JP5181932B2 - Variable capacity turbocharger - Google Patents

Description

  The present invention relates to a variable capacity supercharger including a variable nozzle vane mechanism.

Conventionally, a compressor wheel is disposed on an air supply passage of an engine (internal combustion engine), and a turbine wheel sharing a rotation shaft with the compressor wheel is disposed on an exhaust passage, and excess intake air is exhausted using exhaust energy. There are known superchargers for feeding. In such a turbocharger, there is a turbocharger provided with a plurality of variable nozzle vanes at an exhaust inflow portion to a turbine wheel and a mechanism for improving turbine efficiency by controlling an exhaust inflow velocity to the turbine (for example, a patent) Reference 1).
In such a turbocharger, the compressor wheel on the air supply passage and the turbine wheel on the exhaust passage are connected by a rotating shaft, and the turbine wheel is rotated by using exhaust energy, via the rotating shaft. It is configured to perform supercharging by rotating the compressor wheel.

  FIG. 6 is a cross-sectional view of a variable capacity supercharger including a variable nozzle vane as an example of a conventional supercharger having the above-described configuration. That is, in the variable capacity supercharger 100 shown in FIG. 6, a plurality of variable nozzle vanes 102 provided at an exhaust inflow portion to the turbine wheel 101 are swingable by a pair of shroud plates 103 and 104 and are attached with variable opening. Yes. The shroud plates 103 and 104 are fixed to each other by a gap adjusting pin 108 at a constant interval, and one of the fixed shroud plates 103 (hereinafter referred to as a fixing shroud plate) is attached to a cover 106 attached to the turbine housing 105. It is fixed by a fixing bolt 107.

Further, a fixing structure between the fixing shroud plate 103 and the cover 106 will be specifically described. The fixing shroud plate 103 is formed in a ring shape arranged coaxially with the turbine central axis, and has an L shape in cross section. Then, the fixing bolt 107 is screwed into the plate thickness portion 103a corresponding to one side of the L shape along the turbine axial direction toward the thickness direction of the fixing shroud plate 101 (direction parallel to the axial direction of the turbine). A bolt hole 103b in which a female screw for mating is formed is provided. On the other hand, the cover 106 is provided with an insertion hole 106a through which the fixing bolt 107 is inserted at a position corresponding to the female screw. Then, the first shroud plate 103 and the cover 106 are fixed by inserting the fixing bolt 107 through the insertion hole 106a and screwing it into the female screw of the bolt hole 103b.
JP 2006-348892 A

However, the conventional variable capacity supercharger has the following problems.
That is, in the conventional shroud mechanism of the variable capacity supercharger shown in FIG. 6, the fixing screw 107 is simply fixed to the cover 106 at the female thread portion of the bolt hole 103 b formed in the fixing shroud plate 103. It was necessary to ensure a sufficient screw depth. Further, the bolt hole 103b is designed not to penetrate the fixing shroud plate 103 in the thickness direction in order to prevent the exhaust gas from leaking out of the cover 106 through the bolt hole 103b. The shroud plate 103 has a structure in which the thickness dimension of the portion (the plate thickness portion 103a) where the bolt hole 103b is provided is sufficiently secured.

  The shroud mechanism has a function of holding the variable nozzle vane in a swingable manner with a pair of shroud plates, and is advantageous in that processing is facilitated and manufacturing cost is reduced, or the entire turbocharger can be reduced in size. Therefore, the thickness dimension of the plate is required to be a thin flat plate structure in which the thickness dimension is uniform and thin over the entire circumference, and the pair of shroud plates have the same thickness dimension. However, when the shroud plate has a thin flat plate structure, there is a problem that it is difficult to fasten with a predetermined strength because there is a possibility that a sufficient thread depth as described above may not be secured.

  The present invention has been made in view of the above-described problems. The shroud mechanism can be securely fixed, and the shroud plate can be made thin, so that the apparatus can be reduced in size and weight and easy to process. The purpose is to provide a variable capacity supercharger.

  In order to achieve the above object, in the variable capacity supercharger according to the present invention, the turbine housing that houses therein the turbine wheel that is rotationally driven by exhaust gas, and the openings of a plurality of variable nozzle vanes arranged in the vicinity of the turbine wheel A variable capacity supercharger having a shroud mechanism that variably holds a pair of ring-shaped shroud plates, wherein a pair of ring-shaped shroud plates are opposed to each other with a predetermined spacing, and between the shroud plates. A plurality of variable nozzle vanes, and one fixing shroud plate has a pin member functioning as a bolt projecting in a direction substantially orthogonal to the side surface opposite to the surface where the pair of shroud plates face each other Is characterized by being integrated.

