Patent Application
20120288364
1. Field of the Invention
The invention relates to a turbocharger wheel housing that includes a shell body having a scroll portion and a base body having an accommodation portion in which a wheel is accommodated, with a gas passage formed between the shell body and the base body.
As a turbocharger wheel housing, there is known a turbine housing disclosed in Japanese Patent Application Publication No. 2008-106667 (JP-A-2008-106667). According to a sheet metal turbine housing such as this turbine housing, the thicknesses of respective wall portions can be made small in comparison with a cast turbine housing, so a reduction in weight and a reduction in thermal capacity can be achieved.
However, in the sheet metal housing, the following problem arises due to a small thickness of a shell body. That is, should part of a wheel separate from a main body as a fragment during rotation thereof and hit the shell body, a region hit by the fragment is greatly deformed as a result of the small thickness of the shell body. It should be noted that a similar problem may be caused not only in a sheet metal housing but also in any housing with a shell body whose lateral wall portion includes a thin-walled portion.
SUMMARY OF THE INVENTION
The invention provides a turbocharger and a wheel housing thereof that can restrain a shell body from being greatly deformed.
A first aspect of the invention relates to a turbocharger wheel housing. This wheel housing includes a shell body having a scroll portion and a base body having an accommodation portion in which a wheel is accommodated, and in which a gas passage formed between the shell body and the base body. The shell body is composed of a first shell body and a second shell body that are formed separately from each other and combined with each other. The second shell body includes the scroll portion. The accommodation portion includes a wheel chamber in which the wheel is arranged, a communication portion that allows a gas to flow from the gas passage to the wheel chamber, and a pillar portion provided adjacently to the communication portion to block flow of the gas from the gas passage to the wheel chamber. The first shell body includes a reinforcement portion superposed on one of an inner peripheral face or an outer peripheral face of a peripheral wall of the scroll portion. The reinforcement portion has a slit portion that is partially discontinuous in a circumferential direction. The pillar portion is provided on a travel path of a fragment of the wheel moving from a main body of the wheel toward the slit portion.
In this wheel housing, the reinforcement portion is superposed on the peripheral wall of the scroll portion. Therefore, the amount of deformation of the second shell body can be made small when the fragment of the wheel hits the peripheral wall of the scroll portion. Meanwhile, it is also conceivable that the reinforcement portion be structured not to include the slit portion. In the case of this structure, however, the operation of superposing the reinforcement portion on the peripheral wall of the scroll portion is troublesome in manufacturing the shell body. In the invention, the slit portion is provided through the reinforcement portion. Therefore, the operability in superposing the reinforcement portion on an inner peripheral face or an outer peripheral face of the peripheral wall of the scroll portion can be made good.
On the other hand, according to the structure of the shell body including the slit portion, that region of the second shell body which corresponds to the slit portion is not substantially reinforced by the reinforcement portion. Therefore, the second shell body is not sufficiently restrained from being deformed in this region. In the invention, the pillar portion is provided on the traveling path of the fragment of the wheel moving from the main body of the wheel toward the slit portion. Therefore, when separating from the main body of the wheel, the fragment of the wheel hits the pillar portion located between the wheel and the slit portion, and hence is unlikely to hit the slit portion. Thus, that region of the second shell body which corresponds to the slit portion can be restrained from being greatly deformed.
A second aspect of the invention relates to a turbocharger wheel housing. This wheel housing includes a shell body having a scroll portion and a base body having an accommodation portion in which a wheel is accommodated, and in which a gas passage formed between the shell body and the base body. The shell body is composed of a first shell body and a second shell body that are formed separately from each other and combined with each other. The second shell body includes the scroll portion. The accommodation portion includes a wheel chamber in which the wheel is arranged, a communication portion that allows a gas to flow from the gas passage to the wheel chamber, and a pillar portion provided adjacently to the communication portion to block flow of the gas from the gas passage to the wheel chamber. The first shell body includes a reinforcement portion superposed on one of an inner peripheral face or an outer peripheral face of a peripheral wall of the scroll portion. The reinforcement portion has a slit portion that is partially discontinuous in a circumferential direction. The pillar portion is so provided as to intersect with that tangential line of the wheel which passes the slit portion.
