JP5586087B2 - Variable valve mechanism for internal combustion engine - Google Patents

Description

  The present invention relates to a variable valve mechanism for an internal combustion engine.

  Conventionally, in a variable valve device for an internal combustion engine, a hydraulically driven slide pin for changing the engagement state between a valve stem and a valve lifter is provided in a valve lifter that is constantly pressed against a cam of a camshaft by a spring. An operation mode that can be switched between an open / close operation state and a pause state is disclosed (see, for example, Patent Document 1). Patent Document 1 discloses a configuration in which a valve stem of a valve is pushed down by a rocker arm driven by a cam of a camshaft.

JP 2009-161004 A

By the way, when the variable valve mechanism using the valve lifter that is always pressed by the conventional spring is applied to the valve that is pushed down by the rocker arm as described above, the spring force is applied to the rocker arm by the valve lifter pressed against the spring. Acts, and the camshaft is pressed by the rocker arm. For this reason, when the camshaft is removed from the cam holder that supports the camshaft for maintenance, the camshaft cannot be removed unless the rocker arm is removed.
The present invention has been made in view of the above-described circumstances, and an object of the present invention is to improve the maintainability of a variable valve operating apparatus for an internal combustion engine by allowing the camshaft to be removed without removing the rocker arm.

In order to achieve the above object, the present invention includes a valve lifter (13E) driven by a rocker arm (27) interlocked with a valve cam (25) and interposed between valve stems (12c) of a poppet valve (12). The slide pin is slidably supported in the lifter guide hole (91), and is urged by the lifter spring (90) in a direction to always contact the rocker arm (27). The slide pin is controlled by hydraulic pressure in the valve lifter (13E). In the variable valve mechanism for an internal combustion engine that moves the valve (86) to change the valve operation, the cam holder (51) of the valve cam (25) is inclined with respect to the deck surface (19) of the cylinder head (4r). provided, the other valve mechanism which is linked to one of the valve operating mechanism driven by a rocker arm (27) (10E) (10I ) is a valve lifter The cam valve (25) is configured to be directly pressed, and the mating surface (55) of the cam holder (51) is provided in parallel to the top surface (32) of the direct pressure side valve lifter (13I). 51) between the head side holder (52) formed on the cylinder head (4r) side and the head side holder (52) and the valve side cam (25) between the head side holder (52). ) And a shaft support hole (54) into which the valve cam (25) is fitted, and the mating surface (55) includes the head side holder (52) and the cap. (53) is a surface where the mating surface (55) is inclined downwardly with respect to the deck surface (19) on the opposite side to the rocker arm (27), and is inclined and lowered. Of the head side holder (52 A space (M) positioned below the center (O1) of the shaft support hole (54) is provided between the deck support surface (19) and the center of the shaft support hole (54) ( O1) is provided in accordance with the height of the deck surface (19) .
According to this configuration, in the variable valve mechanism in which the valve lifter is always brought into contact with the rocker arm interlocked with the valve cam by the lifter spring, the cam holder of the valve cam is inclined with respect to the deck surface of the cylinder head. Since it provided, the valve-operating cam can be removed to the inclination direction side of the cam holder. For this reason, the valve cam can be removed without removing the rocker arm, and the maintainability can be improved. Further, since the mating surface of the cam holder is parallel to the top surface of the direct pressing side valve lifter, the cam holder can efficiently receive the force acting on the valve operating cam from the direct pressing side valve lifter. In addition, the mating surface of the head side holder and cap is inclined downward with respect to the deck surface on the side opposite to the rocker arm, and the valve cam can be removed on the side opposite to the rocker arm, so the rocker arm is removed. Therefore, the valve cam can be removed without any problem, and the maintainability can be improved.

Further, in the above configuration, the inclination of the mating surface (55) of the cam holder (51) is such that the contact side (27a) of the rocker arm (27) with the valve cam (25) is placed on the valve cam (25). ) With respect to the tangential extension (S) of the base circle (31a) of the valve cam (25) perpendicular to the mating surface (55) of the cam holder (51). You may incline so that the said contact side (27a) of the said rocker arm (27) may be located in the opposite side to a valve cam (25).
In this case, the inclination of the mating surface of the cam holder is such that the tangent to the base circle of the valve cam perpendicular to the mating surface of the cam holder when the abutment side of the rocker arm with the valve cam is most distant from the valve cam. Since it is inclined so that the contact side of the rocker arm is positioned on the opposite side of the valve cam relative to the extension line, the contact side of the rocker arm does not get in the way when the valve cam is removed. For this reason, the valve cam can be removed without removing the rocker arm, and the maintainability can be improved.

The rocker arm shaft (26) that supports the rocker arm (27) includes a contact point (G1) between the rocker arm (27) and the valve cam (25), and the rocker arm (27) is the valve lifter. It is good also as a structure located below the line segment (T) which connected the contact (G2) which contact | connects (13E).
In this case, since the rocker arm is separated from the contact point with the valve cam with a smaller swing angle, the valve cam can be easily removed.

Furthermore, it is good also as a structure by which the adjustment screw (27b) is provided in the contact part with the said valve lifter (13E) of the said rocker arm (27).
In this case, by adjusting the adjustment screw, the swing angle of the rocker arm can be increased, so that the valve cam can be easily removed .

  In the variable valve mechanism for an internal combustion engine according to the present invention, since the cam holder of the valve cam is provided obliquely with respect to the deck surface of the cylinder head, the valve cam can be removed to the inclination direction side of the cam holder. For this reason, the valve cam can be removed without removing the rocker arm, and the maintainability can be improved.

Also, when the side of the rocker arm that contacts the valve cam is farthest from the valve cam, the rocker arm abutment side does not interfere with the removal of the valve cam. The cam can be removed, and maintainability can be improved.
Further, since the rocker arm is separated from the contact point with the valve cam with a smaller swing angle, the valve cam can be easily removed.

