Subject matter disclosed herein relates generally to exhaust turbines for turbochargers for internal combustion engines.
An exhaust system of an internal combustion engine can include a turbine wheel set in a turbine housing to create backpressure. In such a system, as the pressurized exhaust passes through the turbine housing (e.g., en route to an atmospheric outlet), the turbine wheel harnesses energy as the exhaust expands.
Various parameters may characterize a turbine wheel or a turbine housing. For example, a parameter known as “A/R” (e.g., area divided by radius) describes a geometric characteristic of a turbine housing where a smaller NR may increase velocity of exhaust directed to a turbine wheel and provide for increased power of a turbocharger at lower engine speeds (e.g., resulting in a quicker boost rise from a compressor). However, a small A/R may also cause exhaust flow in a more tangential direction, which can reduce flow capacity of a turbine wheel and, correspondingly, tend to increase backpressure. An increase in backpressure can reduce an engine's ability to “breathe” effectively at high engine speeds, which may adversely affect peak engine power. Conversely, use of a larger A/R may lower exhaust velocity. For a turbocharger, lower exhaust velocity may delay boost rise from a compressor. For a larger A/R turbine housing, flow may be directed toward a turbine wheel in a more radial fashion, which can increase effective flow capacity of the turbine wheel and, correspondingly, result in lower backpressure. A decrease in backpressure can allow for increased engine power at higher engine speeds.
As a turbine housing and turbine wheel can create backpressure in an exhaust system, opportunities exist for exhaust leakage. For example, during operation of a turbine, a turbine housing space is at a higher pressure than its environment. Also, since exhaust gas expands across a turbine wheel, pressure downstream of the turbine wheel is considerably lower than that of a turbine housing volute region. Hence, in the foregoing example, two possible regions may exist for exhaust leakage.
For example, exhaust leakage may be of a type that leaks out of an exhaust system to the environment or of a type that remains within an exhaust system yet bypasses a turbine wheel space. As to the latter, such leakage may occur between components of an exhaust turbine, for example, where the components may expand, contract, experience force, etc., as operational conditions vary. Further, where cycling occurs (e.g., as in vehicles), components may wear, become misaligned, etc., as cycle number increases. Whether external or internal, leakage can alter performance of a turbine wheel and turbine housing assembly. For example, a leaky turbine housing may not perform according to its specified A/R, which can complicate engine control, control of a variable geometry mechanism, etc. Various technologies and techniques described herein are directed to seals and sealing that can reduce leakage of exhaust, for example, within a turbine assembly.
A more complete understanding of the various methods, devices, assemblies, systems, arrangements, etc., described herein, and equivalents thereof, may be had by reference to the following detailed description when taken in conjunction with examples shown in the accompanying drawings where:
As described in various examples, exhaust leaks may occur in a turbine assembly. For example, exhaust may leak between two components of a turbine assembly such that the leaked exhaust bypasses a turbine wheel space. Where the leaked exhaust passes from a volute of a turbine assembly to an outlet of the turbine assembly, without passing through a turbine wheel space, the efficiency of the turbine assembly may decrease. Where components of a turbine assembly expand, contract, experience force, etc., exhaust leakage may vary and make turbine performance less predictable. Where a turbine wheel drives a compressor wheel to charge intake air for an internal combustion engine, variations in exhaust leakage can impact predictability of engine performance.
As described herein, to mitigate exhaust leakage a turbine assembly may include a seal. For example, a turbine assembly for a turbocharger can include a turbine wheel with a base, a nose, blades, and a rotational axis that extends from the base to the nose; a turbocharger shaft operatively coupled to the turbine wheel; an annular component that includes an opening that receives at least a portion of the turbine wheel; a shroud component that includes an axis aligned with the rotational axis of the turbine wheel and an annular portion and a cylindrical portion that include an outer surface and an inner shroud surface where the outer surface includes a lower axial face and an upper axial face; mounts that extend from the annular component to locations at the shroud component where the mounts form an axial clearance between the annular component and the shroud component; a turbine housing that includes an axis aligned with the rotational axis of the turbine wheel, a lower axial face, an upper axial face and an inner surface that extends between the lower axial face and the upper axial face; and a C-shaped seal that includes an inner diameter, an outer diameter, an axis aligned parallel to the rotational axis of the turbine wheel, a lower lip that contacts the lower axial face of the outer surface of the shroud component along the annular portion of the shroud component, an upper lip that contacts the lower axial face of the inner surface of the turbine housing, and a wall portion that extends between the lower lip and the upper lip.
