1. Field of the Invention
The present invention relates to a structure of a turbine wheel used for a turbine of a gas turbine or an exhaust gas turbocharger; the invention particularly relates to a turbine wheel having what they call a scallop part, namely, a wavy-edge part on the back side of the turbine wheel, the scallop part being formed by cutting out of the back side of a radial turbine, so as to leave the blade parts.
2. Background of the Invention
As a rule, there are two types of turbine wheel in the radial turbine: a turbine wheel (shown in
The turbine wheel with the scallop part is advantageous in rotational inertia reduction, material cost reduction and thermal stress reduction; however, the efficiency of the turbocharger in which the turbine wheel with the scallop part is installed is inclined to be inferior to the efficiency of the turbocharger that is provided with the turbine wheel with not the scallop part but the back side wall 02.
Nevertheless, in response to the ever stricter regulations regarding exhaust gas emission and energy conservation in recent years, the quicker response performance regarding the turbocharger is being required and a reappraisal of the turbine wheel with the scallop part is being performed.
Patent Reference 1 (JP2000-170541) proposes the conventional technology regarding the turbine wheel with not the scallop part but the back side wall, whereas Patent Reference 2 (JP1998-131704) and Patent Reference (JP2003-201802) propose the conventional technology regarding the turbine wheel with the scallop part.
According to the technology disclosed in Patent Reference 1, the outer periphery diameter of the back side wall of the circular disk shape approximately agrees with the diameter of the blade parts so that the strength or rigidity of the turbine rotor is enhanced. Further, since the back side wall part blocks the gap between the turbine rotor and the wall part on the casing side (on the stator side), the leakage of the working fluid toward the rear side of the turbine rotor (i.e. hereby the turbine wheel) is prevented; thus, the leakage loss is reduced.
Further, according to Patent Reference 2, as depicted in
Further, according to Patent Reference 3, as depicted in
Patent Reference 1: JP2000-170541
Patent Reference 2: JP1998-131704
Patent Reference 3: JP2003-201802
The scallop profile shown in Patent Reference 2 as well as Patent Reference 3 is unsymmetrically formed between a blade part and the adjacent blade part; the minimum radius part of the scallop profile is sifted to the suction surface side or the (positive) pressure surface side. In
In the disclosure of conventional technologies, however, there is no improvement regarding the scallop profile on the tip end side of the blade part, the tip end side being get firstly exposed to the exhaust gas inlet flow; for instance, the disclosed technology of Patent Reference 2 as well as Patent Reference 3 is insufficient in constraining the leakage flow from the (positive) pressure surface side to the suction surface side; and, the further improvement is desired. The applicant of this invention performs the design of experiments on the analyses regarding how each part of the scallop profile influences on the leakage flow on the rear side of the blade part; according to the findings of the inventors, the width of the scallop parts (i.e. the thickness of the blade part on the back side of the turbine wheel) on the tip end side of the blade or the scallop is effectively widened so as to constrain the leakage flow on the rear side of the blade part.
Hence, the present invention aims at providing a turbine wheel that can constrain the leakage flow on the rear side of the blade part so as to enhance the turbine efficiency, in the manner that the width between the scallop part and the adjacent scallop part on the tip end side of the scallop is increased.
Incidentally, it is hereby noted that the scallop part is formed in the turbine wheel on the back side of the blade parts as well as on the outer periphery side of the hub part on the wheel back-side.
In order to overcome the difficulties of the conventional technologies, the present invention discloses a first aspect thereof, namely, a turbine wheel that includes, but not limited to, a plurality of blades being formed in a scallop shape by cutting-out a back plate side of the blades between a suction surface of a blade and a pressure surface of the adjacent blade, wherein
According to the above first aspect of the invention, the blade part is provided with a suction surface side extended part in the neighborhood of the suction surface side of the blade part so that the thickness of the blade part on the tip end side of the scallop cut-out profile is increased. Thus, the leakage flow on the rear side of the blade part from the (positive) pressure surface side to the suction surface side can be effectively constrained.