Furthermore, since the swing angle of the rocker arm can be increased by adjusting the adjustment screw, the valve cam can be easily removed.
Further, since the mating surface of the cam holder is parallel to the top surface of the direct pressing side valve lifter, the cam holder can efficiently receive the force acting on the valve operating cam from the direct pressing side valve lifter.
In addition, since the valve cam can be removed on the side opposite to the rocker arm, the valve cam can be removed without removing the rocker arm, and the maintainability can be improved.

1 is a left side view showing a motorcycle including a variable valve mechanism for an internal combustion engine according to an embodiment of the present invention. It is sectional drawing which shows an internal combustion engine. It is a mimetic diagram showing the composition at the time of seeing an internal combustion engine from the upper part. It is an expanded sectional view of the valve deactivation mechanism on the exhaust side. It is a top view of an internal combustion engine. It is side surface sectional drawing of a valve mechanism. It is a partially broken side view of the vicinity of a cam holder. It is a partially broken side view explaining the maintenance around the camshaft.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a left side view showing a motorcycle provided with a variable valve mechanism for an internal combustion engine according to an embodiment of the present invention. In the following description, descriptions of directions such as front and rear, left and right and up and down are for the vehicle body.
A body frame 111 of the motorcycle 100 includes a head pipe 112 positioned at the front of the vehicle body, a pair of left and right main frames 114 extending rearward from the head pipe 112 to the center of the vehicle body, and extending downward from a rear end portion of the main frame 114. A pair of left and right pivot plates 115 and a rear frame (not shown) extending from the rear end of the main frame 114 to the rear of the vehicle body are provided.
A front fork 116 is rotatably attached to the head pipe 112, and a front wheel 117 is rotatably supported at the lower end of the front fork 116. A steering handle 118 is attached to the upper portion of the head pipe 112.

Below the main frame 114, a front / rear V-type four-cylinder internal combustion engine 1 is arranged. The internal combustion engine 1 is a horizontally-placed engine in which the crankshaft 2 is oriented horizontally in the horizontal direction, is an OHC type four-stroke water-cooled type, and includes a crankcase 3. This is a narrow-angle V-type engine in which the front bank Bf and the rear bank Br that are inclined to V are configured in a V shape, and the bank angle of each other is smaller than 90 degrees.
One end of a pair of left and right exhaust pipes 119 is connected to the exhaust port of the front bank Bf. The exhaust pipe 119 extends downward from the exhaust port and is then routed toward the rear of the vehicle body, so that the rear bank Br The exhaust pipes 120 are connected to a pair of left and right exhaust pipes 120 extending from the exhaust port, and are connected to a muffler (not shown) provided behind the internal combustion engine 1 via a single exhaust pipe 127 (see FIG. 3). Yes.

A pivot shaft 121 is provided behind the internal combustion engine 1, and a rear fork 122 is attached to the pivot shaft 121 so as to be swingable in the vertical direction about the pivot shaft 121. A rear wheel 131 is rotatably supported at the rear end portion of the rear fork 122. The rear wheel 131 and the internal combustion engine 1 are connected by a drive shaft 123 provided in the rear fork 122, and rotational power from the internal combustion engine 1 is transmitted to the rear wheel 131 through the drive shaft 123. A rear cushion 124 that absorbs an impact from the rear fork 122 is suspended between the rear fork 122 and the vehicle body frame 111.
A stand 125 for stopping the vehicle body is provided at the rear part of the internal combustion engine 1. A side stand 126 is provided at the lower part of the left side surface of the internal combustion engine 1.

A fuel tank 141 is mounted on the upper part of the main frame 114 so as to cover the upper part of the internal combustion engine 1. A seat 142 is located behind the fuel tank 141, and the seat 142 is supported by the rear frame. A tail lamp 143 is disposed behind the seat 142, and a rear fender 144 is disposed below the tail lamp 143 so as to cover the rear wheel 131.
The motorcycle 100 also has a resin body cover 150 that covers the vehicle body. The vehicle body cover 150 includes a front cover 151 that continuously covers from the front of the vehicle body frame 111 to the front portion of the internal combustion engine 1, and a seat. And a rear cover 152 that covers the lower portion of 142. A pair of left and right mirrors 153 are attached to the top of the front cover 151. Further, a front fender 146 is attached to the front fork 116 so as to cover the upper part of the front wheel 117.

FIG. 2 is a cross-sectional view showing the internal combustion engine 1. FIG. 3 is a schematic diagram showing a configuration when the internal combustion engine 1 is viewed from above. In FIG. 2, the upper and lower sides of the figure are described as the upper and lower sides of the internal combustion engine 1, the left side of the figure is the front side of the internal combustion engine 1, and the right side of the figure is the rear side of the internal combustion engine 1.
As shown in FIG. 2, a V bank space K, which is a space formed in a V shape in a side view, is formed between the front bank Bf and the rear bank Br.
The crankcase 3 is divided vertically and has an upper crankcase 3U and a lower crankcase 3L. The crankshaft 2 is rotatably supported so as to be sandwiched between the crankcases 3U and 3L. The upper crankcase 3U includes a front cylinder block 3f and a rear cylinder block 3r in which two cylinders are arranged on the left and right, respectively. It extends obliquely upward so as to form a V shape in a side view and is integrally formed.

Below the lower crankcase 3L, an oil pan 3G in which the oil of the internal combustion engine 1 is stored is provided so as to bulge downward. An oil pump 50 that circulates oil in the internal combustion engine 1 is located below the crankshaft 2 in the lower crankcase 3L. The oil pump 50 is driven by a pump drive chain (not shown) spanned between the crankshaft 2 and the oil pump 50, and is always operated when the crankshaft 2 rotates.
In the crankcase 3, a main shaft 41, a counter shaft 42, and an output shaft 43 that are disposed in parallel with the crankshaft 2 are provided. These shafts 41, 42, and 43 including the crankshaft 2 constitute a gear transmission mechanism that transmits the rotation of the crankshaft 2 in the order of the main shaft 41, the counter shaft 42, and the output shaft 43. Between the counter shaft 42 and the main shaft 41, a six-speed transmission gear group is disposed so as to constitute a transmission. A drive shaft 123 (see FIG. 1) is connected to the output shaft 43 via a bevel gear (not shown).

