NL1040828B1 - A spiral turbine casing of a turbocharger. - Google Patents

Abstract

The invention relates to a spiral turbine casing comprising a spiral casing wall and a base wall. The base wall and the spiral casing wall have a connection which fully extends around a central axis, wherein a portion of the base wall is part of an inside surface of the spiral casing, said portion of the base wall has a curvature. The invention relates further to a turbocharger turbine comprising the above turbine spiral casing, and a turbocharger comprising such a turbocharger turbine.

Description

Title: A spiral turbine casing of a turbocharger

The invention relates to a spiral turbine casing, a turbocharger turbine, a turbocharger, the use of such a turbocharger and a method of manufacturing a turbine spiral casing. A spiral casing of a turbocharger turbine is for example known from DE-10.2004.039.477. The known turbocharger turbine is partly shown in appended figure 1. The spiral casing (10) comprises a base wall and a spiral casing wall. The base wall of the spiral casing is a base plate (15). The spiral casing is provided by welding the spiral casing wall (11) to the base plate (15) forming a connection between the spiral casing wall and the base plate. The weld (16) has a closed or endless form around the central axis of the turbine housing (10) . The base plate and the spiral casing wall are made of sheet metal, wherein the base plate in the known turbocharger turbine is a flat sheet metal plate with a constant thickness. The known turbocharger turbine comprises further a turbine wheel and an exhaust gas control device for controlling the exhaust gas flow from the spiral casing to the turbine wheel.

It is a drawback of the known turbocharger turbine that the spiral casing does not provide an optimal flow of the exhaust gasses inside the spiral casing.

Therefore, it is an object of the present invention to provide a relatively cost effective spiral casing having improved flow properties increasing the efficiency of the turbocharger turbine in use.

This object is achieved by a spiral turbine casing according to claim 1.

The spiral casing has a special designed base wall, in that inside the spiral casing a portion of the base wall has a curvature. This curvature inside the spiral casing optimizes in use the flow properties of exhaust gasses inside the spiral casing, e.g. optimizes the flow towards the central axis of the spiral casing. This central axis coincides with the central axis of a turbine wheel of a turbocharger turbine such that in use the turbine wheel can be driven more efficiently by means of the turbine spiral casing according to claim 1. Further, undesired turbulences inside the spiral casing can be reduced by means of the curvature. Such a spiral casing design improves the overall efficiency of the turbocharger turbine .

In a first embodiment the base wall has a varying thickness to provide the base wall curvature inside the spiral casing. The thickness of the base wall is measured in a (horizontal) direction extending parallel to the central axis. The base wall according to this embodiment requires a varying thickness of the base wall to provide an inside surface of the base wall having a curvature. For example, it is possible to provide such a curvature by gradually increasing the thickness of the base wall from the end of the base wall facing the central axis towards the connection. The side of the base wall opposite to the inside of the spiral casing can be flat or substantially flat. This flat side of the base wall can advantageously be used to connect the spiral casing to other parts of the turbocharger turbine or a bearing housing of a turbocharger.

In a second embodiment, the base wall is a base plate having a constant thickness. The base wall preferably extends in a longitudinal (vertical) direction and has vertically opposing ends, i.e. an end surface closer to the center axis of the spiral casing and an end surface further away of the center axis. The thickness corresponds to the width of the base plate measured in a (horizontal) direction extending transversally to the longitudinal direction, i.e. the width is the distance between the side surfaces which extend between the end surfaces. The base plate extends around the center axis of the spiral casing and has a disc or ring like shape with a through hole in the middle, wherein the center of the hole coincides with the center axis of the spiral casing. The radius of the through hole is larger than the distance between the vertically spaced end surfaces of the base wall. In this context constant thickness has to be understood as having a thickness that only varies due to manufacturing tolerances. The curvature of the base plate is provided by bending the base plate such that the outer side of the base plate wall opposite to the inner side of the spiral casing is also curved. Preferably, the base plate is a sheet metal plate, which can be bent relatively easily. The bent base plate provides additional advantages for assembling a turbine in a turbocharger, because the bent base plate can be used for clamping and/or to increase the contact pressure between parts of a turbocharger. In addition, the bend in the base plate can also be used to provide an pre-tensioned contact between the spiral casing and other components of a turbocharger turbine or turbocharger, i.e. by means of the bend in the base plate such a contact is more flexible and more resistant to thermal stresses experienced for example during warming up.