  In the present invention, one of the fixing shroud plates and the pin member having a bolt function are integrally fixed so that the supporting force of the pin member with respect to the fixing shroud plate is a screw structure. Accordingly, the pin member can be securely engaged with the turbine housing or a cover attached to the turbine housing. For example, the shroud mechanism can be fixed at a predetermined position by inserting a pin member into a turbine housing or a cover and fastening a nut to the tip of the pin. Therefore, in order to provide a bolt hole in which a female thread is formed in a fixing shroud plate as in the prior art, it is not necessary to have a structure that sufficiently secures the screw depth, and the fixing shroud plate is a thin flat plate, In addition, since the thickness dimension can be made uniform and the thickness dimension of the pair of shroud plates can be made the same, there is an advantage that the processing of the shroud plate is facilitated.

  In the variable capacity supercharger according to the present invention, the base end portion of the pin member is inserted in the thickness direction of the fixing shroud plate, and the peripheral portion of the insertion portion of the base end portion is caulked by the fixing shroud plate. It is preferable that the contact is made in a pressed state.

  In the present invention, with the base end portion of the pin member inserted through the fixing shroud plate, the fixing shroud plate is pressed in a direction substantially perpendicular to the thickness direction, and the periphery of the base end portion of the pin member is By crimping, the base end portion and the fixing shroud plate are fixed in pressure contact with each other, and the pin member and the fixing shroud plate can be integrated with each other. Thus, since the supporting force of the pin member is obtained and the screw processing to be formed on the fixing shroud plate is not required as in the prior art, the thickness dimension of the fixing shroud plate can be reduced.

  Further, in the variable capacity supercharger according to the present invention, a male screw is formed at the base end portion of the pin member, and a nut member for attaching the pin member by screwing the base end portion is provided. The member may be inserted in the thickness direction of the fixing shroud plate, and the insertion member peripheral portion of the nut member may be press-contacted in a state of being caulked by the fixing shroud plate.

  In the present invention, the fixing shroud plate is pressed in a direction substantially perpendicular to the thickness direction with the nut member screwed to the base end portion of the pin member inserted in the thickness direction of the fixing shroud plate. By caulking the periphery of the nut member positioned at the insertion portion, the nut member and the fixing shroud plate are fixed in pressure contact with each other, and the pin member and the fixing shroud plate are integrated with each other via the nut member. It can be made. Thus, since the supporting force of the pin member is obtained and the screw processing to be formed on the fixing shroud plate is not required as in the prior art, the thickness dimension of the fixing shroud plate can be reduced.

  In the variable capacity supercharger according to the present invention, the pin member has an outer diameter larger than the inner diameter of the through hole through which the base end portion penetrates in the thickness direction of the fixing shroud plate. It is preferable that the contact is made in a state of being press-fitted into the through hole of the fixing shroud plate.

  In the present invention, the base end of the pin member having an outer diameter larger than the inner diameter of the through hole formed in the fixing shroud plate is press-fitted into the through hole, so that the base end and the fixing shroud plate are pressed. And the pin member and the fixing shroud plate can be integrated with each other. Thus, since the supporting force of the pin member is obtained and the screw processing to be formed on the fixing shroud plate is not required as in the prior art, the thickness dimension of the fixing shroud plate can be reduced.

  Further, in the variable capacity supercharger according to the present invention, a male screw is formed at the base end portion of the pin member, and a nut member for attaching the pin member by screwing the base end portion is provided. The member may have an outer diameter larger than the inner diameter of the through hole penetrating in the thickness direction of the fixing shroud plate, and the nut member may be pressed into contact with the through hole of the fixing shroud plate.

  In the present invention, the nut member and the fixing shroud plate are press-fitted into the through hole with a nut member screwed to the base end of the pin member with an outer diameter larger than the inner diameter of the through hole of the fixing shroud plate. And the pin member and the fixing shroud plate can be integrated with each other via the nut member. Thus, since the supporting force of the pin member is obtained and the screw processing to be formed on the fixing shroud plate is not required as in the prior art, the thickness dimension of the fixing shroud plate can be reduced.