  A front cylinder head 4f is superimposed on the front cylinder block 3f diagonally forward and fastened by fastening bolts (not shown), and a front cylinder head cover 5f covers the front cylinder head 4f. Similarly, a rear cylinder head 4r (cylinder head) is superimposed on the rear cylinder block 3r diagonally rearward and fastened by fastening bolts (not shown), and the rear cylinder head 4r is covered by a rear cylinder head cover (not shown). .

  A pair of cylinder bores 3a is formed in each of the front cylinder block 3f and the rear cylinder block 3r, and a piston 6 that reciprocates in the cylinder bore 3a is accommodated in each cylinder bore 3a. Each piston 6 is connected to one crankshaft 2 common to each piston 6 via connecting rods 7f and 7r.

  As shown in FIG. 3, in the internal combustion engine 1, the cylinders in which the pistons 6 are housed are the first cylinder C1, the second cylinder C2, the third cylinder C3, and the fourth cylinder C4 in order from the left side in the vehicle width direction. Is provided. Specifically, the left cylinder of the front bank Bf is the first cylinder C1, the right cylinder is the fourth cylinder C4, the left cylinder of the rear bank Br is the second cylinder C2, and the right cylinder is the third cylinder C3. It is.

As shown in FIGS. 2 and 3, the front cylinder head 4f and the rear cylinder head 4r are respectively provided with combustion chambers 20 positioned above the four cylinder bores 3a. The front cylinder head 4f is provided with an intake port 21f and an exhaust port 22f that communicate with the combustion chamber 20 of the first cylinder C1, and an intake port 21f and an exhaust port 22f that communicate with the combustion chamber 20 of the fourth cylinder C4. Yes.
The rear cylinder head 4r is provided with an intake port 21r and an exhaust port 22r that communicate with the combustion chamber 20 of the second cylinder C2, and an intake port 21r and an exhaust port 22r that communicate with the combustion chamber 20 of the third cylinder C3. Yes.
A front throttle body 60f for adjusting the amount of intake air flowing through the intake ports 21f, 21f is connected to the intake ports 21f, 21f of the front cylinder head 4f, and an intake air is connected to the intake ports 21r, 21r of the rear cylinder head 4r. A rear throttle body 60r for adjusting the amount of intake air flowing to the ports 21r and 21r is connected.

As shown in FIG. 2, a pair of intake valve openings 81 and a pair of exhaust valve openings 82 are formed in the combustion recess 20A that forms the upper surface of the combustion chamber 20 of each cylinder. The intake valve opening 81 is opened and closed by the intake valve 11, and the exhaust valve opening 82 is opened and closed by the exhaust valve 12 (poppet valve).
The intake valve 11 includes a valve body portion 11b that closes the intake valve opening 81, and a valve stem 11c that extends from the valve body portion 11b as a base end. The exhaust valve 12 includes a valve body portion 12b that closes the exhaust valve opening 82, And a valve stem 12c extending from the valve body 12b as a base end.
The valve stem 11c and the valve stem 12c are slidably fitted to a guide cylinder 83 provided above the intake valve opening 81 and the exhaust valve opening 82.

Retainers 84 are provided at the valve stem ends 11d and 12d at the tips of the valve stem 11c and the valve stem 12c, respectively. The coiled valve spring 11a and the valve spring 12a are provided between each retainer 84 and the intake valve opening 81 and the exhaust valve opening 82, and bias the intake valve 11 and the exhaust valve 12 in the closing direction.
As shown in FIG. 2, the intake valve 11 and the exhaust valve 12 are unicam-type valves that are driven by camshafts 25 (valve cams) arranged one by one for each cylinder head 4f, 4r. The mechanism 10 (variable valve mechanism) is driven to open and close.

The valve operating mechanism 10 includes a camshaft 25 that is rotatably supported by a support portion above the intake valve 11 in each cylinder head 4f, 4r, and an axis parallel to the camshaft 25 to each cylinder head 4f, A rocker shaft 26 (rocker arm shaft) fixed to 4r and a rocker arm 27 pivotally supported by the rocker shaft 26 are provided.
The valve mechanism 10 has an intake valve 11 and is directly driven by a camshaft 25 and is driven by a rocker arm 27 having an intake valve mechanism 10I (the other valve mechanism) and an exhaust valve 12. The exhaust side valve mechanism 10E (one valve mechanism) is provided. The intake side valve mechanism 10I and the exhaust side valve mechanism 10E are driven by one camshaft 25 and operate in conjunction with each other.

  The camshaft 25 has an intake cam 30 and an exhaust cam 31 that protrude to the outer peripheral side of the camshaft 25, and is rotated in synchronization with the rotation of the crankshaft 2. The intake cam 30 and the exhaust cam 31 have a cam profile in which the distance (radius) from the center to the outer periphery is not constant, and the intake valve 11 and the exhaust valve are changed by the change in radius when the intake cam 30 and the exhaust cam 31 rotate. Move 12 up and down.

In the front bank Bf, a front valve lifter 13 is provided between the camshaft 25 and the intake valve 11 so as to be slidably fitted to the front cylinder head 4f below the camshaft 25.
In the rear bank Br, a valve lifter 13I (directly pressed valve lifter) is provided between the camshaft 25 and the intake valve 11 so as to be slidably fitted to the rear cylinder head 4r below the camshaft 25. Yes.

  One end of a rocker arm 27 that is pivotally supported by the rocker shaft 26 is provided with a roller 27a that is in rolling contact with the exhaust cam 31 (on the contact side with the valve cam), and the other end is in contact with the upper end of the exhaust valve 12. A tappet screw 27b (adjustment screw) is screwed so that the advance / retreat position can be adjusted. A valve lifter 13E is provided between the tappet screw 27b on the rear bank Br side and the exhaust valve 12.

  When the intake cam 30 and the exhaust cam 31 are rotated integrally with the camshaft 25, the intake cam 30 pushes down the intake valve 11 via the front valve lifter 13 and the valve lifter 13I, and the exhaust cam 31 contacting the roller 27a The exhaust valve 12 is pushed down via the rocker arm 27, and the intake ports 21f and 22f and the exhaust ports 22r and 22r are opened and closed at a predetermined timing determined by the rotation phases of the intake cam 30 and the exhaust cam 31.