In this wheel housing, the reinforcement portion is superposed on the peripheral wall of the scroll portion. Therefore, the amount of deformation of the second shell body can be made small when the fragment of the wheel hits the peripheral wall of the scroll portion. Meanwhile, it is also conceivable that the reinforcement portion be structured not to include the slit portion. In the case of this structure, however, the operation of superposing the reinforcement portion on the peripheral wall of the scroll portion is troublesome in manufacturing the shell body. In the invention, the slit portion is provided through the reinforcement portion. Therefore, the operability in superposing the reinforcement portion on the inner peripheral face or the outer peripheral face of the peripheral wall of the scroll portion can be made good.
On the other hand, according to the structure of the shell body including the slit portion, that region of the second shell body which corresponds to the slit portion is not substantially reinforced by the reinforcement portion. Therefore, the second shell body is not sufficiently restrained from being deformed in this region. In the invention, the pillar portion is so provided as to intersect with that tangential line of the wheel which passes the slit portion, the wheel moving from the main body of the wheel toward the slit portion. Therefore, when separating from the main body of the wheel, the fragment of the wheel hits the pillar portion located between the wheel and the slit portion, and hence is unlikely to hit the slit portion. Thus, that region of the second shell body which corresponds to the slit portion can be restrained from being greatly deformed.
A third aspect of the invention relates to a turbocharger wheel housing. This wheel housing includes a shell body having a scroll portion and a base body having an accommodation portion in which a wheel is accommodated, and in which a gas passage formed between the shell body and the base body. The shell body is composed of a first shell body and a second shell body that are formed separately from each other and combined with each other. The second shell body includes the scroll portion. The accommodation portion includes a wheel chamber in which the wheel is arranged, a communication portion that allows a gas to flow from the gas passage to the wheel chamber, and a pillar portion provided adjacently to the communication portion to block flow of the gas from the gas passage to the wheel chamber. The first shell body includes a reinforcement portion superposed on one of an inner peripheral face or an outer peripheral face of a peripheral wall of the scroll portion. The reinforcement portion has a slit portion that is partially discontinuous in a circumferential direction. The pillar portion is so provided as to prevent a fragment of the wheel, which separates from a main body of the wheel and moves toward a thin-walled portion of a peripheral wall of the shell body, from hitting the thin-walled portion, the thin-walled portion being that region of the peripheral wall of the shell body where a peripheral wall of the scroll portion and the slit portion are superposed on each other.
In this wheel housing, the reinforcement portion is superposed on the peripheral wall of the scroll portion. Therefore, the amount of deformation of the second shell body can be made small when the fragment of the wheel hits the peripheral wall of the scroll portion. Meanwhile, it is also conceivable that the reinforcement portion be structured not to include the slit portion. In the case of this structure, however, the operation of superposing the reinforcement portion on the peripheral wall of the scroll portion is troublesome in manufacturing the shell body. In the invention, the slit portion is provided through, the reinforcement portion. Therefore, the operability in superposing the reinforcement portion on the inner peripheral face or the outer peripheral face of the peripheral wall of the scroll portion can be made good.
On the other hand, according to the structure of the shell body including the slit portion, that region of the second shell body which corresponds to the slit portion is not substantially reinforced by the reinforcement portion. Therefore, the second shell body is not sufficiently restrained from being deformed in this region. In the invention, the pillar portion is so provided as to prevent the fragment of the wheel, which moves from the main body of the wheel toward the slit portion, from hitting the thin-walled portion. Therefore, when separating from the main body of the wheel, the fragment of the wheel hits the pillar portion located between the wheel and the slit portion, and hence is unlikely to hit the slit portion. Thus, that region of the second shell body which corresponds to the slit portion can be restrained from being greatly deformed.
In the turbocharger wheel housing according to each of the foregoing aspects of the invention, the first shell body and the second shell body may be provided as sheet metal shell bodies.
In this wheel housing, the first shell body and the second shell body are provided as sheet metal shell bodies. Therefore, the wheel housing can be reduced in weight and thermal capacity. Further, due to the first shell body and the second shell body that are provided as sheet metal shell bodies, the peripheral wall is lower in strength in comparison with cast shell bodies. However, the peripheral wall is reinforced by the reinforcement portion, and hence can be restrained from being deformed.
