JP4253630B2 - Variable valve mechanism for engine - Google Patents

Description

  The present invention relates to an engine variable valve mechanism that changes a maximum valve lift amount of an engine valve (at least one of an intake valve and an exhaust valve).

  The variable valve mechanism is configured to include a control shaft disposed on the cylinder head so as to be movable in the axial direction, and a plurality of valve lift mechanisms provided on the control shaft for lifting the engine valve. (See Patent Document 1).

  The valve lift mechanism is a slider gear movable in conjunction with the control shaft, an input gear provided on the slider gear and driven by the camshaft of the engine valve, and provided on the slider gear to lift the engine valve. And an output gear.

The input gear is provided with an input arm that comes into contact with the cam of the camshaft.
The output gear is provided with an output arm that comes into contact with a valve driving device (such as a rocker arm or a valve lifter).

  The slider gear is formed with a helical spline that meshes with a helical spline formed on the input gear, and a helical spline that meshes with a helical spline formed on the output gear. That is, the slider gear, the input gear, and the output gear are meshed through the helical spline.

In such a variable valve mechanism, the maximum valve lift of the engine valve is changed by changing the relative phase difference between the input arm of the input gear and the output arm of the output gear by displacing the slider gear together with the control shaft in the axial direction. can do.
JP 2001-263015 A

  By the way, in the conventional variable valve mechanism, the teeth of each helical spline formed on the slider gear are all set to the same shape. That is, the arm gear (input gear and output gear) can be attached to the slider gear from any position in the circumferential direction.

  For this reason, when the arm gear is assembled to the slider gear, the circumferential position of the arm (input arm or output arm) may deviate from the correct position. In this case, the maximum valve lift amount of the engine valve cannot be controlled as required.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide an engine that can prevent the circumferential position of the arm from deviating from the correct position when the slider gear and the arm gear are assembled. The object is to provide a variable valve mechanism.

In the following, means for achieving the above object and its effects are described.
(1) The invention according to claim 1 is a slider gear arranged in the cylinder head so as to be movable in the axial direction, and a plurality of arm gears meshed with a helical spline of the slider gear and assembled on the slider gear. An engine variable valve mechanism that changes a maximum valve lift amount of an engine valve by changing a relative phase of an arm provided in each of the plurality of arm gears through movement of the slider gear in an axial direction. The slider gear helical spline and a part of the helical spline of the arm gear meshing with the helical spline are formed with a plurality of deformed tooth portions different in shape from other portions, and the formation positions of the plurality of deformed tooth portions are in the radial direction. The point is that the position is set to be asymmetric.

  According to the above configuration, when assembling the slider gear and the arm gear, the arm gear can be assembled to the slider gear only at a phase where the deformed tooth portion of the slider gear and the deformed tooth portion of the arm gear coincide with each other. Accordingly, it is possible to prevent the arm gear from being assembled to the slider gear in a state where the circumferential position of the arm is deviated from the correct position.

Here, when the slider gear and the arm gear are assembled, the posture of the arm gear in which the circumferential position of the arm coincides with the correct position is set as a reference posture. A posture rotated 180 ° from the reference posture around an axis orthogonal to the central axis of the arm gear is defined as a reverse posture.
  Depending on the configuration of the deformed tooth portion formed, it may be permitted to assemble the arm gear in the inverted posture to the slider gear. In this case, the circumferential position of the arm deviates from the correct position.
  In this regard, according to the first aspect of the present invention, since the arm gear cannot be assembled to the slider gear when the arm gear is in the reverse posture, the arm gear is moved in the state where the circumferential position of the arm is shifted from the correct position. It becomes possible to suppress that it is assembled.

(2) The invention according to claim 2 is the variable valve mechanism for the engine according to claim 1,
  The variable valve mechanism includes a first arm gear and a second arm gear corresponding to a pair of engine valves as the plurality of arm gears, and the helical spline of the first arm gear and the helical of the slider gear that meshes with the helical spline. The spuriously deformed tooth portion of the spline, the helical spline of the second arm gear, and the spuriously deformed tooth portion of the helical spline of the slider gear meshing with the helical spline, the shapes of the deformed tooth portions are set to be different from each other. It is said.

(3) The invention according to claim 3 is the variable valve mechanism of the engine according to claim 1,
  The variable valve mechanism includes a first arm gear and a second arm gear corresponding to a pair of engine valves as the plurality of arm gears, and the helical spline of the first arm gear and the helical of the slider gear that meshes with the helical spline. The spline deformed tooth portion, the helical spline of the second arm gear, and the deformed tooth portion of the helical spline of the slider gear meshing with the helical spline, the number of the deformed tooth portions are set to be different from each other. It is said.

Depending on the configuration of the first aspect of the invention, it may be permitted to assemble the first arm gear to the helical spline corresponding to the second arm gear in the slider gear. In some slider gears, it is permitted to assemble the second arm gear to a helical spline corresponding to the first arm gear. In such a case, the circumferential position of the arm is shifted from the correct position.
  In this respect, according to the invention described in claim 2 or 3, the first arm gear cannot be assembled to the helical spline corresponding to the second arm gear, and the second arm gear cannot be assembled to the helical spline corresponding to the first arm gear. For this reason, it is possible to prevent the arm gears from being assembled to the slider gear in a state where the circumferential position of the arm is deviated from the correct position.

(4) The invention according to claim 4 is provided with a valve lift mechanism which is disposed on the cylinder head and lifts the engine valve, and the valve lift mechanism includes a slider gear which is movable in the axial direction, and a cam of the engine valve. An input gear provided with an input arm that is pushed through a shaft, and an output gear provided with an output arm that pushes the valve drive device of the engine valve are configured, and the input gear includes the slider gear Meshed with the input side helical spline formed on the slider gear and provided on the slider gear, and the output gear meshed with the output side helical spline formed on the slider gear and provided on the slider gear. And the input arm and the output through the movement of the slider gear in the axial direction. In the variable valve mechanism of the engine that changes the maximum valve lift amount of the engine valve by changing the relative phase with the engine, the input side helical spline and a part of the helical spline of the input gear meshing with the helical spline The output side helical spline and a part of the helical spline of the output gear that meshes with the helical spline are formed on the output side different in shape from the other parts. The gist is that a deformed tooth portion is formed, and the formation positions of the plurality of input side deformed tooth portions are set to asymmetric positions in the radial direction.

According to the above configuration, when assembling the slider gear and the input gear, it is possible to assemble the input gear to the slider gear only at the phase where the input side irregular tooth portion of the slider gear and the input side irregular tooth portion of the input gear coincide. It becomes. Therefore, the input gear can be prevented from being assembled to the slider gear in a state where the circumferential position of the input arm is deviated from the correct position.
  Further, when the slider gear and the output gear are assembled, the output gear can be assembled to the slider gear only in a phase where the output-side deformed tooth portion of the slider gear and the output-side deformed tooth portion of the output gear coincide. Accordingly, it is possible to suppress the output gear from being assembled to the slider gear in a state where the circumferential position of the output arm is deviated from the correct position.
  Depending on the configuration of the deformed tooth portion, an input gear in a reversed posture can be assembled to the slider gear. In this case, the circumferential position of the input arm is shifted from the correct position.
  In this regard, according to the fourth aspect of the present invention, when the input gear is in the reverse posture, the input gear cannot be assembled to the slider gear, so that the input arm is shifted in the circumferential position from the correct position. It becomes possible to prevent the gear from being assembled to the slider gear.

(5) The invention according to claim 5 is the variable valve mechanism of the engine according to claim 4, wherein a plurality of the output-side deformed teeth are formed, and the formation positions of the plurality of output-side deformed teeth are the diameters. The gist is that the position is asymmetrical in the direction.

Depending on the configuration of the invention described in claim 4, there is a case where it is permitted to assemble the output gear in the reverse posture to the slider gear. In this case, the circumferential position of the output arm is shifted from the correct position.
  In this regard, according to the fifth aspect of the invention, since the output gear cannot be assembled to the slider gear when the output gear is in the reverse posture, the output arm is output with the circumferential position shifted from the correct position. It becomes possible to prevent the gear from being assembled to the slider gear.