  As shown in FIG. 3, the front throttle body 60f is provided at the rear portion of the front bank Bf, and includes a pair of intake passages 61, 61 communicating with the first cylinder C1 and the fourth cylinder C4 in one case body 62. Has been. A pair of butterfly throttle valves 63, 63 are provided in the intake passages 61, 61 so as to be openable and closable, respectively. The throttle valves 63, 63 are shafts 64 provided in the intake passages 61, 61 (see FIG. 2). Is supported by. The shaft 64 is driven by one motor 65 connected to the shaft 64, and the two throttle valves 63 and 63 are driven simultaneously.

  Further, the rear throttle body 60r is provided in the front portion of the rear bank Br, and includes a pair of intake passages 66a and 66b communicating with the second cylinder C2 and the third cylinder C3 in one case body 68. Yes. A pair of butterfly throttle valves 67 and 67 are provided in the intake passages 66a and 66b so as to be openable and closable, respectively. The throttle valves 67 and 67 are shafts 64 provided in the intake passages 66a and 66b (see FIG. 2). Is supported by. The shaft 64 is driven by one motor 65 connected to the shaft 64, and the two throttle valves 67 and 67 are driven simultaneously.

  The throttle valves 63 and 63 and the throttle valves 67 and 67 are so-called TBWs that open and close by electronic control in conjunction with each motor 65 in accordance with the accelerator opening operated by the driver, that is, the driver's intention to accelerate. This is a (throttle-by-wire) type throttle valve. The driving state of each motor 65 is controlled according to the accelerator opening and the like by an ECU 76 as an electronic control unit of the vehicle.

The intake passages 61 and 61 and the intake passages 66a and 66b are respectively provided with injectors 70 that inject fuel into the intake passages 61 and 61 and the intake passages 66a and 66b. Each injector 70 is disposed downstream of the throttle valves 63 and 63 and the throttle valves 67 and 67. In the center of each combustion chamber 20, a spark plug 71 that ignites the air-fuel mixture supplied to each combustion chamber 20 is provided.
In addition, a cam chain chamber 35 extending vertically is provided at the right ends of the front bank Bf and the rear bank Br. The camshaft 25 is driven by the crankshaft 2 and is connected to the cam chain chamber 35 (not connected). It is driven by rotation.

  In the present embodiment, the rear bank Br is provided with a valve pause mechanism 80 that keeps the intake valve 11 and the exhaust valve 12 closed to pause the cylinder. As shown in FIG. 2, the valve pause mechanism 80 is provided between the valve stem end 11d of the intake valve 11 and the intake cam 30 on the intake side, and the valve stem end 12d of the exhaust valve 12 on the exhaust side. And the tappet screw 27 b of the rocker arm 27.

  The valve pausing mechanism 80 performs the operation / non-operation of the pressing force in the valve opening direction from the intake cam 30 to the intake valve 11 and the operation / non-operation of the pressing force in the valve opening direction from the rocker arm 27 to the exhaust valve 12. In a specific operating range of the internal combustion engine 1, for example, in a low load range such as a low speed operating range, the pressing force is inactive and the intake valve 11 and the exhaust valve 12 are deactivated. That is, the valve pause mechanism 80 is a variable valve operating device that can change the operation of the intake valve 11 and the exhaust valve 12 and can switch whether the intake valve 11 and the exhaust valve 12 are operated.

FIG. 4 is an enlarged cross-sectional view of the valve pause mechanism 80 of the exhaust side valve mechanism 10E.
The valve deactivation mechanism 80 is similarly configured on the intake side and the exhaust side, and here, the valve deactivation mechanism 80 on the exhaust side valve mechanism 10E side will be mainly described. Further, since the valve deactivation mechanism 80 is provided in each of the second cylinder C2 and the third cylinder C3 and has the same configuration, the valve deactivation mechanism 80 of the second cylinder C2 will be described here.

  As shown in FIG. 4, the exhaust-side valve pausing mechanism 80 has a valve lifter 13E, which lifts up and down in the axial direction of the valve stem 12c by the pressing force from the camshaft 25. 85, a slide pin 86 which is provided in the lifter 85 and slides in a direction orthogonal to the axial direction of the valve stem end 12d, a slide pin holder 87 which holds the slide pin 86, and a hydraulic pressure is applied to the slide pin 86. A hydraulic pressure supply mechanism 88, a return spring 89 that biases the slide pin 86 in one direction against the hydraulic pressure applied to the slide pin 86, and a lifter 85 that biases against the pressing force from the lower end of the tappet screw 27b. The lifter spring 90 is provided. The valve lifter 13 </ b> E is a hydraulic actuator that is driven by the hydraulic pressure from the hydraulic pressure supply mechanism 88.

  The valve pause mechanism 80 of the intake side valve mechanism 10I includes a valve lifter 13I provided between the valve stem end 11d of the intake valve 11 and the intake cam 30. The valve lifter 13I is configured substantially the same as the valve lifter 13E.

The lifter 85 is formed in a cylindrical shape having an axial upper end formed in a flat shape, and has a lower surface opened to accommodate a disc-shaped slide pin holder 87 therein. A communication hole 85 a is formed on the outer peripheral surface of the lifter 85 to communicate the inside and outside of the lifter 85.
A receiving member 94 for the tappet screw 27b is interposed between the upper surface of the lifter 85 and the lower end of the tappet screw 27b. The lifter spring 90 is a coil spring, is accommodated in the lifter 85, and is provided in contact with the lower surface of the slide pin holder 87.
The lifter 85 is slidably supported in a cylindrical lifter guide hole 91 provided in the upper part of the rear cylinder head 4r. An oil supply groove 91 a is formed on the inner peripheral surface of the lifter guide hole 91 so as to surround the lifter 85.