In the foregoing example, the seal may be deformable responsive to loading. Such deformability may allow the seal to seal a space between two components over a wide range of conditions. For example, a seal may deform responsive to force due to expansion or contraction of one or more components resulting from heating or cooling. As another example, a seal may deform responsive to axial thrust forces that occur during operation of an exhaust turbine (e.g., as in a turbocharger). As yet another example, a seal may deform in response to a load or loads applied to one or more components of a turbine assembly or a turbocharger assembly during an assembly process. In such an example, a bolt or other mechanism may be torqued according to a torque specification that results in a load (e.g., a “pre-load”) being applied to a seal seated between two or more components of an assembly.
As an example, where a turbine assembly includes a shroud component, deformation of the shroud component may affect performance. For example, if an inner shroud surface deforms, a clearance or clearances between blades of a turbine wheel and the inner shroud surface may change. As an example, such changes may impact fluid dynamics of exhaust, which may decrease performance, increase noise, vibration, etc. In an assembly, a shroud component may be subject to various forces. For example, a seal may contact a shroud component and contact a turbine housing such that force applied to the shroud component is transmitted to the turbine housing via the seal. Depending on the stiffness of the seal, such force may act to deform the shroud component. The type of deformation, risk of deformation, etc. may depend on where such a shroud component is supported with respect to where it contacts such a seal. For example, where distances between locations of mounts that support a shroud component and contact locations of a seal with the shroud component increase, a risk of deformation may increase. As an example, a seal may be configured and located in an assembly to achieve distances between locations of mounts that support a shroud component and contact locations of the seal with the shroud component that act to reduce risk of deformation of the shroud component. For example, a seal may be configured with axially aligned upper and lower lips that contact a turbine housing and a shroud component respectively within a radial distance from a mount location (e.g., to more effectively transmit axial forces to a mount at that location). As an example, a seal may include a lower lip that is located axially closer to a mount location for a shroud component than an upper lip (e.g., the lower lip may be disposed at a radius greater than that of the upper lip). As an example, a seal may include an elongated C-shape, an offset C-shape (e.g., with radially offset upper and lower lips), or other shape that may include an upper lip, a lower lip and an inwardly curving wall between the upper lip and lower lip.
As a particular example, a seal may be positioned between a cartridge and a turbine housing of a variable geometry turbine assembly (e.g., consider a VGT assembly or a variable nozzle turbine “VNT” assembly). In such an example, the cartridge may include a shroud component and an annular component spaced axially by mounts where vanes are accommodated to control exhaust flow from a volute to a turbine wheel space. As an example, a vane may include a trailing edge and a leading edge with a pressure side airfoil and a suction side airfoil that meet at the trailing edge and the leading edge. Such a vane may have a planar upper surface and a planar lower surface where a clearance exists at least between the planar upper surface and the shroud component (e.g., between a lower planar surface of an annular portion of the shroud component). As an example, each vane may include an axis about which the vane may pivot (e.g., a pivot axis). As an example, each vane may include a post (e.g., or axel) that defines a pivot axis. In such an example, movement of a vane (e.g., arcwise) may be less closer to the pivot axis and greater further away from the pivot axis. For example, a trailing edge or a leading edge may be disposed a distance from the pivot axis such that upon pivoting of a vane, the leading edge and/or the trailing edge sweeps a maximum arc of the vane for a desired amount of pivoting. If clearance between an upper surface of a vane and a shroud component is diminished, the vane may bind, where the risk may increase depending on arc length as interaction area can increase with respect to arc length. In such an example, deformation to a shroud component may cause a vane or vanes to bind upon pivoting or even in a static position. Binding can result in loss of control, stress to a control mechanism, wear, etc.