The walls or inner surface parts of the base wall and the spiral casing wall are substantially V-shaped towards the connection. Such V-shaped walls further optimize the flow properties of exhaust gasses inside the spiral casing. The inner surfaces of the spiral casing wall and the base wall towards the connection can be bent, wherein the curvature of the base wall may provide one bent wall part of the V-shape. In addition, the base wall may also have more than one radius of curvature .

The invention also relates to a turbocharger turbine comprising a turbine spiral casing as discussed above. The turbocharger turbine comprises an exhaust gas control device with a nozzle passage defined between a nozzle mount and a nozzle plate. The exhaust gas control device comprises a nozzle passage defined between a nozzle mount and a nozzle plate, wherein the dimensions of the nozzle passage can be varied by means of vanes to control an exhaust gas flow between the spiral casing and a turbine wheel. The base wall contacts the nozzle mount without being connected thereto. This contact provides a fluid tight connection between the nozzle mount and the base wall.

Further, the invention relates to a turbocharger comprising the above described turbine. Such a turbocharger has a compressor and between the turbine and the compressor a bearing housing. The turbine can be connected to the bearing housing by means of a clamping mechanism using a connecting element and a clamping element. Further, the exhaust gas control device in the turbocharger according to the present invention can be clamped between the bearing housing and the base wall by means of the clamping mechanism, i.e. the exhaust gas control device is clamped without being connected to other components of the turbocharger. Such clamping contact is more flexible and more heat resistant than a welded connection, i.e. the exhaust gas control device is supported by clamping, wherein the flexible clamping contact is able to withstand relative large temperature differences for a relative long period of time.

To explain the invention in more detail, exemplary embodiments thereof will hereinafter be described with reference to the accompanying drawings, wherein:

Figure 1 shows a part of a turbocharger according to the prior art in axial section;

Figure 2a shows schematically a part of a turbocharger according to a first embodiment in axial section;

Figure 2b shows schematically an enlarged view of a part of the turbocharger shown in figure 2a;

Figure 3 shows schematically a part of a turbocharger according to a second embodiment in axial section;

Figure 4 shows schematically a part of a turbocharger according to a third embodiment in axial section.

In this description, identical or corresponding parts have identical or corresponding reference numerals.

Figure 1 partly shows a turbocharger turbine known from the prior art. For a description of the known turbocharger turbine in detail reference is made to DE-10.2004.039.477. A part of a turbocharger 1 according to a first embodiment is shown in figures 2a and 2b showing a part of a turbocharger turbine 2 and a part of a bearing housing 3. The figures 3 and 4 show parts of a turbocharger 101; 2 01 according to a second and third embodiment. The turbine 2; 102; 202 comprises a single flow spiral casing 8, 108; 208.

The turbocharger turbine 2; 102; 202 comprises a turbine wheel (not shown), an exhaust gas control device 10; 210 and a spiral casing 8; 108; 208. The spiral casing 8; 108; 208 comprises a spiral casing wall 4; 104; 204 and a base plate 5; 205. The base plate 5 (figures 2a, b and 3) has a first end part 6 and a second end part 7, wherein the second end part 7 of the base plate 5 extends transversely to the central axis (not shown in figures 2a,b) of the turbine 2. The central axis of the turbine 2 corresponds to the dotted line 28 shown in figure 1. The central axis of the turbine 2 coincides with the central axis (not shown) of the spiral casing 8; 108; 208. The spiral casing 8; 108; 208 is provided by connecting a first bent end part 9; 109; 209 of the spiral casing wall 4; 104; 204 to the first end part 6; 206 of the base plate 5; 205 such that the spiral casing 8; 108; 208 has a connection 51; 251 between the spiral casing wall 4; 104; 204 and the base plate 5; 205. The connection 51; 251 fully extends around the central axis of the turbine 2; 102; 202.