  The hydraulic pressure supply mechanism 88 includes an oil pump 50 (see FIG. 2) for sending hydraulic oil, an upstream control oil path 72 (see FIG. 3) connected to the oil pump 50, and a second control oil path 72 through the second control oil path 72. The control oil passages 73 and 74 that branch into the cylinder C2 and the third cylinder C3, the hydraulic pressure switching unit 75 (see FIG. 3) that switches the working oil flowing through the control oil passages 73 and 74, and the end points of the control oil passages 73 and 74 Are provided with oil supply grooves 91a.

  The hydraulic pressure switching unit 75 is a spool valve 75a that switches ON / OFF the hydraulic pressure of the hydraulic oil supplied to the valve deactivation mechanism 80 of the second cylinder C2, and the hydraulic oil that is supplied to the valve deactivation mechanism 80 of the third cylinder C3. Has a spool valve 75b for switching ON / OFF of the hydraulic pressure. The switching of the spool valves 75a and 75b is controlled by the ECU 76 based on the driving situation of the vehicle such as the rotational speed of the internal combustion engine 1.

  As shown in FIG. 4, the slide pin holder 87 includes a cylinder hole 87 a that extends in the radial direction of the disk shape and faces in a direction orthogonal to the valve stem 12 c, and a valve stem at the center of the slide pin holder 87. 12 c and a stem hole 87 b provided coaxially, and is fitted in the lifter 85. An opening 87c is provided at one end of the cylinder hole 87a, and a wall portion 87d is formed at the other end. A stopper pin 92 that restricts the position of the slide pin 86 in the cylinder hole 87a is provided on the opening 87c side of the cylinder hole 87a.

  The slide pin 86 is provided in the cylinder hole 87a so as to be slidable in a direction perpendicular to the valve stem 12c, and has a stem through hole 93 penetrating in a direction perpendicular to the axial direction. Further, the slide pin 86 has a stem contact surface 93 a whose outer peripheral surface is recessed inward, and the stem contact surface 93 a is provided continuously adjacent to the stem through hole 93. In the cylinder hole 87a, a space between one end of the slide pin 86 and the lifter 85 is a hydraulic chamber 95 in which the hydraulic oil acts.

A return spring 89 is provided between the other end of the slide pin 86 and the wall portion 87d of the cylinder hole 87a. As shown in FIG. 4, the return spring 89 moves the slide pin 86 to the hydraulic chamber 95 side. Energized. The position of the slide pin 86 in the axial direction is regulated by fitting the stopper pin 92 in a groove provided on one end side. In a state where the slide pin 86 is pressed against the stopper pin 92 side, the stem through hole 93 is located closer to the hydraulic chamber 95 than the stem hole 87b.
When the hydraulic pressure from the control oil passage 73 acts on the hydraulic chamber 95 and the slide pin 86 slides against the return spring 89 in the direction opposite to the urging direction of the return spring 89, the stem through hole 93 becomes the stem hole 87b. To the stem hole 87b. The diameter of the stem through hole 93 is formed larger than the diameter of the valve stem end 12d.

The valve stem end 12 d of the exhaust valve 12 is inserted in the stem hole 87 b and is provided in a state of being engaged with the stem contact surface 93 a of the slide pin 86. In the valve pause mechanism 80, the slide pin 86 is slid to change the engagement state between the valve lifters 13I and 13E and the intake and exhaust valves 11 and 12.
That is, the valve pausing mechanism 80 is configured to move the slide pin 86 under the control of hydraulic pressure so that the stem contact surface 93a and the stem through hole 93 selectively face the valve stem end 12d.

  In the valve stop mechanism 80, the spool valve 75a is controlled to be in the OFF state, the hydraulic pressure acting on the slide pin 86 is low, and the valve stem end 12d is not moved to the other end side against the return spring 89. Comes into contact with the stem contact surface 93 a and the exhaust valve 12 is connected to the lifter 85. For this reason, when the rocker arm 27 is swung through the exhaust cam 31 by the rotation of the camshaft 25 and the lifter 85 is pressed and lowered by the tappet screw 27b, the exhaust valve 12 passes through the stem contact surface 93a of the slide pin 86. The exhaust valve 12 is opened by the pressing force, and the exhaust valve 12 opens and closes as the lifter 85 reciprocates.

  Further, when the valve pause mechanism 80 is operated and the spool valve 75a is controlled to be in the ON state and hydraulic oil is supplied to the hydraulic chamber 95, the slide pin 86 is moved to the other end side against the return spring 89. The stem through hole 93 of the slide pin 86 communicates with the stem hole 87b, and the valve stem end 12d of the exhaust valve 12 can be fitted into the stem through hole 93. In this state, when the lifter 85 is pressed and reciprocated through the rocker arm 27 by the rotation of the camshaft 25, the lifter 85 reciprocates up and down independently with the valve stem end 12d of the exhaust valve 12 inserted. The pressing force of the rocker arm 27 is not transmitted to the exhaust valve 12. That is, the exhaust valve 12 is in a resting state in which the pressing force of the rocker arm 27 does not act even when the camshaft 25 rotates, and the valve closing state is maintained.

  The valve deactivation mechanism 80 is provided in all the intake valves 11 and exhaust valves 12 in the second cylinder C2, and when the second cylinder C2 is deactivated, all the intake valves 11 and exhaust valves in the second cylinder C2 are provided. 12 is put into a dormant state. Also, in the third cylinder C3, as in the second cylinder C2, all the intake valves 11 and the exhaust valves 12 are provided with valve deactivation mechanisms 80. When the third cylinder C3 is deactivated, the third cylinder C3 All the intake valves 11 and exhaust valves 12 in C3 are put into a resting state. That is, the rear bank Br composed of the second cylinder C2 and the third cylinder C3 is a deactivated cylinder that can be deactivated. Further, the internal combustion engine 1 is operated with four cylinders for operating all four cylinders, with two cylinders for stopping the second cylinder C2 and the third cylinder C3, and with either one of the second cylinder C2 or the third cylinder C3 being stopped. The three-cylinder operation can be performed.