(6) The invention according to claim 6 is the variable valve mechanism of the engine according to claim 4 or 5, wherein the variable valve mechanism is a first output gear corresponding to a pair of engine valves as the output gear. And the second output gear, the helical spline of the first output gear and the output-side deformed tooth portion of the output-side helical spline meshing with the helical spline, the helical spline of the second output gear, and the helical spline The output-side helical spline meshing with the output-side deformed tooth portion of the output-side helical spline is set to have different shapes.

(7) The invention according to claim 7 is the variable valve mechanism of the engine according to claim 4 or 5, wherein the variable valve mechanism is a first output gear corresponding to a pair of engine valves as the output gear. And the second output gear, the helical spline of the first output gear and the output-side deformed tooth portion of the output-side helical spline that meshes with the helical spline, the helical spline of the second output gear, and the helical spline The output side helical spline that meshes with the output side deformed tooth portion is set to have a different number of deformed tooth portions.

Depending on the configuration of the invention described in claim 4 or 5, it may be permitted to assemble the first output gear to the helical spline corresponding to the second output gear in the slider gear. In some slider gears, it is permitted to assemble the second output gear to the helical spline corresponding to the first output gear. In such a case, the circumferential position of the output arm is shifted from the correct position.
  In this regard, according to the invention described in claim 6 or 7, the first output gear is assembled to the helical spline corresponding to the second output gear, and the second output gear is attached to the helical spline corresponding to the first output gear. Since it cannot be assembled, it is possible to prevent each output gear from being assembled to the slider gear in a state where the circumferential position of the output arm is deviated from the correct position.

(8) The invention according to claim 8 is the variable valve mechanism for an engine according to any one of claims 4 to 7, wherein the input side helical splines are set to have the same circumferential width. And a plurality of grooves, and the plurality of grooves are formed including a slider gear input side tooth-less portion as a groove whose circumferential width is set to a different size. The helical spline is formed including an input gear buried tooth portion as a tooth meshing with the slider gear input side toothless portion, and the input side deformed tooth portion includes the slider gear input side toothless portion and the slider gear input side toothless portion. The gist of the invention is that it is constituted by an input gear toothed portion.

(9) The invention according to claim 9 is the variable valve mechanism for the engine according to any one of claims 4 to 7, wherein the input-side helical splines are set to have the same circumferential width. A plurality of teeth, and the plurality of teeth are formed including a slider gear input side embedded portion as a tooth having a circumferential width set to a different size. The helical spline is formed including a force gear missing tooth portion as a groove that meshes with the slider gear input side tooth portion, and the input side deformed tooth portion includes the slider gear input side tooth portion and the slider gear input side tooth portion. The gist of the invention is that it is constituted by an input gear missing tooth portion.

(10) The invention according to claim 10 is the variable valve mechanism for an engine according to any one of claims 4 to 9, wherein the output-side helical spline is set to have the same circumferential width. A plurality of grooves, and the plurality of grooves are formed including a slider gear output-side toothless portion as a groove whose width in the circumferential direction is set to be different. The helical spline is formed including an output gear buried tooth portion as a tooth meshing with the slider gear output side toothless portion, and the output side deformed tooth portion includes the slider gear output side toothless portion and the slider gear output side toothless portion. The gist of the invention is that it is constituted by an output gear toothed portion.

(11) The invention according to claim 11 is the variable valve mechanism for an engine according to any one of claims 4 to 9, wherein the output-side helical spline is set to have the same circumferential width. And a plurality of teeth, and a plurality of teeth, and a slider gear output side embedded tooth portion as a tooth whose width in the circumferential direction is set to be different from each other. The helical spline is formed including an output gear missing tooth portion as a groove meshing with the slider gear output side embedded tooth portion, and the output side deformed tooth portion includes the slider gear output side embedded tooth portion and the slider gear output side embedded tooth portion. The gist of the invention is that it is constituted by an output gear missing tooth portion.

(First embodiment)
A first embodiment of the present invention will be described with reference to FIGS.
In the present embodiment, the variable valve mechanism that changes the maximum valve lift amount of the intake valve of the engine is assumed to be applied to the variable valve mechanism.

<Engine structure>
FIG. 1 shows a planar structure of the engine.
The engine 1 includes a cylinder block 11 and a cylinder head 12.

A plurality of cylinders 13 are provided in the cylinder block 11.
The cylinder head 12 is provided with an intake valve 21 for opening and closing the intake port of the cylinder 13 for each cylinder 13. An exhaust valve 22 that opens and closes the exhaust port of the cylinder 13 is provided for each cylinder 13.

  In each cylinder 13, an intake camshaft 23 is provided in the vicinity of the intake valve 21. The intake cam shaft 23 is provided with intake cams 25 at positions corresponding to the cylinders 13.

  In each cylinder 13, an exhaust camshaft 24 is provided in the vicinity of the exhaust valve 22. The exhaust cam shaft 24 is provided with exhaust cams 26 at positions corresponding to the cylinders 13.

The intake camshaft 23 and the exhaust camshaft 24 are drivingly connected to the crankshaft 15 via the timing chain 14.
In the engine 1, in the vicinity of the intake camshaft 23, a variable valve mechanism 4 for continuously changing the maximum valve lift amount and the valve operating angle (valve opening period) of each intake valve 21 (a part surrounded by a broken line) ) Is provided.

  The variable valve mechanism 4 is provided with a plurality of valve lift mechanisms 4 </ b> A that lift the intake valve 21 through the torque of the intake camshaft 23. The valve lift mechanism 4A is disposed between a pair of adjacent partitions 16.

<Overall structure of variable valve mechanism>
FIG. 2 shows a perspective structure of the variable valve mechanism 4.
The variable valve mechanism 4 includes a valve mechanism main body 41 and an actuator 42. The valve mechanism main body 41 includes a rocker shaft 43, a control shaft 44, and a valve lift mechanism 4A.

  The rocker shaft 43 is arranged to extend in the cylinder arrangement direction (arrow FR direction) in the cylinder head 12. That is, it is arranged in parallel with the intake camshaft 23. Further, the cylinder head 12 is fixed through a partition wall 16 so that it cannot be rotated and moved in the axial direction. An arrow F indicates a direction away from the actuator 42, and an arrow R indicates a direction approaching the actuator 42.

  A control shaft 44 is disposed in the rocker shaft 43 so as to be movable in the axial direction. On the rocker shaft 43, a valve lift mechanism 4A is provided at a position corresponding to each cylinder 13. That is, all the valve lift mechanisms 4A are supported by one common rocker shaft 43.

The control shaft 44 is drivingly connected to the actuator 42.
The actuator 42 is driven through the electronic control unit 9 that controls the engine 1 in an integrated manner.

  The electronic control unit 9 changes the maximum valve lift amount and the operating angle of the intake valve 21 by displacing the control shaft 44 in the axial direction through the control of the actuator 42. When the control shaft 44 is displaced in the direction of the arrow F, the maximum valve lift amount of the intake valve 21 is changed to a direction in which it increases. On the contrary, when the control shaft 44 is displaced in the direction of the arrow R of the engine 1, the maximum valve lift amount of the intake valve 21 is changed to be smaller. The relationship between the moving direction of the control shaft 44 and the changing direction of the maximum valve lift amount can be set opposite to the above relationship.

<Structure of valve mechanism body>
FIG. 3 shows an exploded perspective structure of the valve mechanism main body 41.
The valve lift mechanism 4A includes a slider gear 5, an input gear 6, a first output gear 7, and a second output gear 8. The input gear 6, the first output gear 7, and the second output gear 8 correspond to arm gears.

  The slider gear 5 is provided on the rocker shaft 43. Further, the rocker shaft 43 is provided so as to move in the axial direction in conjunction with the control shaft 44.