The experimental design is performed to evaluate the influence of each location of the scallop profile on the leakage flow, the locations being a pressure surface side inlet a, a pressure surface side middle b, a pressure surface side corner c, a minimum diameter location d, a suction surface side corner e, a suction surface side middle f, and a suction surface side inlet g, as shown in
Accordingly, the leakage flow on the rear side of the blade part can be effectively constrained, by forming the suction surface side extended part in the neighborhood of the suction surface side of the blade part, on the tip end side of the scallop parts (i.e. on the tip end side of the blade part). In addition, this extended part of the blade parts on the tip end side as well as on the back side of the turbine wheel does not bring a drastic increase in the rotational inertia of the turbine wheel in comparison with the conventional scallop profile (i.e. the conventional blade part on the back side of the wheel); thus, no deterioration in the response performance is brought. In this way, the leakage flow on the rear side of the blade part can be effectively constrained, and the turbine efficiency can be enhanced.
The suction surface side extended part may be provided mainly on the tip end side of the blade part (mainly on the tip end side of the scallop profile); or, the projecting-out width part may be provided so that the extended width on the blade root part side is smaller than the extended width on the tip end side. Further, the extended part may form a strip area in the cross section whose plane is at right angles to the rotation axis on the back side of the turbine wheel, so that the projecting-out width is an almost constant width along the blade height from the tip end side to the root side of the blade. When the extended part is provided mainly on the tip end side of the blade part, the increase of the rotational inertia can be further constrained and the response performance regarding the turbine can be improved. Further, the reduction effect regarding the working stresses in the turbine wheel can be further achieved.
Hereby, based on
According to the first aspect of the invention, as described in
In the next place, the present invention discloses a second aspect thereof, namely, a turbine wheel that includes, but not limited to, a plurality of blades being formed in a scallop shape by cutting-out a back plate side of the blades between a suction surface of a blade and a pressure surface of the adjacent blade, wherein
According to the above second aspect of the invention, as is the case with the first aspect, by providing the extended part on the tip end side of the blade part as well as on the back side of the blade part, without the deterioration of the response performance, the leakage flow on the rear side of the blade part can be effectively constrained and the turbine efficiency can be enhanced.
Further, the pressure surface side extended part may be provided mainly on the tip end side of the blade part; or, the projecting-out width part may be provided so that the extended width on the blade root part side is smaller than the extended width on the tip end side. Further, the extended part may form a strip area in the cross section whose plane is at right angles to the rotation axis on the back side of the turbine wheel, so that the projecting-out width is an almost constant width along the blade height from the tip end side to the root side of the blade. When extended part is provided mainly on the tip end side of the blade part, the increase of the rotational inertia can be further constrained and the response performance regarding the turbine can be improved. Further, the reduction effect regarding the working stresses in the turbine wheel can be further achieved.
According to the second aspect of the invention, as described in
It is hereby noted that the pressure difference ΔQ1 in the first aspect is smaller (a bit preferable) the pressure difference ΔQ2 in the second aspect; this is because the static pressure distribution rather steeply changes in the area near the suction surface side in comparison with the area near the pressure surface side.
In the next place, the present invention discloses a third aspect thereof, namely, a turbine wheel that includes, but not limited to, a plurality of blades being formed in a scallop shape by cutting-out a back plate side of the blades between a suction surface of a blade and a pressure surface of the adjacent blade, wherein
According to the third aspect of the invention, as described in
A preferable embodiment according to the above the first, the second and the third aspect of the present invention is the turbine wheel, wherein
According to the above described embodiment of the invention, as shown in
When the extended width is smaller than 1/20 of the pitch P, the improved pressure difference ΔQ1 cannot be expected, as shown in
In this way, the extended width is preferably smaller than ⅓ of the pitch P; and, when the extended width is greater than or equal to 1/12 of the pitch P, a remarkable pressure difference can be achieved.
Another preferable embodiment according to the above the first, the second and the third aspect of the present invention is the turbine wheel, wherein
In this way, the pressure surface side extended part is extended on the pressure surface side or on the suction surface side of the blade part so that the width is an almost constant width along the camber line of the blade part from the tip end side to the root side of the blade, the projecting-out width part forming a strip area; the projecting-out width part is can be easily casted, welded or machined.