The connection 51; 251 is provided by tungsten inert gas (TIG) welding and/or laser beam welding (LBW). The fully around the central axis extending endless form of the connection 51; 251 can be substantially circular. The inner surface 53 of the spiral casing wall 4; 104; 2 04 and the inner surface 55 of the base plate 5; 205 are V-shaped 57 towards the connection 51; 251. Inside the spiral casing 8; 108; 208 between the connection 51; 251 and the second end part 7; 207 of the base plate 5; 205 at least a portion of the base plate 5 has a curvature 61; 261. In the embodiments shown in figures 2a, b and 3, the curvature 61 of the inside surface 59 continues in a continuous or smooth way to the connection 51 such that the curvature 61 also provides one of the V-shaped wall parts towards the connection 51, i.e. the curvature 61 forms the inner surface 55 of the base plate 5. The V-shaped inner surfaces 53, 55 of the spiral casing wall 4 and the base plate 5 are bent.

The base plate 5; 205 has a first outer surface 62; 262, an opposite second surface 64; 264 which is located closer to the central axis than the first surface 62; 262 and two side surfaces 66, 68; 266; 268 extending between the first surface 62; 262 and the second surface 64; 264, wherein one of the two side surfaces is an outer side surface 68; 268 and a portion of the other side surface 66; 266 of the base plate 5; 205 extending between the connection 51; 252 and the other side surface 66; 266 is part of the inside surface of the spiral casing. In the embodiments shown in figures 2a, b and 3, the part of the inside surface of the spiral casing further comprises the second surface 64 of the base plate 5. In the embodiment shown in figure 4 the second surface 264 of the base wall 205 is positioned against a turbine element. The second end 2 07 of the base plate 205 has the curvature 261, i.e. the second end 207 does not extend transversely to the central axis .

The base plate 5; 205 has an edge 72; 272 between the second surface 64; 264 and the other side surface 66; 266 of the base wall, wherein a vertically extending first virtual plane (not shown) extends between the central axis and the edge 72; 272. The first virtual plane lies further from the center 95 inside the spiral casing than a second virtual plane extending between the connection and the central axis. In the embodiments shown in figures 2a, b and 4 the horizontal distance between the first virtual plane and the second virtual plane corresponds to two times the thickness of the base plate 5; 205. In the embodiment of the spiral casing 102 shown in figure 3 this distance is larger, wherein the maximum distance is two times smaller than the horizontal distance between the second virtual plane and the inside center 95 of the spiral casing 102. The distance D (figure 3) between the connection 51 and an inside surface 63 of the second end part 7 of the base wall 5 or the edge 72 corresponds to about five times the thickness of the second end part 7 of the base wall 5.

The exhaust gas control device 10; 210 of the turbocharger turbine 2; 102; 202 comprises a nozzle mount 79. The nozzle mount 7 9 is in the turbocharger according to the present invention clamped between the base plate 5; 205 and a turbine-side flange 77 of the bearing housing 3. By means of the curvature 61; 261 of the base plate 5; 2 05 a more flexible clamping can be achieved such that the thermal stresses due to the temperature differences in use can be compensated. Such flexible clamping provides a reliable fluid-tight sealing between the base plate 5; 205 and the nozzle mount 79. The nozzle mount 79 supports by means of supporting pins 80 a nozzle plate 82 (figure 2a). The nozzle mount 79 and nozzle plate 82 define a nozzle passage 84 for guiding gasses from the spiral casing 8 to a turbine wheel (not shown). The exhaust gas flow between the spiral casing and the turbine wheel can be controlled by means of vanes (not shown) varying the dimensions of the nozzle passage.