  The slider gear 5, the input gear 6, and the output gears 7 and 8 are meshed with each other through a helical spline. Further, the input gear 6 and the output gears 7 and 8 are respectively assembled to the slider gear 5 in a state where the side surfaces located between the gears 6, 7 and 8 are in contact with each other.

<Slider gear structure>
FIG. 4 shows a perspective structure of the slider gear 5.
FIG. 5 shows a side structure of the slider gear 5 as viewed from the direction V1 in FIG.

FIG. 6 shows a side structure of the slider gear 5 as viewed from the direction V2 in FIG.
The slider gear 5 is provided with a slider gear input spline 51, a slider gear first output spline 52, and a slider gear second output spline 53. The slider gear input spline 51 corresponds to an input side helical spline. The slider gear first output spline 52 and the slider gear second output spline 53 correspond to an output-side helical spline.

Hereinafter, the structure of each of these splines will be described.
[1] "Slider gear input spline"
The slider gear input spline 51 is provided at the center of the slider gear 5 in the axial direction. Further, it is formed so as to mesh with a helical spline (input gear spline 61) of the input gear 6.

  The slider gear input spline 51 is formed with a groove (slider gear input side reference toothless portion 51B) having a circumferential width larger than that of the other groove 51A. That is, the slider gear input spline 51 includes a plurality of grooves 51A whose circumferential widths are set to the same size, and one slider gear input side reference toothless portion 51B having a different circumferential width. It is formed including. The slider gear input side reference missing tooth portion 51B corresponds to the slider gear input side missing tooth portion (input side irregular tooth portion).

  The shape of the slider gear input side reference missing tooth portion 51B is a groove formed by removing one of the teeth of the slider gear input spline 51 in a slider gear in which the teeth of the slider gear input spline 51 are all set to the same shape. Corresponds to the shape.

[2] "Slider gear first output spline"
The slider gear first output spline 52 is provided at the end of the slider gear input spline 51 on the actuator 42 side. Further, the first output gear 7 is formed so as to mesh with the helical spline (first output gear spline 71). The slider gear input spline 51 and the slider gear first output spline 52 are formed so that the inclination directions of the tooth traces are opposite.

  The slider gear first output spline 52 is formed with a groove (slider gear first output side toothless portion 52B) having a larger circumferential width than the other grooves 52A. That is, the slider gear first output spline 52 includes a plurality of grooves 52A having the same width in the circumferential direction, and a slider gear first output side toothless portion 52B having a different width in the circumferential direction. It is formed including. The slider gear first output side toothless portion 52B corresponds to the slider gear output side toothless portion (output side irregular tooth portion).

  The shape of the slider gear first output side toothless portion 52B is a slider gear in which the teeth of the slider gear first output spline 52 are all set to the same shape, except for one of the teeth of the slider gear first output spline 52. This corresponds to the shape of the groove formed.

[3] "Slider gear second output spline"
The slider gear second output spline 53 is provided at the end of the slider gear input spline 51 opposite to the actuator 42. Further, the second output gear 8 is formed so as to mesh with a helical spline (second output gear spline 81). The slider gear input spline 51 and the slider gear second output spline 53 are formed so that the inclination directions of the tooth traces are opposite.

  The slider gear second output spline 53 is formed with a groove (slider gear second output-side toothless portion 53B) having a larger circumferential width than the other grooves 53A. That is, the slider gear second output spline 53 includes a plurality of grooves 53A having the same circumferential width and the slider gear second output side toothless portion 53B having a circumferential width different from that of the grooves 53A. It is formed including. The slider gear second output side toothless portion 53B corresponds to a slider gear output side toothless portion (output side irregular tooth portion).

  The shape of the slider gear second output side toothless portion 53B is a slider gear in which all teeth of the slider gear second output spline 53 are set to the same shape, except for one of the teeth of the slider gear second output spline 53. This corresponds to the shape of the groove formed.

<Structure of input gear>
FIG. 7 shows a perspective structure of the input gear 6.
FIG. 8 shows a side structure of the input gear 6 viewed from the direction V3 in FIG.

  In the input gear 6, a space extending in the axial direction of the rocker shaft 43 is formed inside the input gear housing 62. A helical spline (input gear spline 61) that meshes with the slider gear input spline 51 of the slider gear 5 is formed on the inner peripheral side of the input gear housing 62.

  The input gear spline 61 is formed with teeth (input gear reference embedded portion 61B) whose circumferential width is set larger than that of the other teeth 61A. That is, the input gear spline 61 is formed to include a plurality of teeth 61A having the same circumferential width and the input gear reference embedded portion 61B having a circumferential width different from that of the teeth 61A. Yes. The input gear reference tooth portion 61B corresponds to the input gear tooth portion (input-side irregular tooth portion).

  The shape of the input gear reference embedded portion 61B corresponds to the shape of a tooth formed by filling one of the grooves of the input gear spline 61 in the input gear in which the grooves of the input gear spline 61 are all set to the same shape. .

  The input gear reference embedded portion 61B is formed so as to correspond to the shape of the slider gear input side reference missing tooth portion 51B of the slider gear input spline 51. That is, the slider gear input spline 51 is formed so as to mesh with only the slider gear input side reference toothless portion 51B among the plurality of grooves formed in the spline 51.

  An input arm 63 that contacts the intake camshaft 23 is provided on the outer peripheral side of the input gear housing 62. The input arm 63 includes a pair of support arms 63L and 63R, a shaft 63A, and a roller 63B.

Each of the above elements constituting the input arm 63 is configured as follows.
The support arms 63L and 63R are formed to protrude in the radial direction from the outer peripheral side of the input gear housing 62. Moreover, it forms so that it may mutually become parallel.
The shaft 63A is provided between the support arm 63L and the support arm 63R so as to be parallel to the axial direction of the rocker shaft 43.
The roller 63B is attached to the shaft 63A in a rotatable state.

<Structure of the first output gear>
FIG. 9 shows a perspective structure of the first output gear 7 (first arm gear).
FIG. 10 shows a side structure of the first output gear 7 viewed from the direction V4 in FIG.

  In the first output gear 7, a space extending in the axial direction of the rocker shaft 43 is formed inside the first output gear housing 72. A helical spline (first output gear spline 71) that meshes with the slider gear first output spline 52 of the slider gear 5 is formed on the inner peripheral side of the first output gear housing 72. Note that the inclination direction of the tooth trace of the first output gear spline 71 is formed opposite to the inclination direction of the tooth trace of the input gear spline 61.

  The first output gear spline 71 is formed with teeth (first output gear embedded portion 71B) whose circumferential width is set larger than that of the other teeth 71A. That is, the first output gear spline 71 includes a plurality of teeth 71A having the same circumferential width and the first output gear embedded portion 71B having a circumferential width different from that of the teeth 71A. Is formed. The first output gear toothed portion 71B corresponds to an output gear toothed portion (output-side deformed tooth portion).

  The shape of the first output gear embedded portion 71B is a tooth formed by filling one of the grooves of the first output gear spline 71 in an output gear in which the grooves of the first output gear spline 71 are all set to the same shape. This corresponds to the shape of

  The first output gear embedded portion 71B is formed so as to correspond to the shape of the slider gear first output side toothless portion 52B of the slider gear first output spline 52. That is, the slider gear first output spline 52 is formed so as to mesh with only the slider gear first output side toothless portion 52B among the plurality of grooves formed in the spline 52.

A first output arm 73 projecting in the radial direction is formed on the outer peripheral side of the first output gear housing 72.
The first output arm 73 is formed in a substantially triangular shape. Further, a cam surface 73A curved in a concave shape is provided on one side thereof.

  In the first output gear housing 72, a bearing portion 74 for supporting the rocker shaft 43 is provided on a side wall located on a side surface that does not contact the input gear 6 among the side surfaces orthogonal to the central axis of the rocker shaft 43. Yes.

<Structure of second output gear>
FIG. 11 shows a perspective structure of the second output gear 8 (second arm gear).
FIG. 12 shows a side structure of the second output gear 8 as viewed from the direction V5 in FIG.