As an example, a seal may be positioned in an assembly to reduce risk of deformation to a component such as a shroud component such that the seal can thereby reduce risk of vane sticking, binding, friction, etc. For example, where a shroud component is supported by mounts, a seal may contact the shroud component proximate to locations of such mounts on the shroud component. As an example, mount locations may be radially outward from a turbine wheel space (e.g., a shroud contour) as the mounts may interfere with exhaust flow, vane pivoting, etc. For example, as vanes may be shaped to provide a particular flow profile, locating mounts upstream (e.g., upstream of leading edges of the vanes) may have a lesser impact on flow to a turbine wheel space compared to locating mounts downstream (e.g., downstream of trailing edges of the vanes). In such an example, the shroud component may be supported near an outer radius (e.g., outer diameter), which may allow for flexing, deformation, etc. of portions interior thereto. Given such examples of constraints, a seal may be configured to contact a shroud component close to mount locations. Alternatively or additionally, a seal may be configured to contact a shroud component close to vane pivot axes such that force is transferred to a portion of a shroud component where vanes sweep smaller arcs.
As an example, another factor, which may give rise to a constraint, is the overhang of a turbine housing. For example, where a turbine housing has a small radial overhang (e.g., small annular lower axial face), an ability to position a seal toward a mount location or a vane pivot axis location may be limited.
While various examples of factors, constraints, etc. are described with respect to vane pivoting, shroud deformation, etc., a seal may likewise be constrained by factors as to sealing. As an example, a C-shaped seal may be configured for sealing as well as reducing risk of shroud deformation, for example, by including lower contact points that may be positioned radially outwardly from a cylindrical portion of a shroud component and where upper contact points may be directly, axially above the lower contact points or, for example, where lower contact points may be radially offset from the upper contact points (e.g., located radially outward from the upper contact points such that the upper lip is not axially above the lower lip). In such examples, the C-shaped seal may include a wall portion that extends radially inwardly from the upper and lower contact points, for example, to define a minimum diameter of the C-shaped seal. Such a wall portion may include a radius, for example, that allows for compression of a lower lip of the seal that forms the lower contact points with respect to an upper lip of the seal that forms the upper contact points.
As an example, a C-shape may be elongated, for example, to position contact points radially outwardly from a turbine wheel and more closely to, for example, shroud component mount locations. As an example, an elongated C-shape may be defined with respect to an aspect ratio. For example, a C height may be less than a C width such that the C-shape is elongated in width (e.g., width to height aspect ratio greater approximately one). As an example, an elongated C-shaped seal (e.g., a type of C-shape) may have a width to height aspect ratio greater than about 1.1. As an example, an elongated C-shaped seal may have a width to height aspect ratio of approximately 1.2. As an example, where one lip is at a diameter that is greater than another lip, the larger diameter may, for example, be used to define in part an aspect ratio (e.g., consider an elongated C-shaped seal with radially offset lips).
As an example, a seal may provide for a better stack up of components, for example, to reduce a turbine/cartridge differential expansion ratio leading to less compression/decompression of the seal. As an example, to locate a seal radially outwardly (e.g., closer to a mount, vane pivot axis, etc.), a seal may include an outer diameter that is a large percentage of a mount location diameter for a shroud component (e.g., approximately 75 percent or more). In such an example, contact area may also be increased, which may provide for a flexible seal configuration (e.g., seal shape). As mentioned, as an example, a C-shaped seal may be elongated and positioned radially outwardly between a shroud component and a housing; whereas, for example, if a seal is constrained to a smaller region (e.g., radially inward), elongation may not be possible or practical (e.g., it may be limited to a smaller width to height aspect ratio). As an example, a seal may provide for better localization of loading transmission (e.g., closer to spacers, mounts, etc.), for example, which for a given load may decrease the potential deformation of a shroud component (e.g., conical or other form of deformation). As an example, a seal may be configured and positioned to reduce bending force on a shroud component, a spacer, etc., for example, to help avoid flexure of the shroud component and, for example, binding of vanes.
As an example, a seal may act to maintain performance predictability of a turbine or turbocharger by withstanding bulk temperatures of approximately 800° C. and pressure differentials (ΔPmax) of approximately 300 kPa. Such a seal may result in lower leak rates than a piston ring approach, which may have a leak rate of approximately 15 to approximately 30 l/min under a pressure differential of approximately 50 kPa. As an example, a seal may provide for lower stack-up limits (e.g., axial stack-up of components) and may comply with thermal evolution/growth during operation (e.g., and temperature cycling). As an example, a seal may be implemented without alteration to existing components (e.g., in terms of structure). For example, where a slot or slots exist for one or more piston rings, a seal may be positioned in a manner where the slot or slots do not alter sealing ability of the seal. As an alternative example, one or more components may be manufactured without machining or otherwise forming one or more slots.
