JP5239605B2 - Variable valve gear and internal combustion engine - Google Patents

Description

  The present invention relates to a variable valve operating apparatus and an internal combustion engine.

As a conventional variable valve device for an engine valve, there is an apparatus that can continuously increase / decrease the operating angle or lift amount of an intake valve and continuously delay / advance the lift center angle (for example, , See Patent Document 1).
JP 2002-256905 A

  However, the conventional variable valve device described above has a configuration in which the opening timing of the intake valve is always advanced as the operating angle or lift amount of the intake valve is increased. Therefore, when the operating angle or lift amount of the intake valve is increased, the intake valve and the piston are likely to interfere with each other near the top dead center. In order to avoid interference between the valve and the piston, it is necessary to take measures such as providing a valve recess in the piston.

  The present invention has been made paying attention to such conventional problems, and an object of the present invention is to prevent the valve and the piston from easily interfering with each other.

The present invention solves the above problems by the following means .

Variable BenSo location according to the present invention, a drive shaft which rotates in synchronism with the crankshaft bets for an internal combustion agencies, and driving cams provided on the drive shaft, the rocking supported swingably to the drive shaft and whether arm, and the rocking cams intake valve driven to open and close by swinging of said drive shaft and parallel to the oscillation axis, and a rocker arm which is swingably supported on the pivot shaft, a first link for linking the said rocker arm and said driving cams, a second link that links the said rocking cams and the rocker arm, the relative position against the driving shaft of said rocking shaft and a pivot shaft position changing means to change the operating angle or lift amount of the intake valve by varying a predetermined small operation angle range operating angle or lift amount of the intake valve or small lift range As the operating angle or lift amount of the intake valve increases, the intake valve While the opening timing of the intake valve is advanced, while the operating angle or lift amount of the intake valve is changed within a predetermined large operating angle range or large lift amount range, the operating angle or lift amount of the intake valve is increased. The opening timing of the intake valve is retarded by reducing the distance between the center of the drive shaft and the center of the swing shaft .

  According to the present invention, the valve lift characteristic of the engine valve is such that even if the operating angle or the lift amount is increased, the valve opening characteristic is not greatly advanced, that is, the operating angle or the lift amount is large. When this happens, a change in the opening timing is suppressed or the valve lift characteristic is retarded.

  As a result, it is possible to suppress the approach between the engine valve and the piston and prevent the interference between the engine valve and the piston, so that a valve recess for avoiding the interference between the valve and the piston is unnecessary or a valve recess is provided. The depth can be suppressed.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a diagram showing an engine 100 applied to the present invention.

  Engine 100 includes a variable compression ratio mechanism that continuously changes the engine compression ratio by changing the piston stroke. In the present embodiment, as the compression ratio variable mechanism, a multi-link type compression ratio variable mechanism that has been publicly proposed by the present applicant, for example, disclosed in Japanese Patent Application Laid-Open No. 2001-227367 is applied. Hereinafter, the engine 100 provided with the multi-link type compression ratio variable mechanism is referred to as a “compression ratio variable engine 100”.

  The variable compression ratio engine 100 connects the piston 122 and the crankshaft 121 with two links (an upper link (first link) 111 and a lower link (second link) 112), and a control link (third link) 113. To control the lower link 112 and change the compression ratio.

  The upper link 111 has an upper end connected to the piston 122 via a piston pin 124 and a lower end connected to one end of the lower link 112 via a connection pin 125. The piston 122 is slidably fitted to a cylinder 120 formed in the cylinder block 123, and reciprocates in the cylinder 120 under a combustion pressure.

  The lower link 112 has one end connected to the upper link 111 via the connecting pin 125 and the other end connected to the control link 113 via the connecting pin 126. Further, the lower link 112 inserts the crankpin 121b of the crankshaft 121 into a substantially central connecting hole, and swings about the crankpin 121b as a central axis. The lower link 112 can be divided into left and right members. The crankshaft 121 includes a plurality of journals 121a and a crankpin 121b. The journal 121a is rotatably supported by the cylinder block 123 and the ladder frame 128. The crank pin 121b is eccentric from the journal 121a by a predetermined amount, and the lower link 112 is swingably connected thereto.

  The control link 113 is connected to the lower link 112 via a connecting pin 126. The control link 113 is connected to the control shaft 114 at the other end via a connecting pin 127. The control link 113 swings around the connecting pin 127. Further, a gear is formed on the control shaft 114, and the gear meshes with a pinion 132 provided on the rotation shaft 133 of the compression ratio changing actuator 131. The control shaft 114 is rotated by the compression ratio changing actuator 131, and the connecting pin 127 moves.