The ECU 76 controls the cylinder deactivation of the rear bank Br by switching the spool valves 75a and 75b of the valve deactivation mechanism 80 in accordance with the driving situation of the vehicle. When deactivating the cylinder, the ECU 76 of the cylinder 70 to be deactivated is controlled. Stop fuel supply. For this reason, the fuel consumption of the internal combustion engine 1 can be improved.
On the other hand, the first cylinder C1 and the fourth cylinder C4 do not have the valve deactivation mechanism 80, and the front bank Bf is a normally operating cylinder in which the intake valve 11 and the exhaust valve 12 are always opened and closed when the internal combustion engine 1 is operated. It is.

FIG. 5 is a plan view of the internal combustion engine 1. FIG. 6 is a side sectional view of the valve mechanism 10. Here, FIG. 5 shows a state in which the rear cylinder head cover is removed from the second cylinder C2 of the rear cylinder head 4r. Further, as shown in FIG. 2, the rear cylinder head 4r is mounted in a rearward tilted state, but in FIG. 6, the rear cylinder head 4r is illustrated with a deck surface 19 described later in a horizontal state.
As shown in FIG. 5, the camshaft 25 formed in a hollow shape is disposed above the lifter guide hole 91 so as to extend in the vehicle width direction in parallel with the crankshaft 2 (see FIG. 2), and the rear cylinder head 4r. Is rotatably supported by a plurality of cam holders 51 provided on the top of the head. The cam holder 51 is disposed in front of the spark plug 71 disposed in the center of the substantially circular combustion chamber 20 (see FIG. 3), and is located in the center of the combustion chamber 20 in the vehicle width direction. The spark plug 71 is supported by the cylindrical plug hole 29. FIG. 6 shows the plug hole 29 of the third cylinder C3.

The pair of intake cams 30 is provided on both sides of the cam holder 51 with the cam holder 51 interposed therebetween, and the pair of exhaust cams 31 is provided on the outer side in the vehicle width direction than the intake cams 30.
The lifter guide holes 91 that support the pair of valve lifters 13I are respectively positioned below the intake cams 30, and the cam holder 51 is provided between the pair of lifter guide holes 91 in the upper part of the rear cylinder head 4r. .
The pair of rocker arms 27 is disposed so as to extend rearward to the exhaust valve lifters 13E continuously from the exhaust cams 31, and the pair of tappet screws 27b bend inward toward the rear end side. 27 is provided at the rear end.
In the third cylinder C3 (see FIG. 3) of the rear cylinder head 4r, the valve mechanism 10 is configured substantially the same as the third cylinder C3, and the camshaft 25 is configured as the cam holder 51. (Not shown).

  A deck surface 19 is formed on the upper surface of the side wall 18 of the rear cylinder head 4r so as to be combined with the lower surface of the rear cylinder head cover (not shown). The deck surface 19 is formed in a planar shape perpendicular to the axis of the cylinder bore 3a (see FIG. 2). A frame-shaped gasket (not shown) is interposed between the deck surface 19 and the lower surface of the rear cylinder head cover.

  As shown in FIG. 6, the rocker arm 27 is disposed at an inner position of a valve clamping angle A defined by an angle at which the valve axes V1 and V2 of the intake valve 11 and the exhaust valve 12 intersect with each other, and is located above the rear cylinder head 4r. It is pivotally supported by a rocker shaft 26 inserted through a shaft support portion 36 formed in a swingable manner in the front-rear direction.

The rocker arm 27 is formed in an arm shape extending in the front-rear direction, and a shaft through hole 27c that is pivotally supported by the rocker shaft 26 is located on the side of the combustion chamber 20 at an intermediate portion of the rocker arm 27 between the roller 27a and the tappet screw 27b. It is formed in a portion that bulges downward.
The rocker arm 27 has a screw support hole 28 penetrating vertically at an end on the exhaust side, and the tappet screw 27b is screw-supported by a nut 28a that is inserted into the screw support hole 28 and tightened to the upper part. It is fixed to the hole 28. The vertical position of the tappet screw 27b can be adjusted by tightening the nut 28a and the tappet screw 27b.

The exhaust-side valve lifter 13E urged by the lifter spring 90 always presses the tappet screw 27b upward, and the rocker arm 27 receiving this force is on the camshaft 25 side with the rocker shaft 26 as an axis. It is pressed against. For this reason, the roller 27 a is constantly pressed against the exhaust cam 31. Specifically, when the exhaust valve 12 is closed, the roller 27a is in contact with the base circle 31a of the exhaust cam 31 (the base circle of the valve cam), and protrudes from the base circle 31a when the exhaust valve 12 is opened. It contacts the cam crest 31b. In the present embodiment, the contact point G1 between the roller 27a and the base circle 31a is located on the surface on the rocker arm 27 side of the exhaust cam 31 above the center of the base circle 31a.
Further, the valve lifter 13I on the intake side is always pressed against the intake cam 30 by the lifter spring 90. Specifically, when the intake valve 11 is closed, the valve lifter 13I is in contact with the base circle 30a of the intake cam 30, and when the intake valve 11 is opened, it is in contact with the cam crest 30b protruding from the base circle 30a.

FIG. 7 is a partially broken side view in the vicinity of the cam holder 51. In FIG. 7, the intake cam 30, the exhaust cam 31, and the rocker arm 27 are not shown.
As shown in FIGS. 6 and 7, the cam holder 51 includes a head side holder 52 formed integrally with the upper portion of the rear cylinder head 4r, and a cap 53 connected to the head side holder 52 from above. Has been. The head-side holder 52 and the cap 53 have camshaft support portions 52a and 53a that are semicircular in a front view and a front-rear intermediate portion, respectively. Thus, a circular shaft support hole 54 is formed. The camshaft 25 is supported by a shaft portion 25 a formed between a pair of intake cams 30 (see FIG. 5) being fitted into the shaft support hole 54.
Specifically, the cam holder 51 forms a mating surface 55 by bringing the upper surface of the head-side holder 52 and the lower surface of the cap 53 into contact with each other, and in this state, a pair of cap fixings provided across both sides of the shaft support hole 54. The cap 53 is fastened to the head side holder 52 by the bolt 56 and assembled.