Another preferable embodiment according to the above the first, the second and the third aspect of the present invention is the turbine wheel, wherein
As described above, a back-surface wall facing the extended part on the rear side of the turbine wheel is formed so that a gap space is formed between the back surface wall (on the casing side) and the back side surface of the turbine wheel; and, a plurality of grooves is formed along the radial lines or the spiral curves on the surface of the back-surface wall so that the pressure of the fluid streaming through the gap is increased. Thus, the leakage flow on the rear side of the blade part from the pressure surface side to the suction surface side can be constrained. Hence, in addition to the effect of the pressure surface side extended part on the pressure surface side or on the suction surface side, the leakage flow is constrained by the effect of the grooves.
According to the present invention, the tip end side of the scallop parts (i.e. hereby, of the blade parts) are provided with the suction surface side extended parts on the suction surface side of the blade part or toward the positive pressure area on the pressure surface side. Thus, the present invention can provide the turbine wheel provided with the scallop parts, wherein the leakage flow on the rear side of the blade parts from the positive pressure area to the suction surface area can be effectively constrained so that the turbocharger efficiency can be enhanced.
a) shows a scallop profile according to a first mode of the present invention; in relation to
a) shows a scallop profile according to a second mode of the present invention; in relation to
a) shows a scallop profile according to a second mode of the present invention; in relation to
a) and 7(b) are used for explaining a fourth mode (an embodiment) of the present invention;
a) and 8(b) show conventional turbine wheels;
Hereafter, the present invention will be described in detail with reference to the modes or embodiments shown in the figures. However, the dimensions, materials, shape, the relative placement and so on of a component described in these modes or embodiments shall not be construed as limiting the scope of the invention thereto, unless especially specific mention is made.
Based on
As shown in
Further, on the outer periphery side of the blade parts 5, a casing member 11 is provided so that the casing member 11 houses the blade parts 5; the casing member 11 is provided with an inlet passage 13 to feed the exhaust gas toward the gas inlet of the blade parts 5. Further, on the rear side of the blade parts 5, namely, on the rotor shaft side of the hub part 3, a back plate 15 is arranged so that the back plate 15 faces to the turbine wheel (i.e. the back side of the blade parts 5) and forms a back-surface wall facing the turbine wheel.
Further, a scallop (part) 17 is formed on the back surface side of the blade parts 5, namely, on the rotor shaft 7 side of the hub part 3. The profile of the scallop part 17 is depicted in
Hereby, the exhaust gas flow through a gap 23 between the back side (the back side) of the blade parts 5 and the back plate 15 is now explained.
Apart of the exhaust gas streaming toward the front edge (the leading edge) of the blade parts 5 from the inlet passage 13 leaks through the gap 23 between the back side of the blade parts 5 and the back plate 15, in the direction toward the rotor shaft 7. Further, there is a pressure difference between the pressure surface side 19 of a blade part 5 and the suction surface side 21 of the blade part 5; thus, the exhaust gas leaks from the pressure surface side 19 to the suction surface side 21 through the gap 23 formed between the rear side of the blade parts 5 and the back plate 15. Accordingly, a part of the energy included in the exhaust gas on the pressure surface side 19 is dissipated, while the gas is leaking through the gap; and, the exhaust gas having leaked into the suction surface side 21 disturbs the main current on the suction surface side 21 so that the driving torque generated by the main current may be reduced.
In order to constrain the leakage flow from the pressure surface side to the suction surface side through the gap on the rear side of the blade parts, the present invention provides a constraining means (a device) in which the projecting-out width of the turbine wheel along the scallop part 17 in the rotation hoop direction at each height level of the back side of the blade 5 is extended so that the leakage flow from the pressure surface side to the suction surface side through the gap on the rear side of the blade parts 5 is constrained. The scallop part is formed in the turbine wheel on the back side of the blade parts as well as on the outer periphery side of the hub part on the wheel back-side.