As to pressure differentials and temperatures in a variable geometry turbine assembly, as an example, exhaust in a volute may have pressure in a range of approximately 120 kPa to approximately 400 kPa and possible peak pressure of up to approximately 650 kPa (absolute) and temperature in a range of approximately 200 degrees C. to approximately 830 degrees C. and possible peak temperature of up to approximately 840 degrees C.; whereas, at a location downstream blades of a turbine wheel, exhaust may have pressure in a range of approximately 100 kPa to approximately 230 kPa (absolute) and temperature in a range of approximately 100 degrees C. to approximately 600 degrees C. As described herein, as an example, a seal may be made of a material and be configured to withstand pressures and temperatures in such ranges. For example, a seal may be made of a material such as the INCONEL® 718 alloy (Specialty Materials Corporation, New Hartford, N.Y.). The INCONEL® 718 alloy includes nickel (e.g., 50-55% by mass), chromium (e.g., 17-21% by mass), iron, molybdenum, niobium, cobalt, aluminum and other elements. Some other examples of materials include INCONEL® 625, C263 (aluminum-titanium age hardening nickel), René 41 (nickel-based alloy), WASPALOY® alloy (age hardened austenitic nickel-based alloy, United Technologies Corporation, Hartford, Conn.), etc. As an example, a seal may be shaped via a stamping process (e.g., for shaping material provided as a sheet, optionally from a roll).
As an example, a seal may be configured for ease of assembly, optionally without any specialized jigs, tools, etc. As an example, upon assembly (e.g., at ambient or room temperature), a seal may be positioned between two or more components and loaded to exert a particular force on a cartridge (e.g., X N) in a first axial direction where another load may be applied to the cartridge (e.g., Y N) by another component in a second, opposing axial direction, for example, to help maintain axial location of the cartridge. In such an example, the load Y applied to the cartridge by the component exceeds the load X applied to the cartridge by the seal (e.g., |Y|>|X|). In such an example, the resulting load on the cartridge (e.g., at ambient or room temperature) may be determined as |Y| minus |X|, in the direction of Y. The resulting load on the cartridge may help maintain its axial location in a turbine assembly (e.g., or in a turbocharger assembly). During operation, for example, where temperature and exhaust pressure are acting simultaneously, the load exerted by the seal may diminish and, in turn, the resulting load experienced by the cartridge may increase.
As an example, a seal may undergo a negligible level of plastic strain during operation (e.g., at an exhaust temperature of approximately 800 degrees C.). As to a duty cycle of a turbocharger, temperature may vary from approximately 200 degrees C. to approximately 800 degrees C. where load may vary correspondingly. As an example, a seal may offer near linear stiffness during thermal cycling (e.g., for an expected duty cycle).
Below, an example of a turbocharged engine system is described followed by various examples of components, assemblies, methods, etc.
Turbochargers are frequently utilized to increase output of an internal combustion engine. Referring to
The turbocharger 120 acts to extract energy from the exhaust and to provide energy to intake air, which may be combined with fuel to form combustion gas. As shown in
In the example of
In the example of
In
The turbine assembly 260 further includes a variable geometry assembly 250, which may be referred to as a “cartridge”, that is positioned using a flange 270 (e.g., optionally shaped as a stepped annular disc) that clamps between the housing 280 and the turbine housing 262, for example, using bolts 293-1 to 293-N and a heat shield 290 (e.g., optionally shaped as a stepped annular disc), the latter of which is disposed between the cartridge 250 and the housing 280. As shown in the example of
As an example, vanes (see, e.g., a vane 255) may be positioned between the shroud component 252 and the annular component 270, for example, where a control mechanism may cause pivoting of the vanes. As an example, the vane 255 may include a vane post 275 that extends axially to operatively couple to a control mechanism, for example, for pivoting of the vane 255 about a pivot axis defined by the vane post 275. As an example, each vane may include a vane post operatively coupled to a control mechanism. In the example of
As to exhaust flow, higher pressure exhaust in the volute 266 passes through passages (e.g., a nozzle or nozzles) of the cartridge 250 to reach the turbine wheel 264 as disposed in a turbine wheel space defined by the cartridge 250 and the turbine housing 262. After passing through the turbine wheel space, exhaust travels axially outwardly along a passage 268 defined by a wall of the turbine housing 262 that also defines an opening 269 (e.g., an exhaust outlet). As indicated, during operation of the turbocharger 200, exhaust pressure in the volute 266 (PV) is greater than the exhaust pressure in the passage 268 (PO).