In the turbocharger wheel housing according to each of the foregoing aspects of the invention, the shell body may include a connection portion that connects the scroll portion with an exhaust pipe or an intake pipe, the first shell body may include a first divisional connection portion as part of the connection portion, the second shell body may include a second divisional connection portion that forms part of the connection portion, and the connection portion may be composed of the first divisional connection portion and the second divisional connection portion that are combined with each other.
It is also conceived that the sheet metal shell body be structured with its connection portion undivided. In this case, however, when an opening portion for the gas passage is formed through the connection portion, a process of punching out part of a sheet metal is required. In the aforementioned wheel housing, the connection portion is composed of the first divisional connection portion and the second divisional connection portion that are combined with each other. Therefore, the process of punching out part of the sheet metal to form the connection portion is not required. Accordingly, the yield ratio of a material can be enhanced.
In the aforementioned turbocharger wheel housing, the first shell body may be formed of a metal plate having an oblong flat plate portion and a protrusion portion that protrudes from a long side of the flat plate portion, the reinforcement portion may be formed by working the flat plate portion into a cylindrical shape, and the first divisional connection portion may be obtained by working the protrusion portion into a circular shape.
It is also conceived that the first shell body be structured by forming the reinforcement portion and the first divisional connection portion separately from each other and joining them to each other through a joining operation such as welding or the like. In this case, however, the aforementioned joining operation is required in manufacturing the first shell body. In the invention, the first shell body is formed of the single metal plate having the oblong flat plate portion and the protrusion portion protruding from the long side of this flat plate portion. Therefore, the first shell body can be manufactured without having to include a joining operation such as welding or the like.
In the aforementioned turbocharger wheel housing, the base body may include a flange portion which protrudes radially outward beyond the accommodation portion, and the wheel housing may be formed by fitting one of the reinforcement portion of the first shell body and the scroll portion of the second shell body to an outer periphery of the flange portion of the base body and fitting the other of the reinforcement portion and the scroll portion to an inner periphery of the one of the reinforcement portion and the scroll portion that is fitted to the outer periphery of the flange.
According to this wheel housing, the reinforcement portion of the first shell body is fitted to the outer periphery of the flange portion of the base body, and the scroll portion of the second shell body is fitted to the inner periphery of the reinforcement portion. Alternatively, the scroll portion of the second shell body is fitted to the outer periphery of the flange portion of the base body, and the reinforcement portion of the first shell body is fitted to the inner periphery of the scroll portion of the second shell body. In either case, the aforementioned respective structural bodies are fitted to each other to remain combined with each other. Accordingly, a jig for combining the aforementioned respective structural bodies with each other can be dispensed with or simplified in construction.
In the wheel housing, the pillar portion may be longer in a circumferential direction than the slit portion.
A turbocharger turbine housing may be constructed in the same manner as the aforementioned wheel housing.
According to this turbine housing, the amount of deformation of the second shell body of the turbine housing can be made small, and the operability in superposing the reinforcement portion on the inner peripheral face or the outer peripheral face of the peripheral wall of the scroll portion can be made good.
A turbocharger compressor housing may be constructed in the same manner as the aforementioned wheel housing.
According to this compressor housing, the amount of deformation of the second shell body of the compressor housing can be made small, and the operability in superposing the reinforcement portion on the inner peripheral face or the outer peripheral face of the peripheral wall of the scroll portion can be made good.
A turbocharger may include the aforementioned wheel housing.
The foregoing and further features and advantages of the invention will become apparent from the following description of example embodiments of the invention with reference to the accompanying drawings, wherein like numerals are used to represent like elements and wherein:
The first embodiment of the invention will be described with reference to
As shown in FIG 1, a turbocharger 1 is provided with a turbine wheel 21 that rotates with the aid of the energy of exhaust gas, a compressor wheel 22 that compresses intake air as the wheel 21 rotates, a rotor shaft 23 that connects these wheels to each other, a turbine housing 11 that accommodates the turbine wheel 21, a compressor housing 12 that accommodates the compressor wheel 22, and a center housing 13 that accommodates the rotor shaft 23. An exhaust pipe 91 and an intake pipe 92 are connected to the turbine housing 11 and the compressor housing 12 respectively.