  In the second output gear 8, a space extending in the axial direction of the rocker shaft 43 is formed inside the second output gear housing 82. A helical spline (second output gear spline 81) that meshes with the slider gear second output spline 53 of the slider gear 5 is formed on the inner peripheral side of the second output gear housing 82. The inclination direction of the tooth trace of the second output gear spline 81 is formed opposite to the inclination direction of the tooth trace of the input gear spline 61.

  The second output gear spline 81 is formed with teeth (second output gear embedded portion 81B) having a circumferential width larger than that of the other teeth 81A. That is, the second output gear spline 81 includes a plurality of teeth 81A having the same circumferential width and the second output gear embedded portion 81B having a circumferential width different from that of the teeth 81A. Is formed. The second output gear toothed portion 81B corresponds to an output gear toothed portion (output-side deformed tooth portion).

  The shape of the second output gear embedded portion 81B is a tooth formed by filling one of the grooves of the second output gear spline 81 in an output gear in which the grooves of the second output gear spline 81 are all set to the same shape. This corresponds to the shape of

  The second output gear embedded portion 81B is formed so as to correspond to the shape of the slider gear second output side toothless portion 53B of the slider gear second output spline 53. That is, the slider gear second output spline 53 is formed so as to mesh with only the slider gear second output side toothless portion 53B among the plurality of grooves formed in the spline 53.

A second output arm 83 protruding in the radial direction is formed on the outer peripheral side of the second output gear housing 82.
The second output arm 83 is formed in a substantially triangular shape. Further, a cam surface 83A curved in a concave shape is provided on one side thereof.

  In the second output gear housing 82, a bearing portion 84 for supporting the rocker shaft 43 is provided on a side wall located on a side surface that does not contact the input gear 6 among the side surfaces orthogonal to the central axis of the rocker shaft 43. Yes.

<Formation position of missing tooth part and buried tooth part>
The formation positions of the missing tooth portion of the slider gear 5 and the buried tooth portions of the gears 6, 7, and 8 will be described.
Here, the input arm reference position, the first output arm reference position, and the second output arm reference position are defined as follows for the circumferential positions of the input arm 63 and the output arms 73 and 83.
[A] As for the position in the circumferential direction of the input arm 63 when the input gear 6 is assembled to the slider gear 5, the position at which the variable valve mechanism 4 can change the maximum valve lift amount as required is the input arm reference. Position.
[B] The position in the circumferential direction of the first output arm 73 when the first output gear 7 is assembled to the slider gear 5 so that the variable valve mechanism 4 can change the maximum valve lift amount as required. Is the first output arm reference position.
[C] A position where the variable valve mechanism 4 can change the maximum valve lift amount as required with respect to the circumferential position of the second output arm 83 when the second output gear 8 is assembled to the slider gear 5. Is the second output arm reference position.

  In the slider gear 5 and the input gear 6, the formation positions of the slider gear input side reference missing tooth portion 51 </ b> B and the input gear reference buried tooth portion 61 </ b> B are the circumferential directions of the input arm 63 when the input gear 6 is assembled to the slider gear 5. Is set to match the input arm reference position.

  In the slider gear 5 and the first output gear 7, the formation positions of the slider gear first output side toothless portion 52 </ b> B and the first output gear embedded portion 71 </ b> B are as follows when the first output gear 7 is assembled to the slider gear 5. The circumferential position of the first output arm 73 is set to coincide with the first output arm reference position.

  In the slider gear 5 and the second output gear 8, the formation positions of the slider gear second output side toothless portion 53 </ b> B and the second output gear embedded portion 81 </ b> B are determined when the first output gear 7 is assembled to the slider gear 5. The circumferential position of the first output arm 73 is set to coincide with the second output arm reference position.

<Assembly mode of variable valve mechanism>
With reference to FIG. 13, an assembly mode of each member constituting the variable valve mechanism 4 will be described.

[1] “Assembly mode of each shaft and slider gear”
The slider gear 5 has a through hole 54 extending in the axial direction and a long hole 55 extending in the circumferential direction. The through hole 54 is formed on the center axis side of the slider gear 5. The long hole 55 is formed between the slider gear input spline 51 and the slider gear second output spline 53.

  The rocker shaft 43 is formed with a long hole 43A extending in the axial direction. The long hole 43 </ b> A is formed on the rocker shaft 43 at a position corresponding to the long hole 55 of the slider gear 5.

  The control shaft 44 is formed with an insertion hole 44A extending in a direction substantially perpendicular to the central axis. The insertion hole 44 </ b> A is formed at a location corresponding to the long hole 43 </ b> A of the rocker shaft 43.

The slider gear 5, the rocker shaft 43, and the control shaft 44 are assembled in the following state.
The control shaft 44 is inserted into the rocker shaft 43.
The control shaft 44 and the rocker shaft 43 are inserted into the through hole 54 of the slider gear 5.
A locking pin 56 is inserted into the long hole 55 of the slider gear 5 and the long hole 43 </ b> A of the rocker shaft 43.
One end of the locking pin 56 is fixed to the insertion hole 44 </ b> A of the control shaft 44.

The slider gear 5 can move as follows.
(A) Since the locking pin 56 can move along the long hole 43A of the rocker shaft 43, the slider gear 5 is interlocked with the control shaft 44 when the control shaft 44 is moved in the axial direction. To move in the axial direction.
(B) Since the locking pin 56 is inserted into the elongated hole 55 of the slider gear 5, the slider gear 5 swings around the rocker shaft 43 when the torque of the intake camshaft 23 is transmitted to the input gear 6. It becomes like this.

  As described above, the slider gear 5 can move in the axial direction on the rocker shaft 43 while the position in the axial direction on the control shaft 44 is fixed. Further, the rocker shaft 43 (control shaft 44) can be swung around a fulcrum.

[2] “Assembly mode of slider gear and each gear”
The slider gear 5, the input gear 6, the first output gear 7, and the second output gear 8 are assembled in the following state.
The slider gear 5 and the input gear 6 are assembled so that the slider gear input side reference toothless portion 51B of the slider gear input spline 51 and the input gear reference toothed portion 61B of the input gear spline 61 are engaged with each other.
The slider gear 5 and the first output gear 7 mesh with the slider gear first output side toothless portion 52B of the slider gear first output spline 52 and the first output gear embedded portion 71B of the first output gear spline 71. Assembled.
The slider gear 5 and the second output gear 8 mesh with the slider gear second output side toothless portion 53B of the slider gear second output spline 53 and the second output gear embedded portion 81B of the second output gear spline 81. Assembled.

<Change mode of maximum valve lift>
FIG. 14 shows the variable valve mechanism 4 in a state in which the upper half of the input gear 6 and the output gears 7 and 8 is removed.

  In the variable valve mechanism 4, the slider gear 5 is moved in the axial direction together with the control shaft 44, and the relative position in the axial direction between the slider gear 5, the input gear 6, and the output gears 7 and 8 is changed. Twisting forces in opposite directions are applied to the input gear 6 and the output gears 7 and 8.

  As a result, the input gear 6 and the output gears 7 and 8 rotate relative to each other, and the relative phase difference between the input gear 6 (input arm 63) and the output gears 7 and 8 (output arms 73 and 83) is changed. The In the variable valve mechanism 4, since all the slider gears 5 are fixed to a common control shaft 44, the maximum valve lifts of all the intake valves 21 are simultaneously generated as the control shaft 44 moves. Be changed.

In the engine 1, the maximum valve lift amount of the intake valve 21 can be changed by changing the relative phase difference between the input gear 6 and the output gears 7 and 8.
The maximum valve lift varies through the movement of the control shaft 44 as follows.
(A) When the relative phase difference is the smallest, that is, when the input arm 63 and the output arms 73 and 83 are closest to each other in the circumferential direction, the maximum valve lift amount of the intake valve 21 is the smallest.
(B) When the relative phase difference is the largest, that is, when the input arm 63 and the output arms 73 and 83 are most distant from each other in the circumferential direction, the maximum valve lift amount of the intake valve 21 is the largest.