As shown in two enlarged views of the example of
In the example of
As an example, the seal 300 may be defined as having a C-shape or a U-shape. As an example, the seal 300 may be defined as being elongated, for example, by having a width to height aspect ratio of a cross-section that is greater than about 1. For example, the cross-sectional view along the line A-A shows the seal 300 as including an aspect ratio of about 1.2 (e.g., Δre is greater than Δzo). As an example, a seal may be defined as having an offset C-shape, for example, where one lip includes a diameter greater than another lip.
In the example of
As mentioned, a seal may be formed by a stamping process, for example, where a sheet of material is stamped and optionally cut to form a seal such as the seal 300 of
As an example, a method can include providing a C-shaped seal that includes a width to height ratio greater than approximately 1, an inner diameter and an outer diameter; providing a shroud component that includes an annular portion and a cylindrical portion; fitting the C-shaped seal on to the shroud component to seat the C-shaped seal about the cylindrical portion and in contact with the annular portion to form a sub-assembly; and inserting the sub-assembly into a turbine housing to contact the C-shaped seal with an axial face of the turbine housing. Such a method may further include operating a turbocharger that includes the turbine housing and sub-assembly where the C-shape seal acts to seal against exhaust leakage within the turbine housing and, for example, acts to direct forces that occur during operation of the turbocharger.
The example of
In the example of
As mentioned, exhaust leakage between components such as the shroud component 552 and the turbine housing 562 may be detrimental to performance of an exhaust turbine. Accordingly, in the example of
As shown, with respect to various coordinates, clearances between a surface 556 of the shroud component 552 and a surface 567 of the turbine housing 562 define a passage in which the seal 300 may be at least in part disposed. In the example of
As an example, the seal 300 can substantially maintain its position during service while contacting the shroud component 552 and contacting the turbine housing 562.
As an example, a seal may optionally be configured to be press-fit (e.g., interference fit) along an inner diameter (e.g., with respect to a shroud component). As an example, a clearance may exist between an inner diameter of a seal and an outer diameter of a cylindrical portion of a shroud component. In such an example, the clearance may allow for some movement of an inner diameter of the seal, for example, responsive to compression, temperature changes, etc. As an example, the seal 300 may expand or contract while still acting as a hindrance for flow of exhaust from the volute 566 to the passage 568 in the space defined by the surfaces 556 and 567 of the components 552 and 562, respectively.
As shown in the example of
In
In
In the example, of
In the example of
As an example, vanes may be located radially inwardly from a radial position of the support 1075-1. Such vanes may include respective posts or axels that define pivot axes for the vanes. As mentioned, the seal 900 may be arranged to reduce risk of deformation of a shroud component, for example, to reduce risk of sticking, binding, friction, etc. of one or more vanes.
As an example,
As an example, a turbine assembly for a turbocharger can include a turbine wheel that includes a base, a nose, blades, and a rotational axis that extends from the base to the nose; a turbocharger shaft operatively coupled to the turbine wheel; an annular component that includes an opening that receives at least a portion of the turbine wheel; a shroud component that includes an axis aligned with the rotational axis of the turbine wheel and an annular portion and a cylindrical portion that include an outer surface and an inner shroud surface where the outer surface includes a lower axial face and an upper axial face; mounts that extend from the annular component to locations at the shroud component where the mounts form an axial clearance between the annular component and the shroud component; a turbine housing that includes an axis aligned with the rotational axis of the turbine wheel, a lower axial face, an upper axial face and an inner surface that extends between the lower axial face and the upper axial face; and a C-shaped seal that includes an inner diameter, an outer diameter, an axis aligned parallel to the rotational axis of the turbine wheel, a lower lip that contacts the lower axial face of the outer surface of the shroud component along the annular portion of the shroud component, an upper lip that contacts the lower axial face of the inner surface of the turbine housing, and a wall portion that extends between the lower lip and the upper lip. As an example, a C-shaped seal may be elongated (e.g., width greater than height in cross-section), include radially offset lips (e.g., or edges), etc.
