JP6368253B2 - Variable nozzle turbine - Google Patents

Description

  The present invention relates to a variable nozzle turbine capable of changing the opening degree and direction of a nozzle that injects a working fluid to a turbine impeller.

  Conventionally, variable nozzle turbines are mounted on automobiles and ships. The variable nozzle turbine is driven by, for example, exhaust gas from an engine. For example, Patent Document 1 discloses a variable nozzle turbine 100 as shown in FIGS. 6 and 7.

  Specifically, the variable nozzle turbine 100 includes a shroud 140 and a cover 150 that forms a link chamber 160 between the shroud 140. The variable nozzle turbine 100 includes a plurality of nozzle members 110 (only one is shown in FIGS. 6 and 7) having a shaft portion 112 and a nozzle vane 111 that penetrate the shroud 140, and each of the nozzle members 110 disposed in the link chamber 160. A link mechanism 120 for rotating the nozzle member 110 around the shaft portion 112 is included.

  The link mechanism 120 includes a plurality of arms 121 that are non-rotatably connected to the shaft portion 112 of the nozzle member 110 and a ring 123 that is connected to a lever that penetrates the cover 150. Each arm 121 is provided with a pin 122 extending in parallel with the shaft portion 112 of the nozzle member 110, while the ring 123 is provided with an elongated hole 124 that engages with the pin 122. That is, both ends of the long hole 124 function as stoppers that define the maximum opening and the minimum opening of the nozzle.

Japanese Utility Model Publication No. 61-197224

  However, in the structure as shown in FIGS. 6 and 7, in order to change either or both of the maximum opening and the minimum opening of the nozzle, an operation such as removing the cover 150 and replacing the ring 123 is performed. I need it.

  Then, an object of this invention is to provide the variable nozzle turbine which can change at least one of the maximum opening degree and minimum opening degree of a nozzle from the outer side of a cover.

  In order to solve the above problems, a variable nozzle turbine according to the present invention includes a plurality of nozzle members including nozzle vanes arranged in an introduction path around a turbine impeller, and a shaft portion extending from the nozzle vanes, and the plurality of nozzle members. Each of which is connected to the link mechanism through a shaft member penetrating the cover, a link forming a link chamber in which the link mechanism is disposed, An input lever, a rod that penetrates the cover, a rod having a tip that contacts the link mechanism when the input lever is operated, and a fixing member that fixes the rod to the cover outside the cover A fixing member capable of changing a rod fixing position for determining a distance from the cover to the tip of the rod; Further comprising, wherein the.

  According to the above configuration, the rod having the tip that contacts the link mechanism when the input lever is operated is fixed to the cover outside the cover by the fixing member, and the rod fixing position can be changed. At least one of the maximum opening and the minimum opening of the nozzle can be changed from the outside.

  The link mechanism may include an input link that is connected to the shaft member and swings around the shaft member, and a tip of the rod may contact the input link when the input lever is operated. . According to this configuration, the link mechanism can have a simple structure.

  The variable nozzle turbine further includes a plate that extends along the introduction path and extends behind the turbine impeller, wherein the shaft portion of the plurality of nozzle members penetrates the plate, and the cover includes the plate You may form the said link chamber in the back side of. According to this configuration, the space on the back side of the plate can be rationally used as a link chamber.

  The rod may be a maximum opening regulating rod that contacts the link mechanism when the input lever is operated in a direction to increase the opening of the nozzle. According to this configuration, the maximum opening of the nozzle can be changed from the outside of the cover.

  The rod has a maximum opening regulating rod that contacts the link mechanism when the input lever is operated in a direction to increase the opening of the nozzle, and the input lever is operated in a direction to reduce the opening of the nozzle. Both of them may be both minimum opening regulating rods that come into contact with the link mechanism. According to this configuration, both the maximum opening and the minimum opening of the nozzle can be changed from the outside of the cover.

  The link mechanism is attached to a plurality of arms extending laterally from the shaft portion and connected to shaft portions of the plurality of nozzle members, respectively, and ends of the plurality of arms opposite to the nozzle members. A plurality of rollers, and a link ring having a plurality of operation pieces that are interposed between the plurality of rollers and guide the movement of the rollers in the radial direction around the axis of the turbine impeller. But you can. According to this configuration, since the roller attached to the arm rolls on the operation piece of the link ring, wear of the arm and the link ring is suppressed, and high durability can be obtained.