The mating surface 55 is a plane that bisects the shaft support hole 54 vertically through the center O1 of the shaft support hole 54, and is a rocker arm with the center O1 as the rotation center with respect to the deck surface 19 of the rear cylinder head 4r. 27 is formed obliquely so as to incline forward toward the front side of the vehicle opposite to 27. The center O1 is provided to coincide with the height of the deck surface 19.
The mating surface 55 is a plane orthogonal to the valve axis V1 of the intake valve 11 and a plane parallel to the top surface 32 of the valve lifter 13I. Further, the mating surface 55 is a flat surface, and the upper surface of the head side holder 52 and the lower surface of the cap 53 are also flush, so that the head side holder 52 and the cap 53 can be easily processed.
The mating surface 55 on the rocker arm 27 side protrudes above the deck surface 19. The mating surface 55 on the front side wall 18 side is located below the deck surface 19 and the center O1. In a state in which the cap 53 is not attached, a space M positioned below the center O1 is formed above the mating surface 55 on the side wall 18 side.

  A seating surface 53 b that receives the head of the cap fixing bolt 56 on the upper surface of the cap 53 is formed in parallel with the mating surface 55, and the cap fixing bolt 56 is an internal thread of the head side holder 52 formed perpendicular to the mating surface 55. It is fastened to the part 52b. Further, a knock pin 57 is provided on the mating surface 55 so as to straddle the bolt hole 53 c and the female screw portion 52 b of the cap 53, and the cap 53 is positioned by the knock pin 57.

In the present embodiment, since the mating surface 55 is provided in parallel to the top surface 32 of the valve lifter 13I, when the valve lifter 13I is directly pushed by the intake cam 30 to drive the intake valve 11, the valve lifter 13I is moved to the camshaft 25. The acting reaction force F can be received by the mating surface 55 perpendicular to the reaction force F. Therefore, the reaction force F when driving the intake valve 11 can be efficiently received by the cam holder 51, and the camshaft 25 can be supported more stably.
Further, since the cap fixing bolt 56 is provided perpendicular to the mating surface 55 and the reaction force F can be received in parallel with the axial direction of the cap fixing bolt 56, the cam holder 51 makes the cam shaft 25 more stable. Can be supported.

Next, maintenance around the camshaft 25 will be described.
FIG. 8 is a partially broken side view for explaining the maintenance around the camshaft 25.
When removing the camshaft 25 from the rear cylinder head 4r, as shown in FIG. 8, the nut 28a is loosened to move the tappet screw 27b upward, and the lower surface of the screw support hole 28 is placed on the receiving member on the upper surface of the valve lifter 13E. 94, the cap fixing bolt 56 is removed, and the cap 53 is removed from the head side holder 52. In this state, the roller 27a that is in contact with the exhaust cam 31 of the rocker arm 27 is separated from the exhaust cam 31, and the roller 27a is in the most separated position.

  Specifically, at the position where the roller 27a is farthest away, the tip of the exhaust cam 31 of the roller 27a is in relation to the tangential extension S on the roller 27a side of the tangent of the base circle 31a of the exhaust cam 31 perpendicular to the mating surface 55. , Located in a region opposite to the exhaust cam 31. That is, the mating surface 55 is opposite to the rocker arm 27 so that the tip of the roller 27a is located in a region opposite to the exhaust cam 31 with respect to the extension line S in a state where the roller 27a is separated from the exhaust cam 31. Inclined downward toward the side.

In the present embodiment, as shown in FIG. 8, the contact point G1 between the exhaust cam 31 and the roller 27a is located in the region on the exhaust cam 31 side with respect to the extension line S, but the rocker arm 27 is connected to the valve lifter 13E side. The tip of the roller 27a can be positioned on the side opposite to the exhaust cam 31 with respect to the extension line S. For this reason, when removing the camshaft 25 along the extension line S to the front upper side opposite to the rocker arm 27, the roller 27a does not interfere with the removal of the camshaft 25. Thereby, since the camshaft 25 can be easily removed without removing the rocker arm 27 and the rocker shaft 26, the maintainability can be improved.
Similarly, when the camshaft 25 is attached to the head side holder 52, since the roller 27a does not get in the way, the camshaft 25 can be easily attached in a state where the rocker arm 27 is assembled, so that maintainability can be improved. .

Further, a space M positioned below the center O1 of the shaft support hole 54 is formed above the mating surface 55 on the front side wall 18 side, and the camshaft 25 is moved to the front upper side opposite to the rocker arm 27. When removing, since the camshaft 25 can pass through the space M, the camshaft 25 can be removed forward and upward. For this reason, the camshaft 25 can be easily removed without removing the rocker arm 27.
Similarly, when the camshaft 25 is attached to the head side holder 52, the camshaft 25 can pass through the space M, and the camshaft 25 can be easily attached with the rocker arm 27 assembled. Can be improved.

As shown in FIG. 6, the center O2 of the rocker shaft 26 has a line segment T connecting a contact point G1 between the roller 27a and the exhaust cam 31 and a contact point G2 where the tappet screw 27b contacts the receiving member 94 of the valve lifter 13E. Is located below. Accordingly, the rocker arm 27 can be separated from the contact point G1 with a smaller swing angle than the configuration in which the rocker shaft 26 is positioned above, so that the camshaft 25 can be easily removed without removing the rocker arm 27. Can be removed.
Further, since the mating surface 55 of the cam holder 51 is parallel to the top surface 32 of the valve lifter 13I on the intake side, the camshaft 25 is moved in the sliding direction of the valve lifter 13I by the pressing force of the valve lifter 13I biased by the lifter spring 90. At this time, since the roller 27a does not get in the way, the camshaft 25 can be easily removed.

  As described above, according to the embodiment to which the present invention is applied, in the valve mechanism 10 in which the valve lifter 13E is always brought into contact with the rocker arm 27 interlocked with the camshaft 25 by the lifter spring 90, the cam Since the cam holder 51 of the shaft 25 is provided obliquely forward and downward on the opposite side of the rocker arm 27 with respect to the deck surface 19 of the rear cylinder head 4r, the camshaft 25 is provided on the outer side of the cam holder 51 in the inclined direction, that is, the front side. Can be removed. For this reason, the camshaft 25 can be removed without removing the rocker arm 27, and the maintainability can be improved.