As an example, a seal can include a wall portion with a radius, an upper length that extends from an upper end of the radius to an upper lip, and a lower length that extends from a lower end of the radius to a lower lip. In such an example, the upper length and the lower length may be straight lengths. As an example, a radius of a seal may include a mid-point that defines an inner diameter of the seal.
As an example, a seal may include a free-standing axial dimension between a lower lip and an upper lip and a compressed axial dimension between the lower lip and the upper lip that is less than the free-standing axial dimension.
As an example, a seal can include a lower lip diameter and an upper lip diameter. In such an example, an assembly may include locations of mounts at a shroud component that include a common mount diameter. In such an example, an inner diameter of a C-shaped seal may be greater than an outer diameter of a cylindrical portion of the shroud component where, for example, the lip diameters are greater than the inner diameter of the C-shaped seal and where the common mount diameter is greater than the lip diameters. As an example, a lower lip diameter may be about 75 percent or more of such a common mount diameter. As an example, a lower lip diameter may be approximately 80 or more of such a common mount diameter.
As an example, a lower lip and an upper lip of a seal may have a common lip diameter. As an example, locations of mounts at a shroud component may have a common mount diameter. As an example, an inner diameter of a C-shaped seal may be greater than an outer diameter of a cylindrical portion of a shroud component, where a common lip diameter is greater than an inner diameter of the C-shaped seal and where a common mount diameter is greater than the common lip diameter. In such an example, the C-shaped seal may direct contact forces axially between the shroud component and a turbine housing, for example, where the shroud component directs forces due to contact with the lower lip of the C-shaped seal to mounts.
As an example, a turbine assembly can include vanes disposed between an annular component and a shroud component where each of the vanes includes an axial post and where, for example, the axial posts have a common post diameter (e.g., about a rotational axis of a turbine wheel). In such an example, a lower lip and an upper lip of a C-shaped seal may include a common lip diameter that is approximately the common post diameter or, for example, at least a lower lip diameter that is approximate the common post diameter.
As an example, for a variable geometry turbine unit with vanes, each of the vanes may include a planar upper surface disposed approximately parallel to a lower surface of an annular portion of a shroud component.
As an example, a C-shaped seal may include an elongated C-shape defined by a width to height ratio greater than approximate 1 or greater than approximate 1.1. As an example, such a ratio may be approximately 1.8. As an example, a C-shaped seal can include an open side and a closed side where the open side faces radially outward.
As an example, a turbocharger assembly can include a compressor wheel disposed in a compressor housing; a center housing that includes a bore and a bearing system disposed in the bore, the compressor housing attached to the center housing; a shaft and turbine wheel assembly that includes a shaft portion, a turbine wheel portion, and a rotational axis wherein the compressor wheel is attached to the shaft portion and the shaft portion is rotatably supported by the bearing system disposed in the bore of the center housing; a variable geometry cartridge positioned with respect to the center housing where the variable geometry cartridge includes a shroud component that includes an axis aligned with the rotational axis of the turbine wheel, an inner shroud surface, a lower axial face, an upper axial face and an outer surface that extends between the lower axial face and the upper axial face; a turbine housing attached to the center housing where the turbine housing includes an axis aligned with the rotational axis of the turbine wheel, a lower axial face, an upper axial face and an inner surface that extends between the lower axial face and the upper axial face; and a C-shaped seal that includes an inner diameter, an outer diameter, an axis aligned parallel to the rotational axis of the turbine wheel, a lower lip that contacts the lower axial face of the shroud component, an upper lip that contacts the lower axial face of the turbine housing, and a wall portion that extends between the lower lip and the upper lip.
Although some examples of methods, devices, systems, arrangements, etc., have been illustrated in the accompanying Drawings and described in the foregoing Detailed Description, it will be understood that the example embodiments disclosed are not limiting, but are capable of numerous rearrangements, modifications and substitutions.
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