JP2019052585A - Actuator for variable compression ratio mechanism for internal combustion engine - Google Patents

Abstract

To provide an actuator for a variable compression ratio mechanism for an internal combustion engine that can regulate a fixing angle of a fixing component for a harness.SOLUTION: An actuator includes: a harness clip 7 fixed at an outside surface of a housing 20 and holding a harness 204; and a guide wall 71 formed into a convex shape at the outside surface of the housing 20 integrally with a gate seat 15 that is formed at the time of cast molding the housing 20 and regulating a fixing angle of the harness clip 7.SELECTED DRAWING: Figure 8

Description

  The present invention relates to an actuator for a variable compression ratio mechanism of an internal combustion engine.

  Patent Document 1 discloses an actuator having an arm link that changes the attitude of a variable compression ratio mechanism of an internal combustion engine, a control shaft fixed to the arm link, and a housing that houses the control shaft.

JP-A-2015-145647

When the harness from the rotation angle sensor is fixed to the housing, the fixing angle of the fixing component that holds the harness may move.
One of the objects of the present invention is to provide an actuator for a variable compression ratio mechanism of an internal combustion engine that can regulate the fixing angle of a fixing component of a harness.

  An actuator of a variable compression ratio mechanism for an internal combustion engine according to an embodiment of the present invention is integrally formed with a fixed part that is fixed to an outer surface of a housing and holds a harness, and a gate seat that is formed when the housing is cast. And a guide wall that regulates the fixing angle of the fixed component.

  Therefore, according to the preferable aspect of this invention, the fixing angle of the fixing component of a harness can be controlled.

1 is a schematic view of an internal combustion engine provided with a variable compression ratio mechanism of Embodiment 1. FIG. FIG. 3 is an exploded perspective view of the actuator according to the first embodiment. FIG. 3 is a perspective view of the actuator according to the first embodiment. FIG. 3 is a plan view of the actuator according to the first embodiment. It is S1-S1 arrow sectional drawing of FIG. 1 is an exploded perspective view of a wave gear reducer according to Embodiment 1. FIG. FIG. 3 is a left side view of the actuator according to the first embodiment. FIG. 3 is an enlarged view of a main part of the front surface of the actuator according to the first embodiment. FIG. 3 is an enlarged view of a main part of the left side surface of the actuator according to the first embodiment. FIG. 3 is a front view of the housing according to the first embodiment.

Embodiment 1
FIG. 1 is a schematic view of an internal combustion engine including the variable compression ratio mechanism according to the first embodiment. The basic configuration is the same as that described in FIG. 1 of Japanese Patent Laid-Open No. 2011-169251, and will be described briefly.
The piston 1 reciprocates in a cylinder of a cylinder block in an internal combustion engine (gasoline engine). The upper end of the upper link 3 is rotatably connected to the piston 1 via a piston pin 2. A lower link 5 is rotatably connected to the lower end of the upper link 3 via a connecting pin 6. A crankshaft 4 is rotatably connected to the lower link 5 via a crankpin 4a. An upper end portion of the first control link 7 is rotatably connected to the lower link 5 via a connecting pin 8. A lower end portion of the first control link 7 is connected to a connecting mechanism 9 having a plurality of links. The connection mechanism 9 includes a first control shaft 10, a second control shaft (control shaft) 11, a second control link 12, and an arm link 13.