  The rod may be a bolt that is screwed into a screw hole provided in the cover, and the fixing member may be a nut that is screwed into the bolt. According to this configuration, the distance from the cover to the tip of the rod can be finely adjusted by the rotation of the rod.

  According to the present invention, at least one of the maximum opening and the minimum opening of the nozzle can be changed from the outside of the cover.

It is sectional drawing of the variable nozzle turbine which concerns on one Embodiment of this invention. It is a front view of a part of nozzle member and a link mechanism, and shows a state where an input lever is at a reference position. It is a front view of a part of nozzle member and a link mechanism, and shows a state where the input lever is tilted from the reference position in the direction of increasing the opening degree of the nozzle. It is sectional drawing along the IV-IV line of FIG. It is sectional drawing along the VV line of FIG. It is a sectional view of a part of a conventional variable nozzle turbine. It is a rear view of a part of link mechanism of the variable nozzle turbine shown in FIG.

  FIG. 1 shows a variable nozzle turbine 1 according to an embodiment of the present invention. The variable nozzle turbine 1 is mounted on, for example, an automobile or a ship and driven by exhaust gas from an engine. However, the variable nozzle turbine 1 may be driven by other working fluid such as steam.

  The variable nozzle turbine 1 includes a turbine impeller 32, a rotating shaft 31 to which the turbine impeller 32 is attached, and a first housing 34 that rotatably supports the rotating shaft 31 via a bush 39. The variable nozzle turbine 1 also includes a plate 35 and a shroud 21 that form the introduction path 24 around the turbine impeller 32, and a second housing 26 that forms a spiral chamber 25 that communicates with the introduction path 24. Hereinafter, for the sake of convenience of explanation, the radial direction around the axis 33 of the turbine impeller 32 is simply referred to as “radial direction R”, and the direction in which the axial center 33 extends is simply referred to as “axial direction X”.

  The introduction path 24 is an annular flow path parallel to the radial direction R. A working fluid (for example, exhaust gas from the engine) is supplied to the spiral chamber 25. The working fluid supplied to the spiral chamber 25 is blown to the turbine impeller 32 through the introduction path 24.

  The plate 35 extends along the introduction path 24 and on the back side of the turbine impeller 32. The plate 35 may be a single plate or may be divided into a plurality of plates. The plate 35 is fixed to the first housing 34.

  The shroud 21 includes a flange portion 23 that faces the plate 35 across the introduction path 24, and a tubular portion 22 that extends from the inner end of the flange portion 23 to the opposite side of the plate 35. That is, the tubular portion 22 constitutes a working fluid discharge port in the variable nozzle turbine 1.

  Further, the variable nozzle turbine 1 includes a plurality of nozzle members 5 disposed at equiangular intervals around the turbine impeller 32 and a link mechanism 6 disposed on the back side of the plate 35. An annular link chamber 36 is formed on the back side of the plate 35 by the cover 4, and the link mechanism 6 is disposed in the link chamber 36. The link mechanism 6 is connected to the input lever 81 via a shaft member 82 that penetrates the cover 4.

  In the present embodiment, the cover 4 is formed integrally with the first housing 34. Specifically, as shown in FIGS. 2 to 5, the cover 4 includes a bottom wall 4 a extending in the radial direction R from the first housing 34, and an axial direction X from the outer peripheral edge of the bottom wall 4 a toward the plate 35. An extending peripheral wall 4b is included.

  As shown in FIGS. 2 to 5, each nozzle member 5 includes a nozzle vane 51 disposed in the introduction path 24, and a shaft portion 52 extending in the axial direction X from the nozzle vane 51 through the plate 35 and into the link chamber 36. Including. The shaft portion 52 is rotatably supported by the plate 35 via the bush 53. However, the bush 53 can be omitted.

  Between adjacent nozzle vanes 51, nozzles 50 for injecting working fluid to the turbine impeller 32 are formed. 2 shows a state in which the above-described input lever 81 is in the reference position, and FIG. 3 shows a state in which the input lever 81 is tilted from the reference position in the direction of increasing the opening degree of the nozzle 50 (of course, the input lever 81 81 may be tilted from the reference position in a direction to reduce the opening of the nozzle 50). By operating the input lever 81, the opening degree and direction of the nozzle 50 are changed.