The bearing housing 3; 103; 203 of the turbocharger 1; 101; 201 houses a common shaft (not shown) connecting a compressor wheel (not shown) with the turbine wheel. The exhaust-gas-driven turbine 2; 102; 202 supplies the drive energy for the compressor. The bearing housing 3; 103; 203 comprises a compressor-side flange 71, a central section 73 which is integrally connected to the flange 71, and a turbine-side section 75 which has the turbine-side flange 77 which is integrally connected to the central section 73. The central housing section 73, the compressor-side flange 71 and the turbine-side flange 77 are formed in one piece. The turbine 2; 102; 202 is connected to the flange 77 by means of an annular clamping element 81. The bearing housing 3; 103; 203 and the turbine 2; 102; 202 differ from the turbocharger of the prior art shown for example in figure 1, in that the connection between the bearing housing 3, 103; 203 and the turbine 2; 102; 202 is different, in particular the design of the base plate 5; 205 and the design of the connecting element 85; 185. The connecting element 85; 185; 285 fully extends around the central axis of the turbine 2; 102; 202.

The connecting element 85; 185; 285 is preferably made of the same material as the base plate, i.e. sheet metal. The connecting element 85; 185; 285 can also be identified as upper casing.

The base plate 5; 205, the spiral casing wall 4; 104; 204 and the connecting element 85, 185; 285 are made from sheet metal having a thickness ^ 3 mm, preferably a thickness i 2 mm such as 1,5 mm. The thickness of the base plate 5 between the first end 6 and the second end 7 does not change neglecting manufacturing tolerances.

The connecting element 85; 185; 285 comprises: - a first end portion 87; 187; 287 to be clamped between the flange 77 and the clamping element 81; - a middle portion 89; 189; 289 and - a second end portion 91; 191, 291.

The middle portion 89; 189; 289 of the connecting element 85; 185; 285 preferably extends parallel to the central axis of the turbine 2; 102; 202 / turbocharger 1; 101; 201. The first end portion 87; 187; 287 preferably has an obtuse angle ε (figure 3) with the middle portion 89; 189; 289, preferably about 135 degrees. The second end portion 91; 191; 289 preferably extends transversely to the middle portion 89; 189; 289 of the connecting element 85; 185; 285. The angle β (figure 3) between the second end portion 91; 191; 2 91 and the middle portion 89; 189; 289 of the connecting element 85; 185; 285 may range between 45-315 degrees, preferably between 80-100 degrees (figure 3) or 260-280 degrees (figures 2a, b and figure 4). The connecting element 85 may also comprise an intermediate portion 93 between the middle portion 89 and the second end portion 91 as shown in figures 2a, 2b. The intermediate portion 93 may have a first angle η (figure 2b) with respect to the middle portion (or horizontal) of for example 45 degrees and a second angle φ (figure 2b) with respect to the second end portion 91 (or vertical) of for example 45 degrees. These angles may be varied to provide the angle β between the second end portion 91; 191 and the middle portion 89; 189 of the connecting element 85; 185 between 45-315 degrees. The second end portion 91 of the connecting element 85 shown in figures 2a, 2b extends at least partially parallel to the first end part 6 of the base plate and may be connected thereto, for example by welding. The second end portion 191 of the connecting element 185 shown in figure 3 extends at least partially parallel to the first end part 7 of the base plate 5 and may be clamped or connected thereto for example by welding. The second end portion 2 91 of the connecting element 285 shown in figure 4 extends at least partially parallel to a middle section 298 of the base plate 205 and is connected thereto for example by welding. By means of the connecting element 85; 185; 285 a reliable and relatively strong connection can be provided between the turbine 2; 102; 202 and the bearing housing 3; 103; 203. In addition, by means of the connecting element 85; 185; 285, the base plate 5; 205 and the clamping element 81 the nozzle mount 79 can be clamped between the second surface 264 of the base plate 205 (figure 4) or the outer side surface 64 of the base plate 5 and the turbine-side flange 7 7 of the bearing housing 3; 103; 203. By means of the curvature 61 of the base plate 5; 205 a relatively high contact force in a direction indicated by arrow PI (figure 2a) can be generated for clamping the nozzle mount 79. The nozzle mount 79 is advantageously clamped to withstand material expansion and material contraction due to temperature differences in use of the turbine 2; 102,- 202.