  The first control shaft 10 is disposed in parallel to the crankshaft 4 disposed along the cylinder row direction inside the internal combustion engine. The first control shaft (first shaft portion) 10 includes a first journal portion 10a, a control eccentric shaft portion 10b, an eccentric shaft portion 10c, a first arm portion 10d, and a second arm portion 10e. The first journal portion 10a is rotatably supported by the internal combustion engine body. The control eccentric shaft portion 10b is rotatably connected to the lower end portion of the first control link 7. The eccentric shaft portion 10c is rotatably connected to one end portion 12a of the second control link (first link) 12. One end of the first arm portion 10d is connected to the first journal portion 10a. The other end of the first arm portion 10d is connected to the control eccentric shaft portion 10b. The control eccentric shaft portion 10b is located at a position offset by a predetermined amount with respect to the first journal portion 10a. One end of the second arm portion 10e is connected to the first journal portion 10a. The other end of the second arm portion 10e is connected to the eccentric shaft portion 10c. The eccentric shaft portion 10c is at a position that is eccentric by a predetermined amount with respect to the first journal portion 10a. One end of the arm link 13 is rotatably connected to the other end portion 12b of the second control link 12. The other end of the arm link 13 is connected to the second control shaft 11. The arm link 13 and the second control shaft 11 do not move relative to each other. The second control shaft 11 is rotatably supported in a housing 20 described later.

  The second control link 12 has a lever shape, and one end portion 12a connected to the eccentric shaft portion 10c is formed substantially linearly. On the other hand, the other end portion 12b to which the arm link 13 is connected is curved. A communication hole 12c through which the eccentric shaft portion 10c is rotatably inserted is formed at the tip of the one end portion 12a (see FIG. 3). As shown in FIG. 5 (longitudinal sectional view of the actuator), the other end portion 12b has a tip portion 12d formed in a bifurcated shape. A connecting hole 12e is formed through the tip portion 12d. Further, a connecting hole 13c having a diameter substantially the same as that of the connecting hole 12e is formed through the protruding portion 13b of the arm link 13. The projecting portion 13b of the arm link 13 is inserted between the tip portions 12d formed in a bifurcated shape, and in this state, the connecting pin 14 passes through the connecting holes 12e and 13c and is press-fitted and fixed.

  As shown in FIG. 2 (exploded perspective view of the actuator), the arm link 13 is formed separately from the second control shaft 11. The arm link 13 is a thick member formed of an iron-based metal material, and has an annular portion in which a press-fitting hole 13a is formed through substantially the center, and a protruding portion 13b that protrudes toward the outer periphery. The fixing hole 23b of the second control shaft 11 is press-fitted into the press-fitting hole 13a, and the second control shaft 11 and the arm link 13 are fixed by this press-fitting. The projection 13b is formed with a connection hole 13c in which the connection pin 14 is rotatably supported. The shaft center of the connection hole 13c (the shaft center of the connection pin 14) is eccentric from the rotation axis O of the second control shaft 11 by a predetermined amount in the radial direction.

  The rotation angle of the second control shaft 11 is changed by the torque transmitted from the electric motor 22 via the wave gear type reduction device 21 which is a part of the actuator of the variable compression ratio mechanism of the internal combustion engine. The second control shaft 11 rotates within a predetermined angle range less than 360 [deg] (for example, about 150 [deg]). When the rotation angle of the second control shaft 11 is changed, the attitude of the second control link 12 is changed, the first control shaft 10 is rotated, and the position of the lower end portion of the first control link 7 is changed. As a result, the posture of the lower link 5 changes, the stroke position and stroke amount of the piston 1 in the cylinder are changed, and the compression ratio of the internal combustion engine is changed accordingly.

Next, the configuration of the actuator of the first embodiment will be described.
2 is an exploded perspective view of the actuator according to the first embodiment, FIG. 3 is a perspective view of the actuator, FIG. 4 is a plan view of the actuator according to the first embodiment, and FIG. 5 is a cross-sectional view taken along line S1-S1 in FIG. As shown in FIGS. 2 to 5, the actuator of the variable compression ratio mechanism of the internal combustion engine includes an electric motor 22, a wave gear type reduction gear 21, a housing 20, and a second control shaft 11. The wave gear speed reducer 21 is attached to the distal end side of the output shaft 48 of the electric motor 22. The housing 20 accommodates the wave gear reducer 21 therein. The second control shaft 11 is rotatably supported by the housing 20.