<Valve lift structure of engine>
FIG. 15 shows a cross-sectional structure of the engine 1 along the line D1-D1 in FIG.
In the cylinder head 12, the variable valve mechanism 4 is disposed in the vicinity of the intake camshaft 23. A roller rocker arm 31 (valve driving device) is provided between the variable valve mechanism 4 and the intake valve 21. One end of the roller rocker arm 31 is supported by a lash adjuster 32 fixed to the cylinder head 12. The other end of the roller rocker arm 31 is in contact with a tappet 33 at the upper end of the intake valve 21.

  The end portion on the tappet 33 side (the tappet side end portion 31 </ b> A) of the roller rocker arm 31 is urged toward the variable valve mechanism 4 by the valve spring 34 of the intake valve 21. As a result, the roller 31B of the roller rocker arm 31 always comes into contact with the valve lift mechanism 4A.

  The roller 63B of the input gear 6 is biased toward the intake camshaft 23 by a spring 35 disposed in a compressed state on the cylinder head 12. As a result, the roller 63B of the input gear 6 always comes into contact with the intake cam 25 of the intake camshaft 23.

  In each of the output gears 7 and 8, one of the base circular portions of the housings 72 and 82 and the cam surfaces 73 </ b> A and 83 </ b> A of the output arms 73 and 83 is always in contact with the roller 31 </ b> B of the roller rocker arm 31.

  In the engine 1, the input gear 6 is pushed as the intake camshaft 23 rotates. At this time, the torque of the intake camshaft 23 is transmitted to the output gears 7 and 8 via the input gear 6 and the slider gear 5. Then, the corresponding roller rocker arm 31 is pressed through the swinging of the output gears 7 and 8, and the intake valve 21 is lifted accordingly.

<Effect of embodiment>
As described above in detail, according to the variable valve mechanism of the engine according to the first embodiment, the following effects can be obtained.

  (1) In the variable valve mechanism 4 of this embodiment, the slider gear input side reference toothless portion 51B is formed in the slider gear input spline 51 of the slider gear 5, and the same toothless portion 51B is formed in the helical spline of the input gear 6. The input gear reference embedded portion 61B corresponding to the above is formed.

  Thus, when the slider gear 5 and the input gear 6 are assembled, the input gear 6 can be assembled to the slider gear 5 only at a phase where the slider gear input side reference missing tooth portion 51B and the input gear reference buried tooth portion 61B coincide. Therefore, the position of the input arm 63 in the circumferential direction can be prevented from shifting from the input arm reference position. That is, it is possible to prevent the input gear 6 from being assembled to the slider gear 5 in a state where the circumferential position of the input arm 63 is shifted from the correct position.

  (2) In the variable valve mechanism 4 of this embodiment, the slider gear first output spline 52 of the slider gear 5 is formed with the slider gear first output side toothless portion 52B, and the first output of the first output gear 7 is output. A first output gear embedded portion 71B corresponding to the missing tooth portion 52B is formed in the gear spline 71.

  Thus, when the slider gear 5 and the first output gear 7 are assembled, the first output to the slider gear 5 is performed only in the phase where the slider gear first output side toothless portion 52B and the first output gear embedded portion 71B coincide. Since the gear 7 can be assembled, it is possible to prevent the circumferential position of the first output arm 73 from deviating from the first output arm reference position. That is, it is possible to prevent the first output gear 7 from being assembled to the slider gear 5 in a state where the circumferential position of the first output arm 73 is shifted from the correct position.

  (3) In the variable valve mechanism 4 according to the present embodiment, the slider gear second output spline 53 of the slider gear 5 is formed with the slider gear second output side toothless portion 53B, and the second output of the second output gear 8 is output. The gear spline 81 is formed with a second output gear embedded portion 81B corresponding to the missing tooth portion 53B.

  Thus, when the slider gear 5 and the second output gear 8 are assembled, the second output to the slider gear 5 is performed only in a phase where the slider gear second output side toothless portion 53B and the second output gear buried portion 81B coincide. Since the gear 8 can be assembled, it is possible to suppress the circumferential position of the second output arm 83 from deviating from the second output arm reference position. That is, the second output gear 8 can be prevented from being assembled to the slider gear 5 in a state where the circumferential position of the second output arm 83 is deviated from the correct position.

  (4) In the present embodiment, as shown in the above (1) to (3), deformed teeth (missed teeth or embedded teeth) are formed on the helical splines of the respective gears 5, 6, 7 and 8. Thus, a positioning function is realized when the slider gear 5 and each arm gear (input gear 6, first output gear 7, and second output gear 8) are assembled. Accordingly, it is possible to suppress errors in the assembly positions of the arm gears without providing a separate positioning mechanism for the gears 5, 6, 7, and 8.

<Example of change>
In addition, the said 1st Embodiment can also be implemented as the following forms which changed this suitably, for example.

  In the first embodiment, the slider gear input spline 51 is formed with one slider gear input side reference missing tooth portion 51B. However, the slider gear input spline 51 has a plurality of slider gear input side reference missing tooth portions 51B. Can also be formed.

-In the said 1st Embodiment, the shape and formation position of the slider gear input side reference | standard missing tooth part 51B can be changed suitably.
In the first embodiment, the slider gear first output spline 52 has one slider gear first output side toothless portion 52B. However, the slider gear first output spline 52 has a plurality of slider gear firsts. The output side missing tooth portion 52B can also be formed.

-In the said 1st Embodiment, the shape and formation position of the slider gear 1st output side missing tooth part 52B can be changed suitably.
In the first embodiment, the slider gear second output spline 53 is formed with one slider gear second output side toothless portion 53B. However, the slider gear second output spline 53 has a plurality of slider gear second gears. The output side missing tooth portion 53B can also be formed.

-In the said 1st Embodiment, the shape and formation position of the slider gear 2nd output side missing tooth part 53B can be changed suitably.
(Second Embodiment)
A second embodiment of the present invention will be described with reference to FIGS.

  According to the variable valve mechanism 4 of the first embodiment, it is possible to suppress the circumferential position of the input arm 63 from deviating from the input arm reference position, but the following is a problem. Become.

  Here, with the posture of the input gear 6 in which the input arm 63 coincides with the input arm reference position as a reference posture, the posture rotated 180 degrees from the reference posture around the axis orthogonal to the central axis of the input gear 6 is reversed. And

  In the variable valve mechanism 4 of the first embodiment, the input gear 6 in the reverse posture can be assembled to the slider gear 5. In this case, since the circumferential position of the input arm 63 deviates from the input arm reference position, the variable valve mechanism 4 cannot function properly.

  Therefore, in the present embodiment, in order to avoid such an assembly error, the following changes are added to the variable valve mechanism of the first embodiment. The variable valve mechanism of this embodiment is the same as that of the first embodiment except for the configuration described below.

<Slider gear structure>
FIG. 16 shows a perspective structure of the slider gear 5.
FIG. 17 shows a side structure of the slider gear 5 as viewed from the direction V6 in FIG.

  The slider gear input spline 51 of the slider gear 5 is formed with a groove (slider gear input side auxiliary toothless portion 51C) having a larger circumferential width than the other grooves 51A. That is, the slider gear input spline 51 includes a plurality of grooves 51A having the same width in the circumferential direction, and one slider gear input side reference toothless portion 51B and a slider different in the circumferential width from these grooves 51A. It is formed including the gear input side auxiliary missing tooth portion 51C. The slider gear input side auxiliary toothless portion 51C corresponds to the slider gear input side toothless portion (input side irregular tooth portion).

  In the slider gear input spline 51, the formation position of the slider gear input side reference toothless portion 51B and the formation position of the slider gear input side auxiliary toothless portion 51C are set to positions that are asymmetric in the radial direction. In other words, the slider gear input side reference toothless portion so that the cross-sectional shape of the spline 51 perpendicular to the axis of the slider gear input spline 51 is asymmetric with respect to the center line (radial line passing through the axis). 51B and a slider gear input side auxiliary toothless portion 51C are formed.