In the base plate 5 the maximum angle a between the ends of the legs of the V-shaped inner surfaces 57 is relatively large by means of the curvature 61 of the base plate 5. The maximum angle a (figure 3) is preferably smaller than 180 degrees. The maximum angle a is larger than 60 degrees, preferably larger than 90 degrees. Further, due to the shape of the spiral casing 8 the angle a will vary around the central axis of the turbine.

As shown in figures 2a, 2b, 3 and 4 the connected end portions 6, 9; 109; 209 of the spiral casing wall 4; 104; 204 and the base wall 5; 205 extend parallel to each other and extend transversely to the central axis of the turbine. This provides a reliable fluid tight seal and a strong connection between the base plate 5; 205 and the spiral casing wall 4; 104; 204. Preferably, the (vertical) length of the connected end portions 6; 9; 109; 209 is more than two times the thickness of the base plate 5; 205, preferably more than two and a half times the thickness of the base plate 5; 205.

Depending on the desired flow properties inside the spiral casing 8, it is possible to design a spiral casing 8 with an inner surface 55 of the base plate wall 5 being less continuous or being less smooth with the curvature 61 compared to the embodiments shown in figures 2a, 2b and 3. The base plate 205 shown in figure 4 is for example flat towards the connection 251.

The base plate 2 05 has a curved second end part 207, which provides the curvature 261 of the inside surface of the base plate 205.

Further, it is also possible that the curvature of the inside surface of the base wall may have more than one radius of curvature .

In another embodiment (not shown) the base wall is not a base plate, but a base wall having a varying thickness to provide the curvature of the inside surface. For example, in such an embodiment a side of the base wall opposite to the spiral casing can be flat or substantially flat, whereas the side facing the inside of the spiral casing comprises a curvature. Between the second and the first end, the thickness of the base wall at least partly varies to provide a curvature on the inside surface of the base wall. A flat or partly flat outer side of the base wall can be used to easily fix and/or connect the turbine to the bearing housing.

Turbocharger assembly comprising a bearing housing and a turbine, wherein the bearing housing and the turbine are connected by means of a connecting element 85; 185; 285, wherein the connecting element 85; 185; 285 is preferably made of sheet metal, wherein an end portion of the connecting element in contact with a base plate 5; 2 05 of a spiral casing has an angle β of 45-315 degrees with respect to a middle or center portion of the connecting element. In such a turbocharger assembly it is possible that the base plate has no curvature. Further, it is possible that the end portion is connected to the base plate for example by welding. In addition, the side of the connecting element opposing the base plate can be in contact with a nozzle mount of an exhaust gas control device for controlling the exhaust gas flow to the turbine. By means of a clamping element as indicated above with reference sign 81 it is possible to clamp the nozzle mount between the bearing housing and the base plate during assembling of a turbocharger.