  The electric motor 22 is a brushless motor, and includes a motor casing 45, a coil 46, a rotor 47, an output shaft 48, and a resolver (rotation angle sensor) 55. The motor casing 45 is formed in a bottomed cylindrical shape. The motor casing 45 has four bosses 45a on the outer periphery of the front end. A screw insertion hole 45b through which the screw 49 is inserted passes through the boss portion 45a. The coil 46 is formed in a cylindrical shape and is fixed to the inner peripheral surface of the motor casing 45. The rotor 47 is rotatably provided inside the coil 46. One end 48 a of the output shaft 48 is fixed to the center of the rotor 47. The output shaft 48 is rotatably supported by a ball bearing 52 provided at the bottom of the motor casing 45.

  The resolver 55 detects the rotation angle of the output shaft 48. The resolver 55 is provided at a position protruding from the opening of the motor casing 45. The resolver 55 includes a resolver rotor 55a and a sensor unit 55b. The resolver rotor 55a is press-fitted and fixed to the outer periphery of the output shaft 48. The sensor unit 55b detects a double-tooth target (not shown) formed on the outer peripheral surface of the resolver rotor 55a. The sensor unit 55b outputs a detection signal to a control unit (not shown) housed in the motor casing 45. The sensor unit 55b is fixed inside the cover 28 with two screws. When attaching the motor casing 45 to the cover 28, the screw 49 is inserted into the boss portion 45a while the O-ring 51 is interposed between the end face of the resolver 55 and the cover 28. Subsequently, the screw 49 is fastened to the male thread portion formed on the electric motor 22 side of the cover 28. The motor housing chamber that houses the electric motor 22 by the motor casing 45 and the cover 28 is a drying chamber that does not supply lubricating oil or the like.

  The second control shaft 11 has a shaft body 23 and a fixing flange 24. The fixing flange 24 is formed in a substantially disc shape having a larger diameter than the shaft body 23. In the second control shaft 11, a shaft body 23 and a fixing flange 24 are integrally formed of a ferrous metal material. The shaft portion main body 23 has a sensor shaft portion 231 and a retainer shaft portion 232. The sensor shaft portion 231 is located on the inner periphery of the angle sensor (rotation angle sensor) 32. A retainer 350 is press-fitted and fixed to the retainer shaft portion 232. The retainer 350 has a larger diameter than the sensor shaft portion 231 and restricts the movement of the second control shaft 11 toward the wave gear reducer in the direction of the rotation axis O (axial direction) (see FIG. 5).

  The second control shaft 11 includes a first journal portion 23a, a fixed portion 23b, and a second journal portion 23c on the wave gear type speed reducer side of the retainer shaft portion 232. The first journal portion 23 a is located on the tip end side of the second control shaft 11. In the fixing portion 23b, the press-fitting hole 13a of the arm link 13 is press-fitted from the first journal portion 23a side. The second journal portion 23 c is located on the fixing flange 24 side of the second control shaft 11. The first journal portion 23a has a smaller diameter than the fixed portion 23b, and the second journal portion 23c has a larger diameter than the fixed portion 23b. A first step portion 23d is formed between the fixed portion 23b and the second journal portion 23c. A second step portion 23e is formed between the first journal portion 23a and the fixed portion 23b. A third step portion 23f is formed between the first journal portion 23a and the retainer shaft portion 232. The third step portion 23f serves as a stopper when the retainer 350 is press-fitted into the retainer shaft portion 232, and the press-fitting operation is facilitated.

  In the first step portion 23d, when the press-fitting hole 13a of the arm link 13 is press-fitted into the fixed portion 23b from the first journal portion 23a side, the end of the press-fitting hole 13a abuts from the axial direction. Thereby, the movement of the arm link 13 toward the second journal portion 23c is restricted. On the other hand, the second step portion 23e comes into contact with the step hole edge 30c of the support hole 30 and the metal bush 301 when the shaft portion main body 23 is inserted into the support hole 30 formed in the housing 20. 2 Restricts movement of the control shaft 11 in the axial direction to the side opposite to the wave gear type reduction gear 21 side. The shaft body 23 can be rotated in the first bearing hole 301a of the metal bush 301 and in the second bearing hole 304a of the metal bush 304, and supported so as to allow a slight axial movement. ing. In other words, there is a slight radial clearance between the inner periphery of the first bearing hole 301a and the outer periphery of the first journal portion 23a, and between the inner periphery of the second bearing hole 304a and the second journal portion 23c. Between the first bearing hole 301a and the first journal portion 23a, and between the second bearing hole 304a and the second journal portion 23c, there are a lubricating oil supply oil passage (housing oil passage) 202 and a lubricating oil supply oil passage (housing oil passage). ) The lubricating oil pumped from the oil pump is introduced through 203. The fixing flange 24 is fastened by a screw 25 to a wave gear output shaft member 27 that is an internal tooth of the wave gear speed reducer 21 via a thrust plate 26.