  The slider gear input side auxiliary toothless portion 51C is formed by removing the adjacent two teeth of the slider gear input spline 51 in the slider gear in which the teeth of the slider gear input spline 51 are all formed in the same shape. Corresponds to the shape of the groove.

<Structure of input gear>
FIG. 18 shows a perspective structure of the input gear 6.
FIG. 19 shows a side structure of the input gear 6 viewed from the direction V7 in FIG.

  The input gear spline 61 of the input gear 6 is formed with teeth (input gear auxiliary embedded portion 61C) whose circumferential width is set larger than that of the other teeth 61A. That is, the input gear spline 61 includes a plurality of teeth 61A having the same circumferential width, and one input gear reference embedded portion 61B and an input gear auxiliary buried portion having a circumferential width different from the teeth 61A. It is formed including the tooth portion 61C. The input gear auxiliary tooth portion 61C corresponds to an input gear tooth portion (input-side deformed tooth portion).

  The shape of the input gear auxiliary tooth portion 61C is a tooth shape formed by filling two adjacent grooves of the input gear spline 61 in an input gear in which the grooves of the input gear spline 61 are all set to the same shape. Equivalent to.

  The input gear auxiliary buried tooth portion 61 </ b> C is formed to correspond to the shape and position of the slider gear input side auxiliary toothless portion 51 </ b> C of the slider gear input spline 51. That is, the slider gear input spline 51 is formed so as to mesh with only the slider gear input side auxiliary toothless portion 51 </ b> C among the plurality of grooves formed in the spline 51.

<Effect of embodiment>
As described above in detail, according to the variable valve mechanism of the engine according to the second embodiment, in addition to the effects (1) to (4) according to the first embodiment, the following is shown. An effect comes to be acquired.

  (5) In the variable valve mechanism 4 of the present embodiment, the slider gear input side auxiliary toothless portion 51C is formed in the slider gear input spline 51 of the slider gear 5, and the same toothless portion 51C is formed in the helical spline of the input gear 6. An input gear auxiliary tooth portion 61C corresponding to the above is formed.

  As a result, when the input gear 6 is in the reverse orientation, the input gear 6 cannot be assembled to the slider gear 5, so that the circumferential position of the input arm 63 can be avoided from deviating from the input arm reference position. become. That is, the input gear 6 can be prevented from being assembled to the slider gear 5 in a state where the circumferential position of the input arm 63 is shifted from the correct position.

<Example of change>
In addition, the said 2nd Embodiment can also be implemented as the following forms which changed this suitably, for example.

  In the second embodiment, the circumferential width of the slider gear input side auxiliary toothless portion 51C is set to be larger than the circumferential width of the slider gear input side reference toothless portion 51B. It can also be changed. That is, the circumferential width of the slider gear input side auxiliary toothless portion 51C can be set smaller than the circumferential width of the slider gear input side reference toothless portion 51B. Further, the circumferential width of the slider gear input side auxiliary toothless portion 51C can be set to the same size as the circumferential width of the slider gear input side reference toothless portion 51B.

  In either case, the formation position of the slider gear input side reference toothless portion 51B and the formation position of the slider gear input side auxiliary toothless portion 51C are set to positions that are asymmetric in the radial direction. That is, the formation positions of the respective missing tooth portions 51B and 51C are set to positions where the cross-sectional shape of the spline 51 perpendicular to the axis of the slider gear input spline 51 is asymmetric with respect to the center line.

  In the second embodiment, the slider gear input spline 51 is formed with the slider gear input side reference toothless portion 51B so that the cross sectional shape of the spline 51 perpendicular to the axis of the slider gear input spline 51 is based on the center line. However, it can be modified as follows, for example. That is, a plurality of slider gear input side reference toothless portions 51B are formed in the slider gear input spline 51, and the formation positions of the plurality of slider gear input side reference toothless portions 51B are set to positions that are asymmetric in the radial direction. Thus, the cross-sectional shape of the slider gear input spline 51 can also be asymmetric.

  In short, if the cross-sectional shape of the spline 51 perpendicular to the axis of the slider gear input spline 51 is formed in an asymmetric shape with respect to the center line, the shape, forming position, and number of each missing tooth portion are It can be changed as appropriate. Such an asymmetrical cross-sectional shape is that the slider gear input spline 51 has a plurality of missing teeth (grooves having different circumferential widths from the groove 51A (slider gear input side reference missing teeth 51B and slider gear input side auxiliary missing teeth). This can be realized by forming the part 51C and the like) and setting the positions where these missing teeth are asymmetric in the radial direction.

(Third embodiment)
A third embodiment of the present invention will be described with reference to FIGS.
According to the variable valve mechanism 4 of the first and second embodiments, the circumferential position of the first output arm 73 / second output arm 83 is the first output arm reference position / second output arm reference position. Although it becomes possible to suppress deviation from the following, the following becomes a problem.

  In the variable valve mechanism 4 of the first and second embodiments, the first output gear 7 can be assembled to the slider gear second output spline 53. Further, the second output gear 8 can be assembled to the slider gear first output spline 52. In such a case, the position of the first output arm 73 / second output arm 83 in the circumferential direction deviates from the first output arm reference position / second output arm reference position, so that the variable valve mechanism 4 can function properly. Disappear.

  Therefore, in the present embodiment, in order to avoid such an assembly error, a change described below is added to the variable valve mechanism of the second embodiment. The variable valve mechanism of the present embodiment is the same as that of the second embodiment except for the configuration described below.

<Slider gear structure>
FIG. 20 shows a perspective structure of the slider gear 5.
FIG. 21 shows a side structure of the slider gear 5 as viewed from the direction V8 in FIG.

  In the present embodiment, the circumferential width of the slider gear first output side toothless portion 52B of the slider gear first output spline 52 and the slider gear second output side toothless portion 53B of the slider gear second output spline 53 are set to be circumferential. It is set to a different size. Here, the circumferential width of the slider gear first output side toothless portion 52B is set larger than the circumferential width of the slider gear second output side toothless portion 53B.

  That is, the cross-sectional shape of the spline 52 orthogonal to the axis of the slider gear first output spline 52 is different from the cross-sectional shape of the spline 53 orthogonal to the axis of the slider gear second output spline 53. Thus, the circumferential widths of the respective missing tooth portions 52B and 53B are set to different sizes.

  The slider gear first output side toothless portion 52B has two adjacent ones of the teeth of the slider gear first output spline 52 in the slider gear in which the teeth of the slider gear first output spline 52 are all set to the same shape. This corresponds to the shape of the groove formed except for.

<Structure of the first output gear>
FIG. 22 shows a perspective structure of the first output gear 7.
FIG. 23 shows a side structure of the first output gear 7 viewed from the direction V9 in FIG.

  In the present embodiment, the circumferential widths of the first output gear embedded portion 71B of the first output gear spline 71 and the second output gear embedded portion 81B of the second output gear spline 81 are set to different sizes. ing. That is, the circumferential width of the first output gear embedded portion 71B is set larger than the circumferential width of the second output gear embedded portion 81B.

  The shape of the first output gear embedded portion 71B is such that, in the first output gear in which all the grooves of the first output gear spline 71 are set to the same shape, two adjacent ones of the grooves of the first output gear spline 71 are filled. This corresponds to the shape of the tooth formed.

  The first output gear embedded portion 71 </ b> B is formed to correspond to the shape and position of the slider gear first output side toothless portion 52 </ b> B of the slider gear first output spline 52. That is, the slider gear first output spline 52 is formed so as to mesh with only the slider gear first output side toothless portion 52B among the plurality of grooves formed in the spline 52.

<Effect of embodiment>
As described above in detail, according to the variable valve mechanism for an engine according to the third embodiment, in addition to the effects (1) to (5) according to the second embodiment, as shown below. An effect comes to be acquired.