  FIG. 2 is a diagram for explaining a compression ratio changing method by the variable compression ratio engine 100.

  In the variable compression ratio engine 100, the controller 300 (to be described later) controls the compression ratio change actuator 131 to rotate the control shaft 114 to change the position of the connecting pin 127, thereby changing the compression ratio. For example, as shown in FIGS. 2 (A) and 2 (C), if the connecting pin 127 is set to the position P, the top dead center position (TDC) is increased and the compression ratio is increased.

  As shown in FIGS. 2B and 2C, when the connecting pin 127 is moved to the position Q, the control link 113 is pushed upward, and the position of the connecting pin 126 is raised. As a result, the lower link 112 rotates counterclockwise about the crank pin 121b, the connecting pin 125 is lowered, and the position of the piston 122 at the piston top dead center is lowered. Therefore, the compression ratio becomes a low compression ratio.

  Next, the intake valve variable valve mechanism 200 of the variable compression ratio engine 100 according to the present invention will be described with reference to FIGS. 3 and 4. FIG. 3 is a perspective view showing an intake valve variable valve mechanism 200 of the compression ratio variable engine 100 according to the present invention. FIG. 4 is a drive shaft direction view of the lift / operating angle variable mechanism 210 constituting a part of the intake valve variable valve mechanism 200.

  The intake valve variable valve mechanism 200 includes a lift / operation angle variable mechanism 210 that changes a lift / operation angle of the intake valve 211 (see FIG. 4), and a lift center angle of the intake valve 211 (the intake valve 211 reaches a maximum lift). And a phase variable mechanism 240 for advancing or retarding the phase of the crank angle position). The variable valve operating apparatus for changing the operating angle or lift amount of the engine valve according to the invention is described as the lift / operating angle variable mechanism 210 in the present embodiment. In FIG. 3, only a pair of intake valves and related parts corresponding to one cylinder are illustrated in a simplified manner.

  First, the configuration and operation of the lift / operating angle variable mechanism 210 will be described.

  As shown in FIG. 3, each cylinder of the compression ratio variable engine 100 is provided with a hollow drive shaft 213 that is provided above the pair of intake valves in parallel with the crankshaft and extends in the cylinder row direction. To be provided.

  The drive shaft 213 is linked to the crankshaft by a belt or chain (not shown) via a driven sprocket 242 provided at one end, and rotates in conjunction with the crankshaft. The drive shaft 213 of the present embodiment is assumed to rotate clockwise in FIG.

  A pair of swing cams 220 are supported on the drive shaft 213 so as to be rotatable (swingable) with respect to the drive shaft 213 for each cylinder. Although the operation will be described in detail later, the pair of swing cams 220 swings (up and down) around the drive shaft 213 within a predetermined rotation range, so that the cam nose 223 of the swing cam 220 is below. The valve lifter of the intake valve located is pressed, and the intake valve lifts downward. The pair of swing cams 220 are integrated with each other via a cylindrical portion covering the outer periphery of the drive shaft 213, and swing at the same phase.

  A drive cam 215 is provided on the drive shaft 213. The drive cam 215 is a circular shape having a center whose outer shape is shifted from the center of the drive shaft 213 by a predetermined amount, and is a so-called eccentric cam. Here, a cylindrical member having an eccentric hole is fixed to the outer periphery of the drive shaft by press-fitting or the like.

  The drive cam 215 is provided at a position shifted in the axial direction from the swing cam 220. A link arm 225 as a first link linked to a rocker arm 217 described later is rotatably fitted to the outer peripheral surface of the drive cam 215.

  The link arm 225 includes an annular base 225a having a relatively large diameter and a protruding end 225b that protrudes from a part of the base 225a. A pin hole 225c is formed through the protruding end 225b.

  A crank-shaped control shaft 216 extends obliquely above the drive shaft 213 in the cylinder row direction in parallel with the drive shaft 213 and is rotatably supported by the cylinder head.

  The control shaft 216 is a main shaft portion 216a supported by the engine body, and is eccentric from the main shaft portion 216a by a predetermined amount, and is provided in parallel with the drive shaft 213 so as to swing a rocker arm 217 described later. The moving shaft 216b includes a connecting portion 216c that connects the main shaft portion 216a and the swing shaft 216b.