  The second control shaft 11 has an introduction portion for introducing lubricating oil pumped from an oil pump (not shown). The introduction part has an axial oil passage 64a and an oil chamber 64b. The axial oil passage 64a penetrates the center of the second control shaft 11 in the axial direction. Lubricating oil is supplied to the axial oil passage 64a via an oil passage (not shown) formed in the housing 20. The oil chamber 64b is formed at the center of the fixing flange 24, and is supplied with lubricating oil from the axial oil passage 64a. The oil chamber 64b side of the axial oil passage 64a and the oil chamber 64b are connected by a pore 400. The cross-sectional area perpendicular to the axis of the pore 400 is smaller than the cross-sectional area perpendicular to the axis of the axial oil passage 64a. For this reason, the pore 400 functions as a diaphragm. As a result, even when a large-diameter axial oil passage 64a is formed from the oil chamber 64b side, a throttling effect can be exerted by the pore 400 provided in the vicinity of the lubricating oil discharge port on the oil chamber 64b side. Oil can be diffused into the oil chamber 64b. The lubricating oil supplied to the oil chamber 64b is supplied to the wave gear type speed reducer 21.

  The housing 20 is made of an aluminum alloy material and is formed into a substantially cubic shape by die casting (aluminum die casting). A large-diameter annular opening groove 20a is formed on the rear end side of the housing 20. The opening groove 20a is closed by the cover 28 via the O-ring 51. The cover 28 has a motor shaft through hole 28a and four boss portions 28b. The motor shaft through hole 28a has the output shaft 48 passing through the center. The boss portion 28b is expanded in diameter toward the radially outer peripheral side. The cover 28 and the housing 20 are fastened by inserting the screw 43 through a screw insertion hole formed through the boss portion 28b.

  An opening for the second control link 12 connected to the arm link 13 is formed on a side surface orthogonal to the opening direction of the opening groove 20a. In the housing 20 in which the opening is formed, a storage chamber 29 serving as an operation region of the arm link 13 and the second control link 12 is formed. A support hole 30b through which the second journal portion 23c of the second control shaft 11 passes is formed between the opening groove portion 20a and the storage chamber 29. A support hole 30 through which the first journal portion 23 a of the second control shaft 11 passes is formed on the side surface in the axial direction of the storage chamber 29. A metal bush 301 is disposed between the support hole 30 and the first journal portion 23a, and a metal bush 304 is disposed between the support hole 30b and the second journal portion 23c.

  A retainer receiving hole 31 is formed at the end of the support hole 30 on the angle sensor 32 side. The retainer accommodation hole 31 is formed to have a larger diameter than the opening of the support hole 30. A step surface 31a is formed between the opening on the angle sensor 32 side of the support hole 30 and the retainer accommodation hole 31. The step surface 31 a extends in a direction orthogonal to the axial direction of the second control shaft 11. The retainer 350 restricts the movement of the second control shaft 11 toward the axial wave gear type reduction device by contacting the step surface 31a. Below the retainer accommodating hole 31, there is provided a lubricating oil recirculating oil path 201 that communicates with the retainer accommodating hole 31 and returns the lubricating oil to the accommodating chamber 29 side.