In the turbocharger 1, the turbine wheel 21 and the compressor wheel 22 are connected to the rotor shaft 23 respectively. Therefore, these three elements rotate integrally. Further, the turbine housing 11 and the compressor housing 12 are connected to the center housing 13.
In the turbine housing 11, a wheel chamber 64 in which the turbine wheel 21 is accommodated, and an exhaust passage 80 for causing an exhaust gas from an exhaust pipe 91 upstream of th e turbine housing 11 to flow to the exhaust pipe 91 downstream of the turbine housing 11 are formed. The exhaust passage 80 is formed of the wheel chamber 64 in which the turbine wheel 21 is accommodated, and a scroll passage 81 for supplying the exhaust gas from the upstream exhaust pipe 91 to the wheel chamber 64, and an outlet passage for delivering the exhaust gas from the turbine wheel 21 to the downstream exhaust pipe 91.
The structure of the turbine housing 11 will be described with reference to
The shell body 30 is composed of a first shell body 40 and a second shell body 50. The first shell body 40 and the second shell body 50 are obtained by press-molding sheet metals. The base body 60, the inlet flange 71, and the outlet flange 72 are cast.
As shown in
The first shell body 40 is configured to include a first divisional connection portion 41 constituting part of the connection portion 31, and a cylindrical reinforcement portion 42 elongated from the connection portion 41 in the circumferential direction to extend along an outer periphery of the lateral wall portion 53 of the second shell body 50. A slit portion 43 that is partially discontinuous in the circumferential direction is formed through the reinforcement portion 42. That is, the reinforcement portion 42 is constructed as a cylindrical element having a region that is discontinuous in the circumferential direction.
The base body 60 is provided with a circular flange portion 62 for connecting the center housing 13 (see FIG 1) and the turbine housing 11 to each other, a cylinder portion 61 to which a joint portion 52A of the second shell body 50 and the outlet flange 72 are fitted, and an accommodation portion 63 in which the turbine wheel 21 is accommodated. The accommodation portion 63 is provided in such a manner as to connect the cylinder portion 61 and the flange portion 62 to each other. The accommodation portion 63 is provided with communication portions 66 through which the scroll passage 81 and the wheel chamber. 64 communicate with each other. Each of pillar portions 65 is provided between corresponding adjacent ones of the communication portions 66 in such a manner as to connect the flange portion 62 and the cylinder portion 61 to each other.
The longitudinal cross-sectional structure of the turbine housing 11 will be described with reference to
The respective elements of the turbine housing 11 are combined with one another as will be described below. The outlet flange 72 is fitted to the outside of a tip end portion 61C of the cylinder portion 61 of the base body 60. An outer peripheral face 61A of the tip end portion 61C and an inner peripheral face 72A of the outlet flange 72 are joined to each other through brazing.
A joint portion 52A of the second shell body 50 is fitted to the outside of a base end portion 61B of the cylinder portion 61 of the base body 60. An outer peripheral face 61A of the base end portion 61B and an inner peripheral face 52B of the joint portion 52A are joined to each other through brazing.
The inner peripheral face 52B of the top wall portion 52 of the second shell body 50 is butted against a top face 63A of the accommodation portion 63 of the base body 60 in the vicinity of the cylinder portion 61. The top face 63A in the vicinity of the cylinder portion 61 and the inner peripheral face 52B of the top wall portion 52 are in contact with each other with no gap formed therebetween.
A lower end face 53B of the lateral wall portion 53 of the second shell body 50 is butted against a top face 62A of the flange portion 62 of the base body 60. The top face 62A of the flange portion 62 and the lower end face 53B of the lateral wall portion 53 are joined to each other through brazing.
A lower end portion 42B of the reinforcement portion 42 of the first shell body 40 is fitted to the outside of the flange portion 62 of the base body 60 and the outside of the lateral wall portion 53 of the second shell body 50. The outer peripheral face 62B of the flange portion 62 and the outer peripheral face 53A of the lateral wall portion 53 are joined to the inner peripheral face 42A of the lower end portion 42B of the reinforcement portion 42 through brazing.
A passage for exhaust gas is formed in the turbine housing 11 as will be described below. The scroll passage 81 is formed between the scroll portion 51 on the one hand and the accommodation portion 63 and the flange portion 62 on the other hand. Further, an outlet passage 82 is formed in the cylinder portion 61. The scroll passage 81 communicates with an inlet of the wheel chamber 64 via the communication portions 66. The outlet passage 82 communicates with an outlet of the wheel chamber 64.