  The link mechanism 6 is for rotating each nozzle member 5 around the shaft portion 52. Specifically, the link mechanism 6 includes a plurality of arms 61, a link ring 65 disposed on the opposite side of the plate 35 with respect to the arms 61, and an input disposed on the opposite side of the plate 35 with respect to the link ring 65. Includes link 7.

  Each arm 61 extends laterally from the shaft portion 52 of the nozzle member 5 (in this embodiment, inward in the radial direction R). The outer end portion of each arm 61 is non-rotatably connected to the shaft portion 52 of the nozzle member 5. A roller 62 is attached to the inner end of each arm 61 (that is, the end opposite to the nozzle member 5).

  In the present embodiment, each roller 62 includes a disk-shaped wheel portion 63 and a shaft portion 64 that extends in the axial direction X from the center of the wheel portion 63. The shaft portion 64 is rotatably supported on the inner end portion of the arm 61. However, the roller 62 may have a ring shape having a through hole at the center, and the roller 62 may be attached to the arm 61 via a shaft member (not shown) that rotatably supports the roller 62.

  The link ring 65 includes a main body portion 66 that is continuous in the circumferential direction, and a plurality of operation pieces 67 that protrude from the main body portion 66. In the present embodiment, the main body 66 has a thin plate shape in the axial direction X, and the operation piece 67 protrudes from the main surface of the main body 66 on the plate 35 side in the axial direction X. However, the link ring 65 may be arranged on the inner side of the arm 61 so that the operation piece 67 protrudes outward in the radial direction R from the main body portion 66.

  The operation piece 67 is interposed between the plurality of rollers 62 and is configured to guide the movement of the roller 62 in the radial direction R. Specifically, each operation piece 67 has a trapezoidal shape that tapers inward in the radial direction R, and side surfaces of the adjacent operation pieces 67 facing each other are parallel to each other.

  A guide ring 37 that is slidably fitted to the link ring 65 is disposed inside the link ring 65. The guide ring 37 is fixed to the first housing 34. The guide ring 37 is formed with a recess 37 a that engages with the inner end of the main body 66 of the link ring 65. The guide ring 37 is attached with a presser ring 38 for holding the inner end of the main body 66 of the link ring 65 in the recess 37a.

  The input link 7 is non-rotatably connected to the shaft member 82 described above. The shaft member 82 extends in the axial direction X through the bottom wall 4 a of the cover 4, and is fixed to the input lever 81. The shaft member 82 is rotatably supported by a bearing member 83 attached to the bottom wall 4 a of the cover 4. That is, the input link 7 swings around the shaft member 82.

  The input link 7 extends from the shaft member 82 to the position overlapping the link ring 65 in the radial direction R, and an opening 71 that opens inward in the radial direction R is formed at the inner end of the input link 7. . In other words, the input link 7 has a pair of engagement pieces 72 that define the opening 71.

  On the other hand, an input roller 69 that engages with the opening 71 of the input link 7 is attached to the link ring 65 via a shaft member 68. In the present embodiment, a screw hole is formed in a thick portion where one operation piece 67 in the link ring 65 is provided, and a screw thread formed at one end of the shaft member 68 is screwed into this screw hole. Yes. The input roller 69 is rotatably supported by the shaft member 68.

  With this configuration, when the input lever 81 is operated, as shown in FIG. 3, the input link 7 swings and the link ring 65 rotates while the input roller 69 rolls on one engagement piece 72. To do. Accordingly, the roller 62 attached to each arm 61 moves in the radial direction R while rolling on one side surface of the operation piece 67 of the link ring 65. When the roller 62 moves in the radial direction, each arm 61 swings around the shaft portion 52 of the nozzle member 5 and the angle of the nozzle vane 51 of the nozzle member 5 is changed. Thereby, the opening degree and direction of the nozzle 50 are changed. Thus, in the variable nozzle turbine 1 of the present embodiment, the roller 62 attached to the arm 61 rolls on the operation piece 67 of the link ring 65, so that wear of the arm 61 and the link ring 65 is suppressed, and high durability is achieved. Sex can be obtained.

  Furthermore, in this embodiment, the structure for restrict | limiting the opening degree of the nozzle 50 is employ | adopted. Specifically, the variable nozzle turbine 1 includes a maximum opening degree defining rod 41 and a minimum opening degree regulating rod 42 that penetrate the peripheral wall 4 b of the cover 4.