  The angle sensor 32 has a sensor holder 32a. The sensor holder 32a is attached so as to close the retainer receiving hole 31 from the outside of the housing 20. The sensor holder 32a has a through hole 32a1 and a flange portion 32a2. In the through hole 32a1, a detection coil is disposed on the inner periphery. The flange portion 32a2 is fastened to the housing 20 by a screw 321. A seal ring 33 is installed between the sensor holder 32a and the housing 20. The seal ring 33 ensures liquid tightness between the retainer receiving hole 31 and the outside. The sensor holder 32a has a sensor cover 32c that closes the through hole 32a1 on the outer peripheral side. The sensor cover 32c is fastened to the sensor holder 32a by a screw 324.

  A seal ring 323 is installed between the sensor cover 32c and the sensor holder 32a. The seal ring 323 ensures liquid tightness between the retainer receiving hole 31 and the through hole 32a1 and the outside. A sensor shaft portion 231 having a rotor 32b attached to the outer periphery is inserted into the through hole 32a1. The rotor 32b is a substantially elliptical part. The angle sensor 32 detects that the distance set between the inner periphery of the through-hole 32a1 and the rotor 32b has changed due to the rotation of the rotor 32b, based on a change in inductance of the detection coil. Thereby, the rotation angle of the rotor 32b, that is, the rotation angle of the second control shaft 11 is detected. The angle sensor 32 outputs rotation angle information to the control unit.

  FIG. 6 is an exploded perspective view of the wave gear reducer according to the first embodiment. The wave gear type speed reducer 21 is a harmonic drive (registered trademark) type, and each component is accommodated in an opening groove 20 a of the housing 20 closed by a cover 28. The wave gear reducer 21 includes a first wave gear output shaft member 27, a flexible external gear 36, a wave generator 37, and a second wave gear fixed shaft member 38. The first wave gear output shaft member 27 is screwed to the fixing flange 24 of the second control shaft 11. The first wave gear output shaft member 27 is formed in an annular shape, and a plurality of internal teeth 27a are formed on the inner periphery. The flexible external gear 36 is disposed on the inner diameter side of the first wave gear output shaft member 27. The flexible external gear 36 has external teeth 36a that can be bent and deformed and mesh with the internal teeth 27a on the outer peripheral surface. The wave generator 37 is formed in an elliptical shape, and its outer peripheral surface slides along the inner peripheral surface of the flexible external gear 36. The second wave gear fixed shaft member 38 is disposed on the outer peripheral side of the flexible external gear 36, and an inner tooth 38a that meshes with the outer tooth 36a is formed on the inner peripheral surface.

On the outer peripheral side of the first wave gear output shaft member 27, a female screw portion 27b is formed in which the screws 25 are screwed at equal circumferential positions. The flexible external gear 36 is formed of a metal material into a thin cylindrical shape that can be bent and deformed. The number of teeth of the external teeth 36a of the flexible external gear 36 is the same as the number of teeth of the internal teeth 27a of the first wave gear output shaft member 27.
The wave generator 37 has a main body 371 and a ball bearing 372. The main body 371 has an elliptical shape. The ball bearing 372 allows relative rotation between the outer periphery of the main body 371 and the inner periphery of the flexible external gear 36. A through hole 37a is formed in the center of the main body 371. Serrations are formed on the inner periphery of the through-hole 37a, and serrated with the outer periphery of the other end 48b of the output shaft 48. Instead of serration coupling, key groove coupling or spline coupling may be used. A cylindrical portion 371b is formed on the electric motor side surface 371a of the main body 371. The cylindrical portion 371b protrudes toward the electric motor so as to surround the outer periphery of the through hole 37a. The cross-sectional shape of the cylindrical portion 371b is a perfect circle, and the diameter of the outer periphery of the cylindrical portion 371b is smaller than the short diameter of the main body portion 371.

  A flange portion 38 b is formed on the outer periphery of the second wave gear fixed shaft member 38. A second thrust plate 42 is disposed between the flange portion 38b and the cover 28. The second wave gear fixed shaft member 38 and the second thrust plate 42 are fastened to the cover 28 by screws 41. The second thrust plate 42 is made of a ferrous metal material having wear resistance equal to or higher than that of the flexible external gear 36. Thus, the wear of the cover 28 is prevented from the thrust force generated in the flexible external gear 36, and the axial position of the ball bearing 700 is restricted. The ball bearing 700 is an open type and is a four-point contact type rolling bearing capable of receiving a load in the thrust direction. The ball bearing 700 allows the main body 371 to rotate relative to the cover 28.