  In addition, the inclination of the mating surface 55 of the cam holder 51 is orthogonal to the mating surface 55 when the roller 27 a that is in contact with the camshaft 25 of the rocker arm 27 is farthest from the exhaust cam 31 of the camshaft 25. The camshaft 25 is inclined to the extension line S with respect to the extension line S of the tangent line of the base circle 30a of the intake cam 30 so that the tip of the roller 27a is located on the opposite side of the camshaft 25 from the intake cam 30. The tip of the roller 27a of the rocker arm 27 does not get in the way when being removed to the outside on the front side. For this reason, the camshaft 25 can be removed without removing the rocker arm 27, and the maintainability can be improved.

Further, the rocker shaft 26 is positioned below a line T connecting the contact point G1 between the rocker arm 27 and the camshaft 25 and the contact point G2 where the rocker arm 27 is in contact with the valve lifter 13E, and the rocker arm 27 is on the valve lifter 13E side. , The contact point G1 is separated with a smaller swing angle. Thereby, since the roller 27a can be largely separated from the contact point G1, the camshaft 25 can be easily removed.
Furthermore, by adjusting the position of the tappet screw 27b with the nut 28a, the swing angle of the rocker arm 27 can be further increased, and the rocker arm 27 can be greatly separated from the contact point G1, so that the camshaft 25 is It can be easily removed.

Further, since the mating surface 55 of the cam holder 51 is parallel to the top surface 32 of the valve lifter 13I on the intake side that is directly pressed, the reaction force F acting on the camshaft 25 from the valve lifter 13I can be efficiently received by the cam holder 51. .
Further, the mating surface 55 where the head side holder 52 and the cap 53 meet is inclined downward with respect to the deck surface 19 on the opposite side to the rocker arm 27, and the camshaft 25 faces the opposite side to the rocker arm 27. Therefore, the camshaft 25 can be removed without removing the rocker arm 27, and the maintainability can be improved.

In addition, the said embodiment shows the one aspect | mode which applied this invention, Comprising: This invention is not limited to the said embodiment.
In the above-described embodiment, the mating surface 55 has been described as a plane orthogonal to the valve axis V1 of the intake valve 11 and a plane parallel to the top surface 32 of the valve lifter 13I. However, the inclination angle of the mating surface 55 may be at least an angle at which the space M positioned below the center O1 of the shaft support hole 54 is formed.
Of course, the detailed configuration of the motorcycle 100 can be arbitrarily changed.

1 Internal combustion engine 4r Rear cylinder head (cylinder head)
10 Valve mechanism (variable valve mechanism)
10E Exhaust valve mechanism (one valve mechanism)
10I Intake side valve mechanism (the other valve mechanism)
12 Exhaust valve (poppet valve)
12c Valve Stem 13E Valve Lifter 13I Valve Lifter (Direct Push Side Valve Lifter)
19 Deck surface 25 Camshaft (valve cam)
26 Rocker shaft (Rocker arm shaft)
27 Rocker arm 27a Roller (contact side with valve cam)
27b Tappet screw (adjustment screw)
31a Base circle (base circle of valve cam)
32 Top surface 51 Cam holder 52 Head side holder 53 Cap 55 Matching surface 86 Slide pin 90 Lifter spring 91 Lifter guide hole 100 Motorcycle G1 contact point (contact point between rocker arm and valve cam)
G2 contact (contact where the rocker arm contacts the valve lifter)
S extension line T segment

Claims (4)

A valve lifter (13E) driven by a rocker arm (27) interlocked with the valve cam (25) and interposed between the valve stems (12c) of the poppet valve (12) is slidable in the lifter guide hole (91). It is supported and urged by the lifter spring (90) so as to always contact the rocker arm (27), and the slide pin (86) is moved under the control of hydraulic pressure in the valve lifter (13E) to change the valve operation. In the variable valve mechanism of the internal combustion engine,
The cam holder (51) of the valve cam (25) is provided obliquely with respect to the deck surface (19) of the cylinder head (4r) ,
The other valve mechanism (10I) interlocked with one valve mechanism (10E) driven by the rocker arm (27) has a structure in which a valve lifter is directly pressed by the valve cam (25), and the cam holder ( 51) is provided in parallel to the top surface (32) of the direct-pressing side valve lifter (13I),
The cam holder (51) is connected between the head side holder (52) formed on the cylinder head (4r) side and the head side holder (52) and the valve valve between the head side holder (52). It has a cap (53) that supports the cam (25) and a shaft support hole (54) into which the valve cam (25) is fitted, and the mating surface (55) is formed by the head side holder (52). And the cap (53) are joined together, and the mating surface (55) is inclined downwardly with respect to the deck surface (19) on the side opposite to the rocker arm (27), and is inclined and lowered. A space (M) positioned below the center (O1) of the shaft support hole (54) is provided between the head side holder (52) and the deck surface (19) on the formed side,
The variable valve mechanism for an internal combustion engine, wherein the center (O1) of the shaft support hole (54) is provided to coincide with the height of the deck surface (19) .   The inclination of the mating surface (55) of the cam holder (51) is such that the abutting side (27a) of the rocker arm (27) with the valve cam (25) is farthest from the valve cam (25). The valve cam (25) with respect to the tangential extension (S) of the base circle (31a) of the valve cam (25) perpendicular to the mating surface (55) of the cam holder (51). The variable valve mechanism for an internal combustion engine according to claim 1, wherein the valve is tilted so that the abutting side (27a) of the rocker arm (27) is positioned on the opposite side.   The rocker arm shaft (26) that supports the rocker arm (27) includes a contact point (G1) between the rocker arm (27) and the valve cam (25), and the rocker arm (27) is connected to the valve lifter (13E). 3. The variable valve mechanism for an internal combustion engine according to claim 2, wherein the variable valve mechanism is located below a line segment (T) connecting a contact point (G2) in contact with the internal combustion engine.   The variable valve mechanism for an internal combustion engine according to claim 2 or 3, wherein an adjustment screw (27b) is provided at a contact portion between the rocker arm (27) and the valve lifter (13E).

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