  According to the variable capacity supercharger of the present invention, by integrating the fixing shroud plate and the pin member having a bolt function among the pair of shroud plates, the supporting force of the pin member with respect to the fixing shroud plate is obtained. For example, the shroud mechanism can be securely fixed at a predetermined position by locking the pin member to the turbine housing. In addition, since the shroud plate can be made thin and flat, it is possible to reduce the size and weight of the apparatus and facilitate the processing, thereby reducing the manufacturing cost. .

Hereinafter, a variable capacity supercharger according to a first embodiment of the present invention will be described with reference to FIGS.
1 is a side sectional view showing a schematic configuration of a variable capacity supercharger according to a first embodiment of the present invention, FIG. 2 is an enlarged view of the shroud mechanism shown in FIG. 1, and FIG. 3 is a pin member of the shroud mechanism. FIG. 4 is a sectional view taken along line AA shown in FIG.

Reference numeral 1 in FIG. 1 indicates a variable capacity supercharger 1 according to the first embodiment provided in, for example, a vehicle engine (internal combustion engine).
As shown in FIG. 1, the variable capacity supercharger 1 has a compressor wheel 2 disposed on an air supply passage of an engine, and a turbine wheel 4 sharing the rotation shaft 3 with the compressor wheel 2 disposed on an exhaust passage. And has a known function of supercharging intake air using exhaust energy. In the first embodiment, in FIG. 1 to FIG. 3, the right side of the paper is the air supply side, and the left side of the opposite paper is the exhaust side.

  Specifically, the variable capacity supercharger 1 includes a center housing 5, a compressor housing 6 attached to one end of the center housing 5 on the air supply side (right side in FIG. 1), and an exhaust side (see FIG. The outer shell is formed from the turbine housing 7 attached to the other end of the left side 1), and the rotary shaft 3 having the compressor wheel 2 and the turbine wheel 4 at both ends passes through the center housing 5. It is arranged. That is, the rotary shaft 3 is supported so as to be rotatable with respect to the center housing 5 through the bearings 51 and 51 around the central axis. The compressor wheel 2 is housed in the compressor housing 6, while the turbine wheel 4 is housed in the turbine housing 7.

  As shown in FIG. 2, a scroll flow path F is formed in the turbine housing 7, and an annular exhaust gas flow path f is formed on the inner peripheral side of the scroll flow path F. The turbine housing 7 is fixed to the center housing 5 with bolts 52 and is disposed so as to surround the turbine wheel 4 so as to be spaced apart in the radial direction, and at a position closer to the supply side of the turbine housing 7 (closer to the center housing 5). A shroud mechanism 10 having a plurality of variable nozzle vanes 8, 8,.

  The shroud mechanism 10 includes a first shroud plate 11 and a second shroud plate 12 made of a pair of ring-shaped thin flat plates, which are arranged coaxially with respect to the central axis of the rotary shaft 3 while facing each other with a spacing therebetween. A plurality (15 in this case) of variable nozzle vanes 8, 8,... Are swingably held on the opposing surfaces of the shroud plates 11, 12. In addition, between these shroud plates 11 and 12, it corresponds with the position of the inflow port (exhaust gas flow path f) from the turbine wheel 4 to the scroll flow path F of the turbine housing 7. The shroud mechanism 10 is a composite in which a pair of shroud plates 11, 12, a plurality of variable nozzle vanes 8, 8,... And a link mechanism 14 for swinging the variable nozzle vanes 8, 8,. Yes.

  The first shroud plate 11 located on the exhaust side and the second shroud plate 12 located on the air supply side are fixed by a plurality of (five places in FIG. 4) gap adjusting pins 13, 13,. Yes. The gap adjusting pin 13 is used to keep the distance between the pair of shroud plates 11 and 12 constant. Each gap adjusting pin 13 is supported in a state where both end portions 13a and 13a thereof are inserted in the thickness direction of the respective shroud plates 11 and 12, respectively.

  A plurality of nozzle drive shafts 141 are inserted into and supported by the first and second shroud plates 11 and 12 in a rotatable state, and the nozzle drive shaft 141 is positioned at a position between the shroud plates 11 and 12. A variable nozzle vane 8 is fixed. That is, each variable nozzle vane 8 is supported on both shroud plates 11 and 12 via the nozzle drive shaft 141. The link mechanism 14 has a structure in which a plurality of links are assembled, and has a structure in which a plurality of nozzle drive shafts 141, 141,... (See FIG. 4) are axially rotated by actuators (not shown) via these links.