The lateral cross-sectional structure of the turbine housing 11 will be described with reference to
As shown in
The inlet flange 71 is fitted to the outside of the first divisional connection portion 41 of the first shell body 40. An outer peripheral face 41A of the connection portion 41 and an inner peripheral face 71A of the inlet flange 71 are joined to each other through brazing.
Although not shown, the inlet flange 71 is fitted to the outside of the second divisional connection portion 54 of the second shell body 50 on a cross-section extending parallel to a cross-section of
The reinforcement portion 42 of the first shell body 40 is entirely superposed on the outer peripheral face 53A of the lateral wall portion 53 of the second shell body 50 in the circumferential direction. The lateral wall portion 32 of the shell body 30 is constituted by a region where the reinforcement portion 42 and the lateral wall portion 53 are superposed on each other.
As shown in FIG 5B, the lateral wall portion 32 has a thickness HA that is set substantially equal from one end to the other end of the connection portion 31 in the circumferential direction of the shell body 30. However, that region of the lateral wall portion 32 where the slit portion 43 and the lateral wall portion 53 are superposed on each other (hereinafter referred to as a thin-walled portion 32A) has a thickness HB smaller than that of the other region of the lateral wall portion 32.
The thicknesses of the respective regions are related to one another as will be described below. The reinforcement portion 42 has a thickness HC that is set substantially equal to a thickness HD of the lateral wall portion 53. The thickness HA of the lateral wall portion 32 except the thin-walled portion 32A is equal to the sum of the thickness HC of the reinforcement portion 42 and the thickness HD of the lateral wall portion 53. The thickness HB of the thin-walled portion 32A is equal to the thickness HD of the lateral wall portion 53.
The pillar portions 65 have a thickness HE that is set larger than the thickness HC of the reinforcement portion 42 and the thickness HD of the lateral wall portion 53 respectively. Further, the thickness HE of the pillar portions 65 is set larger than the thickness HA of the lateral wall portion 32 except the thin-walled portion 32A.
Exhaust gas flows in the turbine housing 11 as will be described below. As indicated by an arrow GA of
The more detailed structure of the turbine housing 11, mainly the constructions of the pillar portions 65 of the base body 60, the reinforcement portion 42 of the first shell body 40, and the lateral wall portion 53 of the second shell body 50 will be described in detail with reference to
The base body 60 is provided with the four pillar portions 65 arranged at angular intervals of 90° in the circumferential direction. Each of the communication portions 66 is formed between corresponding ones of the pillar portions 65 that are adjacent to each other in the circumferential direction. The communication portions 66 have a circumferential length that is set longer than a circumferential length of the pillar portions 65. The circumferential length of the pillar portions 65 is set longer than the circumferential length of the slit portion 43.
Circumferential rotational phases of the shell body 30 and the base body 60 are set on the basis of a concept that will be described below. That is, the thin-walled portion 32A of the lateral wall portion 32 of the shell body 30 is smaller in thickness than the other region of the lateral wall portion 32, and hence is likely to be deformed excessively when a fragment of the blade of the turbine wheel 21 hits the thin-walled portion 32A.
Thus, in this turbine housing 11, the pillars 65 are provided on a traveling path of the fragment of the turbine wheel 21 moving from a main body of the turbine wheel 21 toward the thin-walled portion 32A. That is, the circumferential phases of the shell body 30 and the base body 60 are set such that that one of fragments flying from the main body of the turbine wheel 21 in all directions which may hit the thin-walled portion 32A of the shell body 30 is received by a region higher in strength than the thin-walled portion 32A before the fragment reaches the thin-walled portion 32A.
A mode of setting these phases can be described as follows. It should be noted herein that that one of tangential lines of the turbine wheel 21 which passes one end of the thin-walled portion 32A, namely, which passes a tangent point PT1 on an outer periphery of the turbine wheel 21 and a point PC1 at an end of the thin-walled portion 32A is defined as a tangential line T1. Further, that one of the tangential lines of the turbine wheel 21 which passes the other end of the thin-walled portion 32A, namely, which passes a tangent point PT2 on the outer periphery of the turbine wheel 21 and a point PC2 at an end of the thin-walled portion 32A is defined as a tangential line T2. In the turbine housing 11, the circumferential phases of the shell body 30 and the base body 60 are set such that each of the pillar portions 65 is located between these tangential lines T1 and T2.