Further, in the present invention, it is taken into consideration where the projecting-out width along the scallop part is to be effectively extended; thus, by use of an approach according to experimental design, sensitivity analysis is performed with regard to the height level as the control factor, the height level being a height in the height direction of the blade part 5. To be more specific, the control factors in the design of experiments are the positions on the profile of the scallop part as depicted in
In other words, the exhaust gas collides with the blade part at the location of the pressure surface side inlet where the energy level of the exhaust gas is high and the leakage flow rate level of the gas flow streaming through the rear side of the blade part is great. Further, as shown in
Based on the results of the analysis as well as the findings as described above, the profile of the scallop part is extended toward the suction surface area in the neighborhood of the suction surface 21 of the blade part 5, at least at the tip end side (the leading edge side) of the rear side part of the blade 5. Thus, an suction surface side extended part 25 is formed, the projecting-out width being an almost constant width C along the blade height (along the blade camber line) from the tip end side to the root side of the blade 5. The projecting-out width part is depicted as a strip area of the shaded portion in
As described in
In the above context, when the extended width C is smaller than 1/20 of the pitch P, the improved pressure difference ΔQ1 cannot be expected, as shown in
In this way, the extended width C is preferably smaller than ⅓ of the pitch P; and, when the extended width C is greater than or equal to 1/12 of the pitch P and the extended width C is smaller than ⅓ of the pitch P, a remarkable pressure difference can be achieved.
b) is further explained.
To be more specific, the pressure difference between the pressure surface side and the suction surface side stays at the level of ΔP in a conventional case where no extended part is provided; according to the present mode where the suction surface side extended part is provided on the suction surface side of the blade part, the pressure difference is apparently reduced to the level of ΔQ1. Thus, thanks to this apparent pressure difference reduction from the level of ΔP to the level of ΔQ1, the leakage flow on the rear side of the blade parts can be constrained. Further, the reduced pressure difference of the level of ΔQ1 in a case of the suction surface side extended part is smaller (more efficient) than the reduced pressure difference of the level of ΔQ2 in a case of the pressure surface side extended part; the level of ΔQ2 and the pressure surface side extended part are described later in the second mode of the present invention.
As described thus far, according to the first mode of the present invention, the turbine wheel is provided with the suction surface side extended part 25 on the suction surface side 21 along the scallop part 17; thus, the leakage flow streaming through the gap on the rear side of the blade part 5 from the pressure surface side 19 to the suction surface side 21 can be effectively constrained.
Further, in the above explanation, the suction surface side extended part 25 on the suction surface side is formed so that the projecting-out width is an almost constant width C along the blade height from the tip end side to the root side of the blade. Thereby, the projecting-out width part forms the strip area in the cross section whose plane is at right angles to the rotation axis on the back side of the turbine wheel. However, the projecting-out width part of the width C may be provided mainly on the tip end side of the blade part; or, the projecting-out width part may be provided so that the extended width on the blade root part side is smaller than the extended width on the tip end side; in these events, the weight of the turbine wheel can be further reduced so that the increase in the rotational inertia of the turbine wheel is further constrained. In this way, the quick response performance regarding the turbine can be achieved and the stresses appearing in the turbine wheel 1 can be reduced.
In the next place, based on
As shown in
Thus, an pressure surface side extended part 32 is formed. Thereby, the projecting-out width is an almost constant width E along the blade height from the tip end side to the root side of the blade 5. In addition, the projecting-out width part forms the strip area in the cross section whose plane is at right angles to the rotation axis on the back side of the turbine wheel. Incidentally, the setting conditions regarding the projecting-out width E in this second mode are the same as the setting conditions regarding the projecting-out width C in the first mode.
Based on the configuration as described above,
However, the level of Δ Q2 regarding the reduced pressure difference in the second mode is greater (somewhat less efficient) than the level of Δ Q1 regarding the reduced pressure difference in the first mode. As is the case with the first mode, the static pressure distribution rather steeply changes in the area near the suction surface side in comparison with the area near the pressure surface side. Accordingly, by means of the pressure surface side extended part extended in the neighborhood of the pressure surface side of the blade part 5, the pressure difference between the pressure surface side and the suction surface side can be apparently constrained.
As is the case with the first mode, also according to this second mode, by means of the extended part, the increase in the rotational inertia of the turbine wheel can be constrained so that the quick response performance can be achieved; further, the leakage flow behind the rear surface of the blade part can be constrained so that the turbine efficiency can be enhanced.