  The second thrust plate 42 is an annular disk member, and the inner peripheral edge 42 a is formed so as to be closer to the rotation axis O than the inner periphery of the outer ring of the ball bearing 700. The number of teeth of the internal teeth 38a of the second wave gear fixed shaft member 38 is two more than the number of teeth of the external teeth 36a of the flexible external gear 36. Therefore, the number of teeth of the internal teeth 38a of the second wave gear fixed shaft member 38 is two more than the number of teeth of the internal teeth 27a of the first wave gear output shaft member 27. In the wave gear type reduction mechanism, since the reduction ratio is determined by the difference in the number of teeth, an extremely large reduction ratio can be obtained.

  The cover 28 has a plate housing portion 281a, a bearing housing portion 281b, and a seal housing portion 281c on the end surface 281 on the wave gear speed reducer 21 side. The plate accommodating portion 281a has substantially the same depth as the thickness of the second thrust plate 42 and houses the second thrust plate 42. The bearing housing portion 281b is a bottomed cylindrical step portion that is bent from the plate housing portion 281a toward the electric motor 22 side. The seal housing portion 281c is formed in a cylindrical shape protruding toward the wave generator 37 on the inner diameter side of the bottom surface of the bearing housing portion 281b. A seal member 310 is disposed between the inner periphery of the seal housing portion 281c and the outer periphery of the output shaft 48. The seal member 310 provides a liquid-tight seal between the opening groove 20a that houses the wave gear type reduction gear 21 and the electric motor 22.

  As shown in FIG. 7, the angle sensor 32 and the resolver 55 are electrically connected to the control unit of the electric motor 22 by a harness 204 and a harness 205 arranged outside the housing 20. The angle sensor 32 and the resolver 55 are supplied with a current from the control unit via the harness 204 and the harness 205 and transmit a detection signal to the control unit. A connector 206 is attached to one end of the harness 204 and the harness 205. The connector 206 is connected to a connector 45c disposed outside the motor casing 45. The connector 45c is connected to the control unit. The harness 204 and the harness 205 are held on the left side surface of the housing 20 by the harness bracket 20b. The harness bracket 20b is formed in a substantially L shape by bending a metal plate, and includes a fixing portion 20b1 and a holding portion 20b2. The fixed portion 20b1 is fastened to the housing 20 by a screw 325. The holding part 20b2 has the harness 204 and the harness 205 inserted therein. A predetermined air gap is formed between the holding portion 20b2 and the outer surface of the housing 20.

FIG. 8 is an enlarged front view of the main part of the actuator according to the first embodiment.
The other end side of the harness 204 is connected to the terminal 32a3 of the sensor holder 32a. The harness 204 is held in front of the housing 20 by a harness clip (fixing member) 7.
The harness clip 7 is formed by bending a metal plate and has a fixing portion 7a and a holding portion 7b. The fixing portion 7a is disposed on a clip seat surface 70 (see FIG. 10) formed in the housing 20. The fixing portion 7a is formed in a substantially rectangular shape when viewed from the front side of the housing 20. The fixing portion 7a is fastened to the clip seat surface 70 by a screw 326. The upper part of the fixing portion 7a protrudes to the opposite side of the clip seat surface 70 and floats from the clip seat surface 70. The holding portion 7b is formed in an annular shape protruding from the upper end of the fixed portion 7a above the housing 20 and to the side opposite to the clip seat surface 70. A harness 204 is inserted inside the holding portion 7b. As shown in FIG. 9, an air gap is set between the holding portion 7b and the outer surface of the housing 20 by a gap Δd.