Accordingly, when a fragment separates from the main body of the turbine wheel 21, the frequency with which this fragment hits the pillar portion 65 located between the turbine wheel 21 and the thin-walled portion 32A is high. Thus, the shell body 30 is restrained from being excessively deformed due to the hitting of the fragment.
Patterns of the traveling path of the fragment that has separated from the turbine wheel 21 will be exemplified below. When it is assumed that the fragment has flown out from the tangent points PT1 and PT2, this fragment moves on the tangential lines T1 and T2, and hits a corresponding one of the pillar portions 65 before reaching the thin-walled portion 32A of the shell body 30.
When it is assumed that a fragment has flown out from a tangent point PT3, this fragment moves on a tangential line T3 whose tangent point coincides with the tangent point PT3, and hits that region of the lateral wall portion 32 of the shell body 30 which is formed by the reinforcement portion 42 and the lateral wall portion 53.
When it is assumed that a fragment has flown out from a tangent point PT4, this fragment moves on a tangential line T4 whose tangent point coincides with the tangent point PT4, and hits a corresponding one of the pillar portions 65 of the base body 60 before reaching the lateral wall portion 32 of the shell body 30.
A process of manufacturing the first shell body 40 will be described with reference to
As shown in FIG 7B, the flat plate portion 141 of the metal plate 140 is bent into a cylindrical shape, and the reinforcement portion 42 having the slit portion 43 is formed. Further, the protrusion portion 142 is press-molded into the shape of the first divisional connection portion 41. Thus, the first shell body 40 is formed.
A process of assembling the shell body 30 and the base body 60 will be described. (Step A) The reinforcement portion 42 of the first shell body 40 is fitted to the outside of the flange portion 62 of the base body 60. At this moment, the circumferential phases of the base body 60 and the first shell body 40 are adjusted such that the pillar portions 65 of the base body 60 are so located as to correspond to the tangential lines T1 and T2. (Step B) The lateral wall portion 53 of the second shell body 50 is fitted to the inside of the reinforcement portion 42 of the first shell body 40, and the lower end face 53B of the second shell body 50 is butted against the top face 62A of the flange portion 62 of the base body 60. (Step C) A brazing solder is arranged on respective joint portions of the first shell body 40, the second shell body 50, and the base body 60. (Step D) The first shell body 40, the second shell body 50, and the base body 60 are put into a kilt and heated. At this moment, the brazing solder melts and flows into gaps among the respective joint portions, and the first shell body 40, the second shell body 50, and the base body 60 are joined to one another. (Step E) The inlet flange 71 is fitted to the outside of the connection portion 31 of the shell body 30, and the outlet flange 72 is fitted to the outside of the cylinder portion 61 of the base body 60. (Step F) A brazing solder is arranged on a joint portion between the connection portion 31 of the shell body 30 and the inlet flange 71, and on a joint portion between the base body 60 and the outlet flange 72. (Step G) The shell body 30, the base body 60, the inlet flange 71, and the outlet flange 72 are put into a kilt and heated. At this moment, the brazing solder melts and flows into gaps among the respective joint portions, and the shell body 30, the base body 60, the inlet flange 71, and the outlet flange 72 are thereby joined to one another.
As described above in detail, according to this embodiment of the invention, the following effects are achieved. (1) In this embodiment of the invention, the first shell body 40 is so provided as to include the reinforcement portion 42 superposed on the outer peripheral face 53A of the lateral wall portion 53 of the scroll portion 51. Further, the reinforcement portion 42 is so provided as to have the slit portion 43 that is partially discontinuous in the circumferential direction. Further, the shell body 30 and the base body 60 are combined with each other such that the pillar portions 65 are so located as to intersect with those of the tangential lines T1 and T2 of the turbine wheel 21 which pass the points PC1 and PC2 at the end of the thin-walled portion 32A, namely, such that the pillar portions 65 are located on the traveling path of a fragment of the wheel 21 moving from the main. body of the wheel 21 toward the thin-walled portion 32A.