  In other words, each link is driven by the drive of the actuator, and each nozzle drive shaft 141 is rotated about the central axis, whereby each variable nozzle vane 8 connected to the nozzle drive shaft 141 is centered on the nozzle drive shaft 141. As a result, the opening degree of the variable nozzle vane 8 changes, and the amount of exhaust gas sucked can be changed to control the rotational speed of the turbine.

  As shown in FIGS. 2 and 3, the first shroud plate 11 is substantially orthogonal to the exhaust side surface 11a (the exhaust side surface opposite to the surface where the pair of shroud plates 11 and 12 face each other). A plurality of pin members (15 in FIG. 4) are provided at predetermined intervals in the circumferential direction of the plate, and have a bolt function in which a male screw 15b is formed at a tip portion protruding in the direction. That is, each pin member 15 is inserted into the bolt hole 7a formed in the turbine housing 7 in a state where the base end portion 15a is integrated with the first shroud plate 11, and the male screw 15b at the distal end portion of the pin member 15 is inserted into the turbine housing. 7 from the outside (exhaust side) of FIG. The nut 16 is screwed to the tip portion 15 b of the pin member 15 in a recess 7 b communicating with a bolt hole 7 a formed in the turbine housing 7.

As shown in FIG. 3, more specifically, the pin member 15 is integrally fixed to the first shroud plate 11 by caulking. That is, the first shroud plate 11 is formed with a through hole 11b for fitting the base end portion 15a of the pin member 15 in the thickness direction, and is inserted through the through hole 11b. By pressing the outer peripheral portion of the first shroud plate 11, a caulking portion K in a state where the proximal end portion 15 a of the pin member 15 is caulked from the periphery and pressed is formed. Thus, the base end portion 15a of the pin member 15 is in a state where a receiving surface for receiving the load of the shroud mechanism 10 is formed in the caulking portion K with the first shroud plate 11.
Here, as the material of the pin member 15, a material that is equivalent to the thermal expansion of the turbine housing 7 is adopted in consideration of a change in axial force due to thermal expansion.

  In addition, the through hole 11b of the first shroud plate 11 is formed with a tapered surface 11c whose inner diameter gradually increases toward the air supply side at the end position on the air supply side (opposing second shroud plate 12 side). ing. By forming the tapered surface 11c in the through hole 11b as described above, it becomes easy to caulk, and the first shroud plate 11 and the pin member 15 can be securely fixed and integrated.

Next, the operation of the variable capacity supercharger 1 described above will be described in detail with reference to the drawings.
As shown in FIG. 1 to FIG. 3, the first shroud plate 11, 12 out of the pair of shroud plates 11, 12 is fixed integrally with the first shroud plate 11 and the pin member 15 having a bolt function, thereby the first shroud. The supporting force of the pin member 15 with respect to the plate 11 can be reliably obtained without depending on the screw structure, and the pin member 15 can be locked to the turbine housing 7. That is, with the base end portion 15 a of the pin member 15 inserted through the first shroud plate 11, the first shroud plate 11 is pressed in a direction substantially orthogonal to the thickness direction, and the base end portion of the pin member 15 By caulking the periphery, the base end portion 15a and the first shroud plate 11 are fixed in pressure contact with each other, and the pin member 15 and the first shroud plate 11 can be integrated with each other.

Then, the shroud mechanism 10 can be fixed at a predetermined position by inserting the pin member 15 into the bolt hole 7a of the turbine housing 7 and fastening the nut 16 to the male screw 15b at the tip of the pin.
Therefore, in order to provide a bolt hole in which a female thread is formed in the shroud plate as in the prior art, it is not necessary to have a structure that sufficiently secures the screw depth, and the first shroud plate 11 has a thin plate shape, and Since the thickness dimension can be made uniform and the thickness dimension of the pair of shroud plates 11 and 12 can be made the same, there is an advantage that the processing of the shroud plates 11 and 12 becomes easy. is there.

In the variable capacity supercharger according to the first embodiment described above, the first shroud plate 11 and the pin member 15 having a bolt function of the pair of shroud plates 11 and 12 are integrated to form the first shroud plate. 11, the pin member 15 can be locked to the turbine housing 7 and the shroud mechanism 10 can be reliably fixed at a predetermined position.
Further, since the shroud plates 11 and 12 can be made thin to have a flat plate shape, the apparatus can be reduced in size and weight, and processing can be facilitated, thereby reducing the manufacturing cost. be able to.