  (6) In the variable valve mechanism 4 of the present embodiment, the slider gear first output side toothless portion 52B of the slider gear first output spline 52 and the slider gear second output side toothless portion of the slider gear second output spline 53. 53B is set to a different size. In response to this, the first output gear toothed portion 71B of the first output gear 7 and the second output gear toothed portion 81B of the second output gear 8 are set to different sizes.

  As a result, the first output gear 7 cannot be assembled to the slider gear second output spline 53, and the second output gear 8 cannot be assembled to the slider gear first output spline 52. Therefore, the first output arm 73 / second The position of the output arm 83 in the circumferential direction can be prevented from deviating from the first output arm reference position / second output arm reference position. That is, the first output gear 7 / second output gear 8 is prevented from being assembled to the slider gear 5 in a state where the circumferential position of the first output arm 73 / second output arm reference position is deviated from the correct position. Will be able to.

<Example of change>
In addition, the said 3rd Embodiment can also be implemented as the following forms which changed this suitably, for example.

  In the third embodiment, the circumferential width of the slider gear first output side toothless portion 52B is set larger than the circumferential width of the slider gear second output side toothless portion 53B. The circumferential width of the gear second output side toothless portion 53B can be set larger than the circumferential width of the slider gear first output side toothless portion 52B.

  In the third embodiment, the slider gear first output side toothless portion 52B is set to have a larger width in the circumferential direction than the slider gear second output side toothless portion 53B. Although the cross-sectional shape of the first output spline 52 and the cross-sectional shape of the slider gear second output spline 53 are made different from each other, it can be changed as follows. That is, the number of slider gear first output side toothless portions 52B formed on the slider gear first output spline 52 and the number of slider gear second output side toothless portions 53B formed on the slider gear second output spline 53 are mutually equal. By setting the different values, the cross-sectional shape of the slider gear first output spline 52 and the cross-sectional shape of the slider gear second output spline 53 can be made different.

  In short, the cross-sectional shape of the spline 52 orthogonal to the axis of the slider gear first output spline 52 is different from the cross-sectional shape of the spline 53 orthogonal to the axis of the slider gear second output spline 53. If it is the structure used as a shape, the shape and number of each missing tooth part 52B and 53B can be changed suitably.

(Other embodiments)
In addition, elements that can be changed in common with each of the above embodiments are listed below.
In the above embodiments, the configurations of the slider gear 5 and the input gear 6 can be changed as follows. That is, the slider gear input spline 51 is formed with teeth (slider gear input side embedded portion) having a circumferential width different from other teeth, and a groove (input gear missing tooth) that engages with the slider gear input side embedded portion. Part) can also be formed in the input gear spline 61. When such a configuration is adopted, for example, the slider gear input spline 51 is formed including a plurality of teeth having the same circumferential width and the slider gear input-side reference embedded portion, and the circumferential direction The input gear spline 61 can be formed including a plurality of grooves and the input gear missing tooth portion having the same width.

  In the above embodiments, the configurations of the slider gear 5 and the first output gear 7 can be changed as follows. In other words, the slider gear first output spline 52 is formed with teeth (slider gear output side buried tooth portion) having a width different from that of the other teeth, and is engaged with the slider gear output side buried tooth portion (output gear). (Missing tooth portion) can also be formed in the first output gear spline 71. When such a configuration is adopted, for example, the slider gear first output spline 52 is formed including a plurality of teeth set with the same width in the circumferential direction and the slider gear first output side embedded portion, The first output gear spline 71 can be formed including a plurality of grooves and the output gear missing tooth portion having the same width in the circumferential direction.

  In the above embodiments, the configurations of the slider gear 5 and the second output gear 8 can be changed as follows. In other words, the slider gear second output spline 53 is formed with teeth (slider gear output side embedded portion) having a different width in the circumferential direction from the other teeth, and a groove (output gear) meshing with the slider gear output side embedded portion. (Missing tooth portion) can be formed in the second output gear spline 81. When such a configuration is adopted, for example, the slider gear second output spline 53 is formed including a plurality of teeth set to the same width in the circumferential direction and the slider gear output side embedded portion, and the circumferential direction The second output gear spline 81 can be formed including a plurality of grooves set to the same size and the output gear missing tooth portion.

  In each of the above embodiments, the output gear housings 72 and 82 have a structure in which the side surfaces that do not contact the input gear 6 are closed by the side walls on which the bearing portions 74 and 84 are formed. The output gear housings 72 and 82 that are opened in the same manner as the side surfaces can be employed. In this case, a plurality of output-side deformed tooth portions are formed in the slider gear 5 and the output gears 7 and 8, and the formation positions of the plurality of missing tooth portions are set to positions that are asymmetric in the radial direction. When the gears 7 and 8 are in the reverse posture, the output gears 7 and 8 cannot be assembled to the slider gear 5. As a result, it is possible to avoid the circumferential positions of the output arms 73 and 83 from deviating from the output arm reference position.

  The variable valve mechanism to which the present invention is applied is not limited to the variable valve mechanism exemplified in the above embodiments. In short, it is a variable valve mechanism that includes a slider gear and a plurality of arm gears that are engaged with the helical spline of the slider gear and assembled on the slider gear, and that changes the maximum valve lift amount through movement of the slider gear in the axial direction. The present invention can be applied to any variable valve mechanism as long as it exists.

The top view which shows the planar structure of the engine which mounts the variable valve mechanism about 1st Embodiment which actualized the variable valve mechanism of the engine concerning this invention. The perspective view which shows the perspective structure about the variable valve mechanism of the engine of the embodiment. The disassembled perspective view which shows the disassembled perspective structure about the variable valve mechanism of the engine of the embodiment. The perspective view which shows the perspective structure of the slider gear which comprises the variable valve mechanism of the engine of the embodiment. The side view which shows the side structure seen from the V1 direction of FIG. 4 about the slider gear of the embodiment. The side view which shows the side structure seen from the V2 direction of FIG. 4 about the slider gear of the embodiment. The perspective view which shows the perspective structure of the input gear which comprises the variable valve mechanism of the engine of the embodiment. The side view which shows the side structure seen from the V3 direction of FIG. 7 about the input gear of the embodiment. The perspective view which shows the perspective structure of the 1st output gear which comprises the variable valve mechanism of the engine of the embodiment. The side view which shows the side structure seen from the V4 direction of FIG. 9 about the 1st output gear of the embodiment. The perspective view which shows the perspective structure of the 2nd output gear which comprises the variable valve mechanism of the engine of the embodiment. The perspective view which shows the perspective structure seen from the V5 direction of FIG. 11 about the 2nd output gear of the embodiment. The disassembled perspective view which shows the disassembled perspective structure about the variable valve mechanism of the engine of the embodiment. The perspective view which shows the perspective structure of the state which fractured | ruptured a part about the variable valve mechanism of the engine of the embodiment. Sectional drawing which shows the cross-sectional structure along the D1-D1 line | wire of FIG. 1 about the engine of the embodiment. The perspective view which shows the perspective structure of the slider gear which comprises the variable valve mechanism about 2nd Embodiment which actualized the variable valve mechanism of the engine concerning this invention. The side view which shows the side structure seen from the V6 direction of FIG. 16 about the variable valve mechanism of the engine of the embodiment. The perspective view which shows the perspective structure of the input gear which comprises the variable valve mechanism of the engine of the embodiment. The side view which shows the side structure seen from the V7 direction of FIG. 18 about the input gear of the embodiment. The perspective view which shows the perspective structure of the slider gear which comprises the variable valve mechanism about 3rd Embodiment which actualized the variable valve mechanism of the engine concerning this invention. The side view which shows the side structure seen from the V8 direction of FIG. 20 about the slider gear of the embodiment. The perspective view which shows the perspective structure of the 1st output gear which comprises the variable valve mechanism of the engine of the embodiment. The side view which shows the side structure seen from the V9 direction of FIG. 22 about the 1st output gear of the embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Engine, 11 ... Cylinder block, 12 ... Cylinder head, 13 ... Cylinder, 14 ... Timing chain, 15 ... Crankshaft, 16 ... Bulkhead, 21 ... Intake valve, 22 ... Exhaust valve, 23 ... Intake camshaft, 24 ... Exhaust cam shaft, 25 ... intake cam, 26 ... exhaust cam, 31 ... roller rocker arm, 31A ... tappet side end, 31B ... roller, 32 ... lash adjuster, 33 ... tappet, 34 ... valve spring, 35 ... spring.