Thus, the amount of deformation of the second shell body 50 can be made small when the fragment of the wheel 21 hits the lateral wall portion 53 of the scroll portion 51. On the other hand, it is also conceivable that the reinforcement portion 42 be structured not to include the slit portion 43. In the case of such a structure, the operation of superposing the reinforcement portion 42 on the lateral wall portion 53 of the scroll portion 51 is troublesome in manufacturing the shell body 50. In this embodiment of the invention, the reinforcement portion 42 is provided with the slit portion 43. Therefore, the operability in superposing the reinforcement portion 42 on the outer peripheral face 53A of the lateral wall portion 53 of the scroll portion 51 can be made good.
(2) The first shell body 40 and the second shell body 50 according to this embodiment of the invention are provided as sheet metal shell bodies. Therefore, the turbine housing 11 can be reduced in weight and thermal capacity, further, the first shell body 40 and the second shell body 50 are sheet metal shell bodies, and hence the lateral wall portion 53 is lower in strength in comparison with the case of cast shell bodies. However, the lateral wall portion 53 is reinforced by the reinforcement portion 42 and thus can be restrained from being deformed. Further, since the first shell body 40 and the second shell body 50 are employed for the turbine housing 11, the thermal energy of exhaust gas can be restrained from decreasing.
(3) It is also conceivable that the sheet metal shell body 30 be structured with the connection portion 31 undivided. In this case, however, a process of punching out part of the sheet metal is required in forming an opening portion for the exhaust passage 80 through the connection portion 31. In this embodiment of the invention, the connection portion 31 of the shell body is constructed by combining the first divisional connection portion 41 of the first shell body 40 and the second divisional connection portion 54 of the second shell body 50 with each other. Thus, the process of punching out part of the sheet metal to form the connection portion 31 is not required. Accordingly, the yield ratio of a material can be enhanced.
(4) It is also conceivable that the first shell body 40 be structured by forming the reinforcement portion 42 and the first divisional connection portion 41 separately from each other and joining them to each other through a joining operation such as welding or the like. In this case, however, the aforementioned joining operation is required in manufacturing the first shell body 40. In this embodiment of the invention, the metal plate 140 having the oblong fiat plate portion 141 and the protrusion portion 142 protruding from the long side of this flat plate portion 141 is used as a material for the first shell body 40. The flat plate portion 141 of this metal plate 140 is then worked into a cylindrical shape to form the reinforcement portion 42, and the first shell body 40 is manufactured through a step of working the protrusion portion 142 into a circular shape to form the first divisional connection portion 41. Thus, the first shell body 40 can be, manufactured without the need to include a joining operation such as welding or the like. Further, since the first shell body 40 is obtained through simple working, the yield ratio can be enhanced.
(5) In this embodiment of the invention, the turbine housing 11 is structured such that it can be assembled by fitting the reinforcement portion 42 of the first shell body 40 to the outer periphery of the flange portion 62 of the base body 60 and fitting the lateral wall portion 53 of the second shell body 50 to the inner periphery of the reinforcement portion 42. Thus, the first shell body 40, the second shell body 50, and the base body 60 remain combined with one another. Accordingly, a jig for combining the first shell body 40, the second shell body 50, and the base body 60 with one another can be dispensed with or simplified in construction.
It should be noted that the mode of implementing the invention is not limited to the foregoing embodiment of the invention. For example, the invention can also be implemented in modes that will be described below. Further, the following respective modification examples are applied not only to the foregoing embodiment of the invention, but it is also possible to combine the different modification examples with one another to implement them.
In the foregoing embodiment of the invention, the lateral wall portion 53 of the second shell body 50 is fitted to the inside of the reinforcement portion 42 of the first shell body 40. However, it is also possible to fit the reinforcement portion 42 of the first shell body 40 to the inside of the lateral wall portion 53 of the second shell body 50.
In the foregoing embodiment of the invention, the first shell body 40 is structured with the first divisional connection portion 41 and the reinforcement portion 42 made of the same material and formed integrally with each other. However, the structure of the shell body 40 can also be changed as will be described below. That is, the first shell body 40 can also be constructed by forming the first divisional connection portion 41 and the reinforcement portion 42 separately from each other and joining these components to each other through welding or the like. Further, instead of the first divisional connection portion 41, the region corresponding to the connection portion 31 can also be made of the same material as the reinforcement portion 42 and formed integrally therewith to constitute the first shell body 40.