Next, another embodiment of the variable capacity supercharger according to the present invention will be described with reference to the accompanying drawings. The same reference numerals are used for the same or similar members and parts as those in the first embodiment. A description will be omitted, and a configuration different from that of the first embodiment will be described.
FIG. 5 is a partial side sectional view showing a schematic configuration of a variable capacity supercharger according to the second embodiment.

  As shown in FIG. 5, the variable capacity supercharger 1 according to the second embodiment includes a nut member 18 between a pin member 17 having a bolt shape and a first shroud plate 11 (fixing shroud plate). In the first embodiment, the nut member 18 is press-fitted into the first shroud plate 11 and the pin member 15 and the first shroud plate 11 are directly fixed and integrated. This structure is different (see FIG. 2).

  Specifically, a male screw is formed on the base end portion 17a of the pin member 17 in the variable capacity supercharger 1, and this base end portion 17a is screwed to the female screw 18a of the nut member 18 and this state The nut member 18 is press-contacted in a state of being press-fitted into the through hole 11d of the first shroud plate 11. That is, the nut member 18 has an outer diameter that is larger than the inner diameter of the through hole 11 d that penetrates the first shroud plate 11 in the thickness direction. As a result, the press-fitted nut member 18 and the first shroud plate 11 are integrally fixed to each other. The pin member 17 is configured such that the pin head portion 17 b is received in the recess 7 b of the turbine housing 7 in a state where the pin member 17 is tightened to the nut member 18. In addition, the code | symbol P of FIG. 5 has shown the press injection part.

  As described above, in the second embodiment, by forming the press-fit portion P between the nut member 18 and the first shroud plate 11, the support force of the pin member 17 is obtained, and the shroud is conventionally provided. Since the screw processing to be formed on the plate becomes unnecessary, the thickness dimension of the first shroud plate 11 can be reduced, and the same effect as the first embodiment described above can be obtained.

As mentioned above, although embodiment of the variable capacity | capacitance supercharger by this invention was described, this invention is not limited to said embodiment, In the range which does not deviate from the meaning, it can change suitably.
For example, in the first embodiment, the pin member 15 and the first shroud plate 11 are integrated by caulking, and in the second embodiment, the first nut member 18 and the first nut member 18 are screwed together by press fitting. The shroud plate 11 is integrated with the shroud plate 11, but any of a caulking method and a press-fitting method may be used.

  That is, in the first embodiment, the pin member 15 of the shroud mechanism 10 is caulked and integrated with the first shroud plate 11, but the present invention is not limited to this. For example, the base end portion 15a of the pin member 15 is set to have an outer diameter larger than the inner diameter size of the through hole 11b penetrating in the thickness direction of the first shroud plate 11, and the base end portion 15a of the pin member 15 is changed to the through hole 11b. A fixing structure in which the pin member 15 and the first shroud plate 11 are integrated with each other by press-fitting in a press-fitted state may be used, and thereby a support force for the pin member 15 can be obtained, and a fixing shroud can be obtained as in the past. Since the screw processing to be formed on the plate is not required and the thickness dimension of the first shroud plate 11 can be reduced, the same effect as that of the first embodiment described above can be obtained (see FIG. 2).

  In the second embodiment, the nut member 18 in which the base end portion 17a of the pin member 17 is screwed is press-fitted into the first shroud plate 11 to be integrated. However, the present invention is limited to this. There is no. For example, the first shroud plate 11 is substantially orthogonal to the thickness direction with the nut member 18 screwed into the base end portion 17a of the pin member 17 being inserted into the through hole 11d of the first shroud plate 11. The nut member 18 and the first shroud plate 11 are fixed in a pressed state by pressing in the direction and caulking the periphery of the nut member 18 located at the insertion portion, and the pin member 17 and the first shroud plate 11 are fixed. Can be integrated with each other via the nut member 18, and the supporting force of the pin member 17 can be obtained in the same manner as in the second embodiment described above, and the threading formed on the fixing shroud plate as in the prior art can be performed. Since it becomes unnecessary, the thickness dimension of the 1st shroud plate 11 can be made thin.

