provided with a plurality of sealing elements (47).   An exhaust gas turbine comprising the guide device according to claim 3.   A compressor having the guide device according to claim 3.   An exhaust gas turbocharger comprising the exhaust gas turbine according to claim 11.   An exhaust gas turbocharger comprising the compressor according to claim 12.

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