In the foregoing embodiment of the invention, the second shell body 50 is structured with the second divisional connection portion 54 and the scroll portion 51 made of the same material and formed integrally with each other. However, the structure of the shell body 50 can also be changed as will be described below. That is, the second shell body 50 can also be constructed by forming the second divisional connection portion 54 and the scroll portion 51 separately from each other and joining these components to each other through welding or the like. Further, instead of the second divisional connection portion 54, the region corresponding to the connection portion 31 can also be made of the same material as the scroll portion 51 and formed integrally therewith to constitute the second shell body 50.
In the foregoing embodiment of the invention, the first divisional connection portion 41 and the second divisional connection portion 54, which constitute the connection portion 31, are constructed as part of the first shell body 40 and part of the second shell body 50 respectively. However, the connection portion 31 can also be formed separately from the respective shell bodies. In this case, the first divisional connection portion 41 and the second divisional connection portion 54 can be formed separately from the respective shells and joined to each other to constitute the connection portion 31. Alternatively, the connection portion 31 with the first divisional connection portion 41 and the second divisional connection portion 54 formed separately from the respective shell bodies and joined to each other can also be formed as a single element serving as the connection portion 31.
In the foregoing embodiment of the invention, the slit portion 43 is formed in such a shape that one end face and the other end face of the reinforcement portion 42 extend parallel to each other. However, the slit portion 43 is not limited to this shape. For example, the slit portion 43 can also be formed in such a shape that the clearance between one end face and the other end face of the reinforcement portion 42 gradually increases from one end to the other end in the width direction of the reinforcement portion 42.
In the foregoing embodiment of the invention, the base body 60 is structured to include the four pillar portions 65 and the four communication portions 66. However, the number of the pillar portions 65 or the communication portions 66 can be changed to an integer between 1 and 3 or an integer equal to or larger than 5.
In the foregoing embodiment of the invention, as a structure for preventing the fragment of the turbine wheel 21 from hitting the thin-walled portion 32A, the pillar portions 65 are provided inside those of the tangential lines T1 and T2 of the turbine wheel 21 which pass both the end points of the slit portion 43 respectively. However, the concrete contents of the aforementioned structure are not limited as described above. For example, the pillar portions 65 can also be positioned such that only one of the tangential lines T1 and T2 passes the pillar portions 65. Further, in the foregoing embodiment of the invention, on the premise of the pillar portions 65 and the slit portion 43 that are dimensioned as shown in
In each of the foregoing embodiments of the invention, the turbine housing 11 is constructed with the-first shell body 40, the second shell body 50, the base body 60, the inlet flange 71, and the outlet flange 72 formed separately from one another and joined to one another. However, the turbine housing 11 is not limited to this construction. For example, at least one of the aforementioned respective structural bodies formed separately from one another can also be formed as a plurality of further divided structural bodies. Further, at least two of the aforementioned respective structural bodies except the first shell body 40 and the second shell body 50 can also be formed as a single structural body.
In each of the foregoing embodiments of the invention, the sheet metal shell bodies are adopted as the first shell body 40 and the second shell body 50. However, the first shell body 40 and the second shell body 50 can also be replaced with cast or resinous shell bodies.
In each of the foregoing embodiments of the invention, the cast base body is adopted as the base body 60. However, the base body 60 can also be replaced with a cast or resinous base body. In each of the foregoing embodiments of the invention, the invention is applied only to the former of the turbine housing 11 and the compressor housing 12. However, the invention can also be applied to the respective housings. Further, the invention can also be applied only to the compressor housing 12.
While the invention has been described with reference to the example embodiments thereof, it is to be understood that the invention is not limited to the described embodiments or constructions. To the contrary, the invention is intended to cover various modifications and equivalent arrangements. In addition, while the various elements of the disclosed invention are shown in various example combinations and configurations, other combinations and configurations, including more, less or only a single element, are also within the scope of the appended claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2010-023404 | Feb 2010 | JP | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/IB2011/000309 | 2/2/2011 | WO | 00 | 7/23/2012 |