FIG. 10 is a front view of the housing of the first embodiment.
On the outer surface of the housing 20, a guide wall 71 and a wall portion 72 are formed around the clip seat surface 70. When viewed from the front side of the housing 20, the guide wall 71 is located on the right side and the lower side of the clip seat surface 70, and the wall portion 72 is located on the left side of the clip seat surface 70.
When the harness clip 7 is fastened to the clip seating surface 70, the guide wall 71 abuts with the fixing portion 7a of the harness clip 7 to regulate the fixing angle of the harness clip 7 and prevent the rotation with the screw 326. . The guide wall 71 is formed in an L shape when viewed from the front side of the housing 20, and has a vertical portion 71a and a horizontal portion 71b. The vertical portion 71a extends in the up-down direction on the right side of the clip seat surface 70, and the horizontal portion 71b extends in the left-right direction below the clip seat surface 70. The vertical portion 71a contacts the side edge of the fixed portion 7a, and the horizontal portion 71b contacts the lower edge of the fixed portion 7a.

  On the front side of the housing 20, the guide wall 71 is formed integrally with the gate seat 15 formed on the outer surface of the housing 20. The gate seat 15 is used to prevent a product portion from being broken, that is, a so-called “break-in” when the gate (pouring gate) 16 that press-fits molten metal into the product cavity is cut off when the housing 20 is cast. is there. The gate seat 15 is formed on a parting line 17 of the mold. That is, the guide wall 71 is formed integrally with the parting line 17. The holding part 20 of the harness clip 7 is located on the uppermost part of the parting line 17, and is disposed so as to straddle the horizontal part 17a extending in the horizontal direction. When the harness clip 7 is attached to the clip seat surface 70, the fixing portion 7a and the holding portion 7b do not interfere with the horizontal portion 17a of the parting line 17.

Next, the effect of Embodiment 1 is demonstrated.
At the time of assembling the actuator, the operator inserts the harness 204 inside the holding portion 7b, and then fixes the harness clip 7 to the clip seating surface 70 of the housing 20 with the screw 326. At this time, the harness clip 7 receives a force from the screw head of the screw 326 in the rotational direction of the screw 326, but the harness clip 7 rotates with the screw 326 when the guide wall 71 comes into contact with the fixing portion 7a of the harness clip 7. Can be prevented.
Here, the guide wall 71 of the first embodiment is formed integrally with the gate seat 15 of the housing 20. In other words, in the first embodiment, a part of the gate seat 15 is used as the guide wall 71 to regulate the fixing angle of the harness clip 7. The gate seat 15 is necessarily formed on the outer surface of the housing 20 in order to prevent the housing 20 from being chipped during casting. Therefore, by causing a part of the gate seat 15 to function as the guide wall 71, the guide wall 71 can be easily formed and no additional parts are required. As a result, an increase in weight and an increase in casting cost due to the addition of the guide wall 71 can be suppressed.

The guide wall 71 is formed integrally with the parting line 17. Generally, in aluminum die casting, the gate and overflow are designed on the parting line. Therefore, the guide wall 71 can be formed integrally with the gate seat 15 by arranging the guide wall 71 on the parting line 17.
The guide wall 71 has bent portions (vertical portion 71a and horizontal portion 71b) along the shape of the harness clip 7. Even when the guide wall 71 has a bent shape, the guide wall 71 can be easily formed by forming it integrally with the gate seat 15.
The housing 20 includes a lubricating oil supply oil path 202 and a lubricating oil supply oil path 203 to which engine oil is supplied, and the harness clip 7 includes a fixing portion 7a that is fixed to the housing 20 and a holding portion that holds the harness 204. The holding portion 7b has a portion facing the outer surface of the housing 20 that is not in contact with the outer surface of the housing 20. In other words, the air gap is set between the harness clip 7 and the housing 20 that receives heat from the engine oil and becomes high temperature. Thereby, since heat input to the harness 204 due to engine oil is suppressed, deterioration of the harness 204 can be suppressed.