In the second embodiment, the pin member 17 screwed into the nut member 18 is a bolt-shaped member. However, the present invention is not limited to this, and is the same as the pin member 15 of the first embodiment. Alternatively, a rod-like member having a male screw formed at the tip may be used.
Further, in the first and second embodiments, the shroud mechanism 10 is fixed to the turbine housing 7. However, the present invention is not limited to this. For example, the shroud mechanism 10 ( The pin members 15, 17) may be fixed.
Furthermore, the structure of the link mechanism 14 and the configuration such as the number and size of the variable nozzle vane 8 and the gap adjusting pin 13 are not limited to the present embodiment, and can be appropriately set according to the performance of the turbine. .

1 is a side sectional view showing a schematic configuration of a variable capacity supercharger according to a first embodiment of the present invention. It is an enlarged view of the shroud mechanism shown in FIG. It is a principal part enlarged view which shows the pin member of a shroud mechanism. It is the sectional view on the AA line shown in FIG. It is a fragmentary sectional side view which shows schematic structure of the variable capacity | capacitance supercharger by 2nd Embodiment. It is an example of the conventional supercharger, and is sectional drawing of the variable capacity | capacitance supercharger provided with the variable nozzle mechanism.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Variable capacity supercharger 2 Compressor wheel 3 Rotating shaft 4 Turbine wheel 5 Center housing 6 Compressor housing 7 Turbine housing 7a Bolt hole 8 Variable nozzle vane 10 Shroud mechanism 11 1st shroud plate (fixing shroud plate)
11b, 11d Through hole 12 Second shroud plate 13 Gap adjusting pin 14 Link mechanism 15, 17 Pin member 15a, 17a Base end 15b Male thread 16 Nut 18 Nut member K Caulking part P Press fitting part

Claims (3)

A variable capacity turbocharger comprising a turbine housing that houses therein a turbine wheel that is rotationally driven by exhaust gas, and a shroud mechanism that variably holds the opening degrees of a plurality of variable nozzle vanes disposed in the vicinity of the turbine wheel Because
The shroud mechanism is configured such that a pair of ring-shaped shroud plates are opposed to each other with a predetermined spacing, and a plurality of the variable nozzle vanes are provided between the shroud plates.
One fixing shroud plate is integrated with a pin member having a function of a bolt protruding in a direction substantially orthogonal to a side surface opposite to a surface where the pair of shroud plates face each other .
The pin member has its base end portion inserted in the thickness direction of the fixing shroud plate, and the insertion portion peripheral portion of the base end portion is pressed in a state of being caulked by the fixing shroud plate. Characteristic variable capacity turbocharger. A variable capacity turbocharger comprising a turbine housing that houses therein a turbine wheel that is rotationally driven by exhaust gas, and a shroud mechanism that variably holds the opening degrees of a plurality of variable nozzle vanes disposed in the vicinity of the turbine wheel Because
The shroud mechanism is configured such that a pair of ring-shaped shroud plates are opposed to each other with a predetermined spacing, and a plurality of the variable nozzle vanes are provided between the shroud plates.
One fixing shroud plate is integrated with a pin member having a function of a bolt protruding in a direction substantially orthogonal to a side surface opposite to a surface where the pair of shroud plates face each other.
A male screw is formed at the base end of the pin member,
A nut member for attaching the pin member by screwing the base end portion is provided,
The variable capacity supercharging characterized in that the nut member is inserted in the thickness direction of the fixing shroud plate, and a peripheral portion of the insertion portion of the nut member is pressed in a state of being caulked by the fixing shroud plate Machine. A variable capacity turbocharger comprising a turbine housing that houses therein a turbine wheel that is rotationally driven by exhaust gas, and a shroud mechanism that variably holds the opening degrees of a plurality of variable nozzle vanes disposed in the vicinity of the turbine wheel Because
The shroud mechanism is configured such that a pair of ring-shaped shroud plates are opposed to each other with a predetermined spacing, and a plurality of the variable nozzle vanes are provided between the shroud plates.
One fixing shroud plate is integrated with a pin member having a function of a bolt protruding in a direction substantially orthogonal to a side surface opposite to a surface where the pair of shroud plates face each other.
A male screw is formed at the base end of the pin member,
A nut member for attaching the pin member by screwing the base end portion is provided,
The nut member has an outer diameter dimension larger than an inner diameter dimension of a through-hole penetrating in the thickness direction of the fixing shroud plate,
The variable capacity supercharger, wherein the nut member is press-contacted in a state of being press-fitted into the through hole of the fixing shroud plate .

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