JP2005180401A - Valve lift variable device of internal combustion engine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a valve lift variable device capable of attaining miniaturization, by compatibly establishing assemblability and torsional rigidity. <P>SOLUTION: This valve lift variable device of an internal combustion engine has a rocker arm 4 having a tappet screw 17 and a roller follower 5, an upper link member 7 having one end pivoted on an upper part of the rocker arm and having the other end pivoted on an engine body, a lower link member 9 having one end pivoted on a crank pin part 12 of a crank member 11 supported by the engine body and having the other end pivoted on a lower part of the rocker arm, and a control arm 18 for applying torque of a predetermined angle range to a crankshaft part 14 supported by the engine body of the crank member; and changes a lift quantity of the rocker arm in response to rotation of a cam, by moving one end of a second link member pivoted at the crank pin part by rotating the crank member. The device mutually integrally joins a pair of mutual crank web parts of the crank member in a position non-interfering with the lower link member. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a variable valve lift device for an internal combustion engine, and more particularly to a variable valve lift device configured to continuously and continuously change the lift amount of an intake valve or an exhaust valve provided in a combustion chamber. Is.

  In the specification of Japanese Patent Application No. 2002-196872, the present applicant has already proposed a device for continuously and continuously changing the lift amount of an intake valve provided in a combustion chamber of an internal combustion engine. In this variable valve lift device, a rocker arm that transmits a cam lift to an intake valve is connected to an engine body using a four-bar linkage mechanism, and a connecting point of a first link member is driven by a cam to give a rocking motion to the rocker arm. By changing the position of the fulcrum on the engine body side of the second link member, it is possible to change the lift amount continuously and continuously without changing the valve timing. A crank mechanism is used to move the fulcrum on the engine body side of the second link member.

  According to the structure described in the above specification, the engine body side end of the second link member is pivotally supported by a crank pin portion connecting a pair of crank web portions sandwiching the second link member from both sides in the axial direction. In consideration of the assembly of the second link member to the crank member, at least one crank web portion and the crank pin portion are separate members, and after the second link member is pivotally attached to the crank pin portion, one crank web portion is It must be connected to the free end of the crankpin.

  However, in the variable valve lift device having the above configuration, a torsional force acts on the crankpin portion due to the driving torque applied to the crank web portion, so that a sufficient torsional rigidity is required at the connecting portion between the crankpin portion and the crank web portion. is there. In order to increase the torsional rigidity of the crank member, it is conceivable that the crank pin portion and the crank web portion are integrally formed by forging or the like. However, when the second link member is attached to the crank pin portion integral with the crank web portion, In addition, the crank pin insertion hole of the second link member must be divided into two parts like the large end portion of the connecting rod, and the second link member must be enlarged. That is, it is extremely difficult to secure the torsional rigidity of the connecting portion between the crankpin portion and the crank web portion without securing the assembling property of the second link member and without increasing the size of the valve operating mechanism.

  In order to solve such problems, to achieve both high assemblability and torsional rigidity, and to achieve downsizing, claim 1 of the present invention provides a valve contact portion (tapet screw 17) with which a valve stem end contacts. And a rocker arm (4) having a cam abutting portion (roller follower 5) with which the cam (2) abuts, and a first link having one end pivotally attached to the first fulcrum of the rocker arm and the other end pivotally attached to the engine body. A second link having one end pivotally attached to the member (upper link member 7) and the crankpin portion (12) of the crank member (11) supported by the engine body and the other end pivotally attached to the second fulcrum of the rocker arm A member (lower link member 9) and a drive device (control arm 18) that applies a rotational force within a predetermined angle range to a support shaft (crankshaft portion 14) of the crank member with respect to the engine body, and rotates the crank member. In the variable valve lift device for an internal combustion engine in which the lift amount of the valve contact portion of the rocker arm is changed with the rotation of the cam by moving one end of the second link member pivotally attached to the crank pin portion. Has a pair of crank web portions (13) sandwiching the second link member from both sides in the axial direction, and the crank web portions are integrally coupled to each other at a position not interfering with the second link member. Was characterized.

  According to a second aspect of the present invention, in addition to the above-described configuration, a stopper pin (23) parallel to the support shaft is provided on the crank web portion so as to define a rotation range of the crank member. It was.

  According to such a configuration of claim 1 of the present invention, since the pair of crank web portions sandwiching the second link member from both sides in the axial direction are integrated, even if the torque required for rotation of the crank member is large, The torsional strength burden on the pin portion can be reduced. In addition, the crank pin portion can be separated from the crank web portion, and the crank pin insertion holes of the crank web portion and the second link member can be aligned with each other so that the crank pin portion can be inserted from the axial direction by press fitting or the like. Assembling becomes easy. In addition, since the pair of crank web portions may be connected at a position where they do not interfere with the second link member, the crank member and the second link member need not be enlarged. Further, by providing a stopper pin for defining the rotation range of the crank member in the crank web portion in parallel with the support shaft, the rotation range defining means for the crank member can be made compact.

  Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

  1 and 2 show a basic configuration of a variable valve lift device for an internal combustion engine to which the present invention is applied. The variable valve lift device 1 includes a rocker arm 4 that transmits the lift of the intake cam 2 to the intake valve 3, and an upper portion of the rocker arm 4 having a roller follower 5 (cam contact portion) and an upper pin 6 coupled to the bifurcated portion. A link member 7 (first link member) and a lower link member 9 (second link member) having one end connected to the lower portion of the rocker arm 4 with a lower pin 8 are provided.

  The other end of the upper link member 7 is pivotally attached to a rocker arm support shaft 10 fixed on a cylinder head (not shown), and the other end of the lower link member 9 is pivotally attached to a crankpin portion 12 of the crank member 11. ing.

  Both ends of the crankshaft portion 14 (support shaft) connected to the crankpin portion 12 of the crank member 11 via the crank web portions 13a and 13b are formed as members that are substantially integrated with a cylinder head such as a head cover HC, for example. The support hole 15 is pivotally attached. The intermediate portion of the crankshaft portion 14 connects the pair of crank web portions 13a and 13b sandwiching the connecting portion between the lower link member 9 and the lower portion of the rocker arm 4 in the variable valve lift device 1 on each cylinder in series. And extending in the cylinder row direction. In FIG. 2, in order to clearly show the connecting portion between the lower portion of the rocker arm 4 and the lower link member 9, the crank pin portion 12 is divided and one crank web portion 13 a is biased to the right.

  The intake cam 2 is integrally formed with a cam shaft 16 that rotates in synchronization with the crankshaft of the internal combustion engine, and two tappet screws 17 provided at the free ends of the rocker arm 4 abut against the stem ends of the two intake valves 3, With respect to the point that the intake cam 2 presses the roller follower 5 pivotally attached to the rocker arm 4 by the rotation of 16 and thereby the two intake valves 3 are driven to open at the same time, this is different from the known valve operating mechanism of the internal combustion engine. There is no place. The intake valve 3 is normally urged to be closed by a valve spring, but a description of these structures is omitted.

  The upper end of the control arm 18 (drive device) is fixed to the end of the crankshaft portion 14 protruding from the support hole 15. As shown in FIG. 3, the lower end of the control arm 18 has a nut member 21 screwed to a screw shaft 20 driven by an electric motor (not shown) attached to the end surface of the cylinder head in the crankshaft direction, for example. The other end of the connecting link 22 having one end pin-coupled is pin-coupled.

  The crankshaft portion 14 of the crank member 11 is in a state where the base circle portion of the intake cam 2 is in sliding contact with the roller follower 5 and the rocker arm 4 is in the raised position (the state shown in FIG. 1), that is, the intake valve 3 is closed. In some cases, it is located coaxially with the lower pin 8 pivotally attached to the lower part of the rocker arm 4.

  Next, the operating procedure of this apparatus will be described.

  When the electric motor is driven from the state of FIG. 1, the nut member 21 moves linearly by the rotation of the screw shaft 20, and the control arm 18 connected to the nut member 21 via the connecting link 22 swings. As a result, the crank member 11 swings about the crankshaft portion 14, and the crankpin portion 12 moves on the arc A centering on the crankshaft portion 14, so that the crankpin portion 12 is displaced in the vertical direction. Is given.

  When the motor is driven to retract the nut member 21 from the forward position shown in FIG. 3 and the control arm 18 is swung counterclockwise in FIG. 3, the crank member 11 connected to the control arm 18 is counterclockwise. And the crank pin portion 12 of the crank member 11 is displaced upward as shown in FIG. Thereby, the shape of the four-bar link connecting the rocker arm support shaft 10, the upper pin 6, the lower pin 8, and the crank pin portion 12 becomes a substantially triangular shape having a vertex on the rocker arm support shaft 10 side. When the intake cam 2 presses the roller follower 5 in this state, the four-bar link is deformed, and the rocker arm 4 swings greatly from the position indicated by the imaginary line to the position indicated by the solid line, and the tappet screw 17 is moved to the stem of the intake valve 3. The end is pressed and opened with a high valve lift HL.

  When the motor is driven to return the nut member 21 to the forward position shown in FIG. 3, the crank member 11 connected to the control arm 18 rotates in the clockwise direction, and as shown in FIG. The crankpin portion 12 is displaced downward. As a result, the shape of the four-bar link connecting the rocker arm support shaft 10, the upper pin 6, the lower pin 8, and the crankpin portion 12 becomes a substantially triangular shape having a vertex on the tappet screw 17 side. When the intake cam 2 presses the roller follower 5 in this state, the four-bar link is deformed and the rocker arm 4 is slightly swung from the position indicated by the imaginary line to the position indicated by the solid line, and the tappet screw 17 is connected to the intake valve 3. The stem end is pressed and opened with a low valve lift LL.