  DESCRIPTION OF SYMBOLS 4 ... Variable valve mechanism, 41 ... Valve mechanism main body, 42 ... Actuator, 43 ... Rocker shaft, 43A ... Long hole, 44 ... Control shaft, 44A ... Insertion hole, 4A ... Valve lift mechanism.

  5 ... Slider gear, 51 ... Slider gear input spline, 51A ... Groove, 51B ... Slider gear input side reference toothless part, 51C ... Slider gear input side auxiliary buried tooth part, 52 ... Slider gear first output spline, 52A ... Groove , 52B ... slider gear first output side toothless portion, 53 ... slider gear second output spline, 53A ... groove, 53B ... slider gear second output side toothless portion, 54 ... through hole, 55 ... long hole, 56 ... Locking pin.

  6 ... input gear, 61 ... input gear spline, 61A ... tooth, 61B ... input gear reference toothed portion, 61C ... input gear auxiliary toothed portion, 62 ... input gear housing, 63 ... input arm, 63A ... shaft, 63B ... Roller, 63L ... support arm, 63R ... support arm.

  7 ... 1st output gear, 71 ... 1st output gear spline, 71A ... Teeth, 71B ... 1st output gear embedded part, 72 ... 1st output gear housing, 73 ... 1st output arm, 73A ... Cam surface, 74 ... bearing part.

  8 ... second output gear, 81 ... second output gear spline, 81A ... tooth, 81B ... second output gear embedded portion, 82 ... second output gear housing, 83 ... second output arm, 83A ... cam surface, 84 ... bearing part.

  9: Electronic control device.

Claims (11)

  A slider gear disposed on the cylinder head in a state of being movable in the axial direction; and a plurality of arm gears engaged with the helical spline of the slider gear and assembled on the slider gear. In an engine variable valve mechanism that changes a maximum valve lift amount of an engine valve by changing a relative phase of an arm provided in each of the plurality of arm gears through movement,
  A plurality of deformed tooth portions having different shapes from other portions are formed in a part of the helical spline of the slider gear and a part of the helical spline of the arm gear that meshes with the helical spline, and the formation positions of the plurality of deformed tooth portions are in the radial direction. Set to asymmetric position
  A variable valve mechanism for an engine.   The variable valve mechanism for an engine according to claim 1,
  The variable valve mechanism includes a first arm gear and a second arm gear corresponding to a pair of engine valves as the plurality of arm gears,
  The helical spline of the first arm gear and the deformed tooth portion of the helical spline of the slider gear meshing with the helical spline, and the helical spline of the second arm gear and the deformed tooth portion of the helical spline of the slider gear meshing with the helical spline , The shapes of these irregularly shaped teeth are set to different shapes.
  A variable valve mechanism for an engine.   The variable valve mechanism for an engine according to claim 1,
  The variable valve mechanism includes a first arm gear and a second arm gear corresponding to a pair of engine valves as the plurality of arm gears,
  The helical spline of the first arm gear and the deformed tooth portion of the helical spline of the slider gear meshing with the helical spline, and the helical spline of the second arm gear and the deformed tooth portion of the helical spline of the slider gear meshing with the helical spline The number of these deformed teeth is set to be different from each other.
  A variable valve mechanism for an engine.   It has a valve lift mechanism that is arranged on the cylinder head and lifts the engine valve,
  The valve lift mechanism is provided with a slider gear movable in the axial direction, an input gear provided with an input arm pushed through the camshaft of the engine valve, and an output arm pushing the valve drive device of the engine valve. An output gear, and
  The input gear is provided on the slider gear in mesh with an input side helical spline formed on the slider gear,
  The output gear is provided on the slider gear in mesh with an output-side helical spline formed on the slider gear,
  In an engine variable valve mechanism that changes a maximum valve lift amount of the engine valve by changing a relative phase between the input arm and the output arm through movement of the slider gear in the axial direction.
  The input-side helical spline and a part of the helical spline of the input gear that meshes with the helical spline are formed with a plurality of input-side deformed teeth that are different in shape from other parts, and mesh with the output-side helical spline and the helical spline. An output-side deformed tooth portion having a shape different from that of the other portion is formed in a part of the helical spline of the output gear, and the formation positions of the plurality of input-side deformed tooth portions are set to asymmetric positions in the radial direction.
  A variable valve mechanism for an engine.   The variable valve mechanism for an engine according to claim 4,
  A plurality of the output side irregular tooth portions are formed, and the formation positions of the plurality of output side irregular tooth portions are set at asymmetrical positions in the radial direction.
  A variable valve mechanism for an engine.   The variable valve mechanism for an engine according to claim 4 or 5,
  The variable valve mechanism includes a first output gear and a second output gear corresponding to a pair of engine valves as the output gear,
  The helical spline of the first output gear and the output-side deformed tooth portion of the output-side helical spline that meshes with the helical spline; the helical spline of the second output gear; and the output-side variant of the output-side helical spline that meshes with the helical spline About the tooth part, the shapes of these deformed tooth parts are set to different shapes.
  A variable valve mechanism for an engine.   The variable valve mechanism for an engine according to claim 4 or 5,
  The variable valve mechanism includes a first output gear and a second output gear corresponding to a pair of engine valves as the output gear,
  The helical spline of the first output gear and the output-side deformed tooth portion of the output-side helical spline that meshes with the helical spline; the helical spline of the second output gear; and the output-side variant of the output-side helical spline that meshes with the helical spline About the tooth part, the number of these deformed tooth parts is set to be different from each other.
  A variable valve mechanism for an engine.   The variable valve mechanism for an engine according to any one of claims 4 to 7,
  The input-side helical spline includes a plurality of grooves whose circumferential widths are set to the same size, and a plurality of grooves that are set to have different circumferential widths. It is formed including the tooth part,
  The helical spline of the input gear is formed including an input gear embedded tooth portion as a tooth meshing with the slider gear input side missing tooth portion,
  The input side deformed tooth portion is constituted by the slider gear input side missing tooth portion and the input gear embedded tooth portion.
  A variable valve mechanism for an engine.   The variable valve mechanism for an engine according to any one of claims 4 to 7,
  The input-side helical spline includes a plurality of teeth whose circumferential width is set to the same size, and a plurality of teeth that have a circumferential width different from that of the plurality of teeth. It is formed including the tooth part,
  The helical spline of the input gear is formed including a force gear missing tooth portion as a groove meshing with the slider gear input-side buried tooth portion,
  The input side deformed tooth portion is constituted by the slider gear input side toothed portion and the input gear missing tooth portion.
  A variable valve mechanism for an engine.   The variable valve mechanism for an engine according to any one of claims 4 to 9,
  The output-side helical spline has a plurality of grooves whose circumferential widths are set to the same size, and the slider gear output side cutouts as grooves having different circumferential widths. It is formed including the tooth part,
  The helical spline of the output gear is formed including an output gear embedded portion as a tooth that meshes with the slider gear output side missing tooth portion,
  The output side irregular tooth portion is constituted by the slider gear output side missing tooth portion and the output gear embedded tooth portion.
  A variable valve mechanism for an engine.   The variable valve mechanism for an engine according to any one of claims 4 to 9,
  The output-side helical spline includes a plurality of teeth whose circumferential widths are set to the same size, and the slider gear output-side embedded as teeth whose circumferential widths are different from each other. It is formed including the tooth part,
  The helical spline of the output gear is formed including an output gear missing tooth portion as a groove meshing with the slider gear output-side buried tooth portion,
  The output side irregular tooth portion is constituted by the slider gear output side tooth embedded portion and the output gear missing tooth portion.
  A variable valve mechanism for an engine.

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