  As shown in FIG. 2, the input link 7 is provided with a pair of protrusions 73 and 74 that project outward from the engagement piece 72 in a direction orthogonal to the opening direction of the opening 71. The maximum opening defining rod 41 and the minimum opening defining rod 42 are arranged at positions corresponding to the protrusions 73 and 74.

  In the present embodiment, the maximum opening degree defining rod 41 and the minimum opening degree defining rod 42 extend in parallel with the radial direction R passing through the center of the shaft member 82. When the input lever 81 is operated in a direction to increase the opening degree of the nozzle 50, one of the input links 7 (the right side in FIG. 2) protrudes in a direction approaching the peripheral wall 4b of the cover 4, and the protrusion 73 Comes into contact with the tip of the maximum opening degree defining rod 41, and the swinging of the input link 7 is restricted. On the contrary, when the input lever 81 is operated in a direction to reduce the opening of the nozzle 50, the other projection 74 on the other side (left side in FIG. 2) of the input link 7 moves in a direction approaching the peripheral wall 4b of the cover 4, The swing of the input link 7 is restricted by the protrusion 74 coming into contact with the tip of the minimum opening regulating rod 42.

  The maximum opening degree defining rod 41 is fixed to the peripheral wall 4 b of the cover 4 by the first fixing member 43 outside the cover 4. The first fixing member 43 is configured to be able to change the rod fixing position that determines the distance from the peripheral wall 4 b of the cover 4 to the tip of the maximum opening degree defining rod 41.

  The minimum opening regulating rod 42 is fixed to the peripheral wall 4 b of the cover 4 by the second fixing member 44 outside the cover 4. The second fixing member 44 is configured to be able to change the rod fixing position that determines the distance from the peripheral wall 4 b of the cover 4 to the tip of the minimum opening degree defining rod 42.

  In the present embodiment, two screw holes 45 are provided in the peripheral wall 4 b of the cover 4. Each of the maximum opening defining rod 41 and the minimum opening defining rod 42 is a bolt that is screwed into the screw hole 45, and each of the first fixing member 43 and the second fixing member 44 is screwed into the bolt. It is a nut.

  As described above, in the variable nozzle turbine 1 of the present embodiment, the maximum opening degree defining rod 41 and the minimum opening degree defining rod 42 having the tips that come into contact with the projecting portions 73 and 74 of the input link 7 are the first fixing member 43. Since the rod fixing position is fixed to the cover 4 outside the cover 4 by the second fixing member 44 and the rod fixing position can be changed, both the maximum opening and the minimum opening of the nozzle can be changed from the outside of the cover 4. it can.

  In the present embodiment, the maximum opening degree defining rod 41 and the minimum opening degree regulating rod 42 are bolts that are screwed into the screw holes 45 provided in the cover 4. By the rotation of the degree defining rod 42, the distances from the peripheral wall 4b of the cover 4 to the tips of the maximum opening defining rod 41 and the minimum opening defining rod 42 can be finely adjusted.

(Modification)
The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the gist of the present invention.

  For example, the tips of the maximum opening defining rod 41 and the minimum opening defining rod 42 do not necessarily have to abut against the protrusions 73 and 74 of the input link 7 when the input lever 81 is operated. You may contact | abut to another element. For example, instead of the projecting portions 73 and 74 of the input link 7, the link ring 65 is provided with a projecting portion projecting outward in the radial direction R, and the maximum opening defining rod 41 and the minimum opening defining member are provided on the projecting portion. The tip of the rod 42 may abut. Alternatively, the link mechanism 6 includes a rod-shaped member that is fixed to the end surface of the shaft member 82 and extends in a direction orthogonal to the radial direction R instead of the projecting portions 73 and 74 of the input link 7. The tips of the opening degree defining rod 41 and the minimum opening degree regulating rod 42 may contact each other. However, the link mechanism 6 can have a simple structure as long as the tips of the maximum opening degree defining rod 41 and the minimum opening degree regulating rod 42 abut on the input link 7 as in the above embodiment.

  Further, each of the maximum opening degree defining rod 41 and the minimum opening degree defining rod 42 is not necessarily a bolt, and may be a simple round bar. In this case, the fixing member may be a set screw. Alternatively, the fixing member may be an engaging member that engages with one of a plurality of notches formed on the outer peripheral surface of the round bar.