The fixing portion 7a protrudes from the outer surface of the housing 20, and the holding portion 7b is disposed so as to straddle the horizontal portion 17a of the parting line 17 formed when the housing 20 is cast. Thereby, the harness clip 7 can be attached to the clip seat surface 70 without cutting the parting line 17 by machining. In addition, since the space above the horizontal portion 17a can also be used to fix the harness 204, the layout of the harness 204 can be improved.
The guide wall 71 is bent in an L shape by the vertical portion 71a and the horizontal portion 71b. Thereby, since the rotation of the harness clip 7 can be regulated by the two surfaces of the vertical portion 71a and the horizontal portion 71b, the rotation regulating performance can be improved as compared with the case of regulating by one surface.

[Other Embodiments]
Although the embodiment for carrying out the present invention has been described above, the specific configuration of the present invention is not limited to the configuration of the embodiment, and there are design changes and the like within the scope not departing from the gist of the invention. Are also included in the present invention.
For example, the gate seat may be at a position different from the parting line. In this case, the guide wall may be integral with either the gate seat or the parting line.
Instead of the gate seat, a guide wall may be formed integrally with the overflow.

7 Harness clip (fixing member)
7a Fixed part
7b Holding part
11 Second control axis (control axis)
15 Gate seat
17 Parting line
20 Housing
22 Electric motor
32 Angle sensor (rotation angle sensor)
55 Resolver (rotation angle sensor)
71 guide wall
202 Lubricating oil supply passage (housing oil passage)
203 Lubricating oil supply passage (housing oil passage)

Claims (6)

A control shaft linked to the variable compression ratio mechanism of the internal combustion engine and rotating to change the attitude of the variable compression ratio mechanism of the internal combustion engine;
An electric motor having an output shaft for rotating the control shaft;
A rotation angle sensor for detecting a rotation angle of the control shaft or the output shaft;
A harness extending from the rotation angle sensor;
A housing having a bearing portion for bearing the control shaft and molded by casting to which the electric motor is fixed;
A fixed part fixed to the outer surface of the housing and holding the harness;
A guide wall that is integral with a gate seat formed at the time of molding of the housing, is formed in a convex shape on the outer surface of the housing, and regulates a fixing angle of the fixing part;
An actuator for a variable compression ratio mechanism of an internal combustion engine having A control shaft linked to the variable compression ratio mechanism of the internal combustion engine and rotating to change the attitude of the variable compression ratio mechanism of the internal combustion engine;
An electric motor having an output shaft for rotating the control shaft;
A rotation angle sensor for detecting a rotation angle of the control shaft or the output shaft;
A harness extending from the rotation angle sensor;
A housing having a bearing portion for bearing the control shaft and molded by casting to which the electric motor is fixed;
A fixed part fixed to the outer surface of the housing and holding the harness;
A guide wall that is integral with a parting line formed at the time of molding of the housing, is formed in a convex shape on the outer surface of the housing, and regulates a fixing angle of the fixing part;
An actuator for a variable compression ratio mechanism of an internal combustion engine having An actuator for a variable compression ratio mechanism of an internal combustion engine according to claim 1 or 2,
The guide wall is an actuator of a variable compression ratio mechanism of an internal combustion engine having a bent portion along the shape of the fixed part. An actuator for a variable compression ratio mechanism of an internal combustion engine according to claim 1 or 2,
The housing has a housing oil passage communicating with the oil passage of the internal combustion engine,
The fixed component has a fixed portion fixed to the housing and a holding portion that holds the harness,
The holding portion is an actuator of a variable compression ratio mechanism of an internal combustion engine in which a portion facing the outer surface of the housing is at least partially not in contact with the outer surface of the housing. An actuator for a variable compression ratio mechanism of an internal combustion engine according to claim 4,
The fixing portion protrudes from an outer surface of the housing;
The holding portion is an actuator of a variable compression ratio mechanism of an internal combustion engine arranged so as to straddle a parting line formed at the time of molding the housing. An actuator for a variable compression ratio mechanism for an internal combustion engine according to claim 3,
The guide wall is an actuator of a variable compression ratio mechanism of an internal combustion engine that is bent in an L shape.

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