Further, in the above explanation, the pressure surface side extended part 32 on the pressure surface side is formed so that the projecting-out width is an almost constant width E along the blade height from the tip end side to the root side of the blade. Thereby, the projecting-out width part forms the strip area in the cross section whose plane is at right angles to the rotation axis on the back side of the turbine wheel. However, as is the case with the first mode, the projecting-out width part 32 of the width E may be provided mainly on the tip end side of the blade part; or, the projecting-out width part may be provided so that the extended width on the blade root part side is smaller than the extended width on the tip end side.
In the next place, based on
As shown in
Thereby, regarding the suction surface side extended part 44 on the suction surface side 21 of the blade part 5, the projecting-out width is an almost constant width C along the blade height from the tip end side to the root side of the blade 5; and, regarding the pressure surface side extended part 42 on the pressure surface side 19, the projecting-out width is an almost constant width E along the blade height from the tip end side to the root side of the blade 5. In addition, each of the projecting-out width parts forms the strip area in the cross section whose plane is at right angles to the rotation axis on the back side of the turbine wheel. Incidentally, the setting conditions regarding the projecting-out width C in this third mode are the same as the setting conditions regarding the projecting-out width C in the first mode; the setting conditions regarding the projecting-out width E in this third mode are the same as the setting conditions regarding the projecting-out width E in the second mode.
Based on the configuration as described above,
Hence, the rotational inertia of the turbine wheel according to the third mode is somewhat increased in comparison with the rotational inertia of the turbine wheel according to the first mode or the second mode. However, the extended parts 42 and 44 may be provided mainly on the tip end side of the blade part; or, the extended parts 42 and 44 may be provided so that the extended width on the blade root part side is smaller than the extended width on the tip end side. For instance, a reverse V-shaped profile of the blade part (in
In the next place, based on
The back plate 15 faces the turbine wheel (i.e. the back side of the blade parts 5), and forms a back-surface wall facing the turbine wheel. The back-surface wall is annularly formed so as to face the rear back surface of the blade parts 5; thus, the back plate 15 faces the back surface of each blade part; namely, the back plate 15 faces at least one of the suction surface side extended part 25 and the pressure surface side extended part 32.
Further, on the wall surface of the back plate, a plurality of grooves is formed along the radial lines or the spiral curves. The grooves are provided so that the pressure in the gap between the back plate 15 and the rear side surface of the blade part 5 is increased.
In other words, as shown in
Further, the effect of the suction surface side extended part 25, 32, 42 or 44 according to the first, second or third mode of the present invention on the reduction of the leakage flow on the rear side of the blade parts can be further enhanced by providing the grooves according to the fourth mode of the present invention.
Further, in this fourth mode as described above, the tapered grooves 50 are provided on the surface of the back plate 15, the surface facing the back side surface of the blade parts 5 (a part of the back side surface of the turbine wheel); however, it goes without saying that the grooves may be provided on the back side surface of the blade parts and the extended parts of the scallop parts.
According to the present invention, the tip end side of the scallop parts (i.e. of the blade parts) are provided with the suction surface side extended parts toward the suction surface area on the suction surface side of the blade part or toward the positive pressure area on the pressure surface side. Thus, the leakage flow on the rear side of the blade parts from the positive pressure area to the suction surface area can be effectively constrained so that the turbocharger efficiency can be enhanced. Hence, the present invention is suitably applied to the turbine wheel provided with the scallop parts.
Number | Date | Country | Kind |
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2009-253773 | Nov 2009 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2010/062656 | 7/28/2010 | WO | 00 | 11/16/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2011/055575 | 5/12/2011 | WO | A |
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1386983 | Dec 2002 | CN |
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Entry |
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Chinese Office Action, dated Sep. 27, 2013, for Chinese Application No. 201080014806.6 with an English translation. |
Decision to Grant a Patent effective Jan. 7, 2014 issued in the corresponding Japanese Application No. 2009-253773 with an English translation. |
Chinese Notice of Allowance issued in Chinese Application No. 201080014806.6 on Dec. 24, 2014. |
Number | Date | Country | |
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20130004321 A1 | Jan 2013 | US |