Claims (26)

A spiral turbine shell comprising a spiral shell wall and a base wall, wherein the base wall and the spiral shell wall have a connection that extends completely around a central axis, a part of the base wall being a part of an inner surface of the spiral shell, part of the base wall has a curvature. The spiral casing of claim 1, wherein the base wall is a plate that has a constant thickness, for example, a thickness of approximately 1.5 mm, the curvature being provided by bending the plate. The spiral casing of claim 1, wherein the curvature is provided by varying the thickness of the base wall. Spiral sheath according to any of claims 1-3, wherein the base wall and / or the spiral sheath wall are made of sheet metal. 5. Spiral sheath according to any one of claims 1-4, wherein within the spiral sheath an inner surface portion of the base wall and an inner surface portion of the spiral sheath wall are V-shaped toward the joint, the curvature preferably being the shape of the inner surface portion of the base wall provided. The spiral casing of any one of claims 1-5, wherein the curvature has a variable curvature radius about the central axis. Spiral sheath according to any of claims 1-6, wherein the base wall extends completely around a central axis, which base wall a first surface, an opposite second surface that is closer to the central axis than the first surface and two side surfaces has which side surfaces extend between the first surface and the second surface, one of the two side surfaces being an outer surface and a part of the other side surface of the base wall extending between the joint and the second surface is part of the inner surface of the spiral casing. The spiral casing of claim 7, wherein the inner surface portion of the spiral casing is further provided with the second surface of the base wall. The spiral casing of claim 7, wherein the second surface of the base wall is positioned against a turbine element. A spiral casing according to any of claims 7-9, wherein the outer surface of the base wall is flat or substantially flat. 11. Spiral sheath as claimed in any of the claims 7-10, wherein the base wall has an edge between the second surface and a part of the other side surface of the base wall, wherein a first virtual plane extends between the central axis and the edge, wherein the first virtual plane is further from the center of the spiral envelope within the spiral envelope than a second virtual plane between the connection and the central axis, preferably the horizontal distance between the first virtual plane and the second virtual plane twice is smaller than the horizontal distance between the second virtual plane and the center of the spiral casing. A spiral casing as claimed in any one of claims 1 to 11, wherein the connection is provided with parallel extending connected parts of the spiral casing wall and the base wall. A spiral casing according to claim 12, wherein the connected parts of the spiral casing wall and the base wall extend transversely of the central axis. A spiral casing as claimed in any one of claims 1-13, wherein the spiral casing is a single-flow spiral casing. A turbocharger turbine assembly comprising a spiral shell according to any one of claims 1-14. The turbocharger turbine assembly of claim 15, wherein the turbocharger turbine assembly is provided with an exhaust gas control device for controlling an exhaust gas flow between the spiral casing and a turbine wheel. A turbocharger turbine assembly according to claim 16, wherein the exhaust gas control device is provided with a nozzle passage defined between a nozzle attachment and a nozzle plate, wherein the dimensions of the nozzle passage can be varied by means of blades to control an exhaust gas flow between the spiral casing and a turbine wheel. The turbocharger turbine assembly of claim 16 or 17, wherein the portion of the base wall contacts the nozzle mount without being connected to it. A turbocharger comprising a turbocharger turbine assembly according to any one of claims 15-18. The turbocharger according to claim 19, wherein the turbocharger has a bearing housing, the bearing housing being connected to the turbocharger turbine by means of a clamping mechanism. A turbocharger according to claim 20 and comprising a turbocharger turbine assembly according to claim 16, wherein the exhaust gas control device is clamped between the base wall and the bearing housing by means of the clamping mechanism. Turbo charger according to claim 20 or 21, wherein the clamping mechanism is provided with: a connecting element, preferably the connecting element extends completely around the central axis; a clamping element for clamping the connecting element with the bearing housing, preferably the clamping element extends completely around the central axis. A turbocharger according to claim 22, wherein the connecting element is provided with: a first end part to be clamped by the clamping element with the bearing housing; a middle part and; a second end part that is connected or clamped to the base wall. A turbocharger according to claim 22 or 23, wherein the connecting element is made of sheet metal and / or the clamping element is made of sheet metal. Use of a turbo charger according to any one of claims 19-24. Method for manufacturing the spiral turbine housing according to any of claims 1-14, wherein the connection is provided with tungsten inert gas (Tungsten Inert Gas (TIG)) welding and / or laser beam welding (Laser Beam Welding (LBW) ).