  In this way, according to the variable valve lift device 1 according to the present invention, the position of the other end (crank pin portion 12) of the lower link member 9 is moved continuously and continuously as shown in FIG. Between the lift amount at the time of high lift (corresponding to FIG. 4-a) and the lift amount at the time of low lift (corresponding to FIG. 4-b), the valve timing remains constant and only the lift amount is steplessly Can be changed continuously.

  The position variable control of the rotation center of the lower link member 9 used in the variable valve lift device 1 having the above-described configuration is performed by the turning motion of the crank web portion 13 around the crankshaft portion 14. Therefore, twisting or bending deformation of the crank web portion 13 is not preferable because it reduces the accuracy and stability of the variable valve lift control. Therefore, in the present invention, as shown in FIG. 6, the lower edge of the pair of crank web portions 13 sandwiching the connecting portion between the lower portion of the rocker arm 4 and the lower link member 9 from both sides in the axial direction is connected to the lower portion of the rocker arm 4 and the lower link. In order not to interfere with the movement of the connecting portion with the member 9, the cross-sectional shape is assumed to be interconnected by a bridge portion 22 having a U-shape.

  According to this, since it is possible to prevent the torsional torque from acting almost on the crankpin portion 12 provided on the free end side of the crank web portion 13, the crankpin portion 12 is separated from the crank web portion 13, The lower link member 9 can be easily assembled to the crank member 11 by aligning the crank pin insertion holes of the crank web portion 13 and the lower link member 9 with each other and press-fitting the crank pin portion 12 from the axial direction. Further, since a form in which the pair of crank web portions 13 are connected to each other can be formed by simple bending, the connecting portion between the lower portion of the rocker arm 4 and the lower link member 9 without increasing the number of manufacturing steps. Therefore, it is sufficient to provide a relief that does not interfere with the movement of the valve, so that the entire valve mechanism is not increased in size.

  On the other hand, the lift amount of the tappet screw portion 17 in the rocker arm 4 is controlled by the rotation angle of the crank member 11, that is, the angle of the arc A in FIG. In consideration of protection of the drive system, adjustment during assembly, and convenience of positioning, it is preferable that the rotation range of the crank member 11 is mechanically defined.

  Based on this viewpoint, in the present invention, in order to define the rotation range of the crank member 11, the side surface of the bridge portion 22 continuous with the side surface of the crank web portion 13 is parallel to the axis of the crank shaft portion 14. The stopper pin 23 is fixed by press fitting. For example, an arc-shaped long hole 24 concentric with the support hole 15 is formed on the inner wall surface of the head cover HC, and the tip of the stopper pin 23 is inserted into the long hole 24.

  Thus, by providing the stopper pin 23 in parallel with the crankshaft portion 14 and defining the movement range by the arc-shaped long hole 24, the shape of the crank body 11 can be reduced without complicating the shape of the engine body side. A rotation range defining means can be provided.

It is a side view which cuts and shows a part of valve lift variable device. It is a perspective view which cuts and shows a part of valve lift variable device. It is a principal part perspective view of a drive device. It is operation | movement explanatory drawing of a valve lift variable apparatus. It is a characteristic line figure of a valve lift. It is a perspective view of a crank member. It is a front view of a crankshaft support hole.

Explanation of symbols

2 Cam 4 Rocker arm 5 Roller follower (cam contact part)
7 Upper link member (first link member)
9 Lower link member (second link member)
11 Crank member 12 Crank pin portion 13 Crank web portion 14 Crank shaft portion (support shaft)
17 Tappet screw (valve contact part)
18 Control arm (drive device)
23 Stopper pin 24 Arc-shaped slot

Claims (2)

A rocker arm having a valve abutting portion with which a valve stem end abuts and a cam abutting portion with which a cam abuts; a first link member having one end pivotally attached to the first fulcrum of the rocker arm and the other end pivotally attached to the engine body; A second link member having one end pivotally attached to the crankpin portion of the crank member supported by the engine body and the other end pivotally attached to the second fulcrum of the rocker arm, and a predetermined angle with respect to a support shaft of the crank member with respect to the engine body A driving device that applies a rotational force within a range, and by rotating one end of the second link member pivotally attached to the crank pin portion by rotating the crank member, the valve abutting portion of the rocker arm accompanying the rotation of the cam A variable valve lift device for an internal combustion engine that changes a lift amount,
The crank member has a pair of crank web portions sandwiching the second link member from both sides in the axial direction, and the crank web portions are integrally coupled to each other at a position not interfering with the second link member. A variable valve lift device for an internal combustion engine.   2. The variable valve lift device for an internal combustion engine according to claim 1, wherein a stopper pin parallel to the support shaft is protruded from the crank web portion so as to define a rotation range of the crank member.

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