  In the above-described embodiment, both the maximum opening degree defining rod 41 and the minimum opening degree defining rod 42 are provided. However, only one of the maximum opening degree defining rod 41 and the minimum opening degree defining rod 42 is provided. May be. In this regard, the opening degree of the nozzle 50 becomes zero when the nozzle member 5 is rotated until the adjacent nozzle vanes 51 come into contact with each other, so that at least the maximum opening degree defining rod 41 is preferably provided.

  The arm 61 does not necessarily extend inward in the radial direction R from the shaft portion 52 of the nozzle member 5, and may extend outward in the radial direction R from the shaft portion 52 of the nozzle member 5. Alternatively, the arm 61 may extend obliquely inward or obliquely outward with respect to the radial direction R from the shaft portion 52.

  Further, the guide ring 37 is not necessarily disposed inside the link ring 65, and may be disposed outside the link ring 65. In this case, the link ring 65 may be configured such that the operation piece 67 protrudes inward in the radial direction R from the main body portion 66. Alternatively, the guide ring 37 may be omitted, and the link ring 65 may be directly fitted to the first housing 34.

  Further, the link mechanism 6 does not necessarily have to be disposed on the back side of the plate 35, and is disposed on the opposite side to the introduction path 24 with respect to the flange portion 23 of the shroud 21, as in the configuration shown in FIGS. May be. However, if the link mechanism 6 is disposed on the back side of the plate 35 as in the above embodiment, the space on the back side of the plate 35 can be rationally utilized as the link chamber 36.

  Further, various configurations other than those described above can be employed as the configuration of the link mechanism 6. For example, the link mechanism 6 may be provided with a pin that cannot rotate, instead of the rollers 62 and 69.

DESCRIPTION OF SYMBOLS 1 Variable nozzle turbine 24 Introductory path 32 Turbine impeller 33 Shaft center 35 Plate 36 Link chamber 4 Cover 41 Maximum opening regulation rod 42 Minimum opening regulation rod 43,44 Fixing member 45 Screw hole 5 Nozzle member 51 Nozzle vane 52 Shaft part 6 Link Mechanism 61 Arm 62 Roller 65 Link ring 67 Operation piece 7 Input link 81 Input lever 82 Shaft member

Claims (7)

A plurality of nozzle members including a nozzle vane disposed in an introduction path around the turbine impeller, and a shaft portion extending from the nozzle vane;
A link mechanism for rotating each of the plurality of nozzle members around the shaft portion;
A cover forming a link chamber in which the link mechanism is disposed;
An input lever connected to the link mechanism via a shaft member penetrating the cover;
A rod penetrating the cover, the rod having a tip that comes into contact with the link mechanism when the input lever is operated;
A fixing member for fixing the rod to the cover outside the cover, and a fixing member capable of changing a rod fixing position for determining a distance from the cover to the tip of the rod;
A variable nozzle turbine comprising: The link mechanism includes an input link connected to the shaft member and swinging around the shaft member;
The variable nozzle turbine according to claim 1, wherein a tip of the rod comes into contact with the input link when the input lever is operated. A plate that extends along the introduction path and spreads behind the turbine impeller;
The variable nozzle turbine according to claim 1, wherein the shaft portion of the plurality of nozzle members penetrates the plate, and the cover forms the link chamber on a back side of the plate.   The variable according to any one of claims 1 to 3, wherein the rod is a maximum opening defining rod that contacts the link mechanism when the input lever is operated in a direction to increase the opening of the nozzle. Nozzle turbine.   The rod has a maximum opening regulating rod that contacts the link mechanism when the input lever is operated in a direction to increase the opening of the nozzle, and the input lever is operated in a direction to reduce the opening of the nozzle. The variable nozzle turbine according to any one of claims 1 to 3, which is both a minimum opening degree defining rod that comes into contact with the link mechanism when it comes into contact. The link mechanism is
A plurality of arms extending laterally from the shaft, each connected to a shaft of the plurality of nozzle members;
A plurality of rollers respectively attached to ends of the plurality of arms opposite to the nozzle member;
A link ring having a plurality of operation pieces that are interposed between the plurality of rollers and guide the movement of the rollers in a radial direction around the axis of the turbine impeller;
The variable nozzle turbine according to claim 1, comprising: The rod is a bolt that is screwed into a screw hole provided in the cover,
The variable nozzle turbine according to any one of claims 1 to 6, wherein the fixing member is a nut that is screwed into the bolt.

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