  The rocker arm 217 rotatably attached to the outer peripheral surface of the swing shaft 216b is composed of two members and is mounted around the swing shaft 216b by two bolts 218. The rocker arm 217 includes a connecting pin part 217a and a connecting part 217b. When the compression ratio variable engine 100 is viewed from the front, the connecting pin portion 217a and the connecting portion 217b are connected to the cam nose 223 of the swing cam 220 with respect to a straight line connecting the center of the drive shaft 213 and the center of the swing shaft 216b. Provided on the same side. The connecting portion 217b is located farther from the center of the swing shaft 216b than the connecting pin portion 217a.

  One end of the control shaft 216 is provided with an electric lift amount changing actuator 250 that rotates the main shaft portion 216a of the control shaft 216 within a predetermined rotation angle range and displaces the swing shaft 216b. The lift amount changing actuator 250 is controlled based on a control signal from the controller 300 that controls the engine 100 based on the detection result of the operation state of the compression ratio variable engine 100. When the control shaft 216 rotates around the center of the main shaft portion 216a, the center of the swing shaft 216b moves its position, and the posture of the rocker arm 217 attached to the swing shaft 216b changes. The change in the posture of the rocker arm 217 changes the operating angle or the lift amount of the intake valve 211 as will be described later. The lift amount changing actuator 250 corresponds to swing shaft position changing means for changing the operating angle or lift amount of the intake valve 211 by displacing the swing shaft 126b.

  As shown in FIG. 4, the rocking cam 220 is formed with a base circle surface 220 a and a cam surface 220 b extending from the base circle surface 220 a to the tip edge side of the cam nose 223 in an arc shape. The base circle surface 220a and the cam surface 220b are opposed to or abut on the valve lifter 219 in accordance with the swing position of the swing cam 220. The cam nose 223 is provided so that the rotation direction of the swing cam when the engine valve is opened is the same as the rotation direction of the drive shaft with respect to the straight line connecting the center of the drive shaft 213 and the center of the swing shaft 216b. It has been.

  The axis P1 of the swinging shaft 216b is at a position eccentric from the axis P2 of the main shaft portion 216a by a predetermined amount. The center P4 of the drive cam 215 is located at a position eccentric from the axis P3 of the drive shaft 213 by a predetermined amount.

  The connecting pin portion 217a (axial center P5) of the rocker arm 217 is inserted into a pin hole 225c formed in the protruding portion 225b of the link arm 225. Thereby, the rocker arm 217 and the link arm 225 are connected. The link arm 225 corresponds to a first link that links the rocker arm 217 and the drive cam 215, and the axis P5 of the connection pin portion 217a that is a connection point between the rocker arm 217 and the link arm 225 corresponds to a first connection point.

  The connecting portion 217 b of the rocker arm 217 and the swing cam 220 are connected by a link member 226. The link member 226 includes a bifurcated first bearing portion 226a and a second bearing portion 226b at both ends.

  The first bearing portion 226a supports a connecting pin 230 (axial center P6) that connects the connecting portion 217b of the rocker arm 217 and the link member 226. The connecting portion 217b of the rocker arm 217 is disposed between the first bearing portions 226a of the link member 226 formed in a bifurcated shape.

  The second bearing portion 226b supports a connecting pin 231 (axial center P7) that connects the swing cam 220 and the link member 226. The swing cam 220 is disposed between the second bearing portions 226b of the link member 226 formed in a bifurcated shape.

  A snap ring (not shown) that restricts the movement of the link member 226 in the axial direction is provided at one end of each of the connecting pins 230 and 231. The link member 226 corresponds to a second link that links the rocker arm 217 and the swing cam 220, and the axis P6 of the connecting pin 230, which is a connection point between the rocker arm 217 and the link member 226, corresponds to a second connection point. . From the above, when the compression ratio variable engine 100 is viewed from the front, the axis P5 that is the connection point between the rocker arm 217 and the link arm 225, and the axis P6 that is the connection point between the rocker arm 217 and the link member 226 are The swing cam is located on the same side of the straight line connecting the axis P3 of the drive shaft and the shaft center P1 of the swing shaft, and the shaft center P6 is farther from the shaft center P1 of the swing shaft than the shaft center P5. 220 has a cam nose 223 on the same side as the axis P5 and the axis P6 with respect to the straight line. The cam nose 223 is provided in such a direction that the rotation direction of the swing cam 220 when the intake valve 211 is opened is the same as the rotation direction of the drive shaft 213.

  Next, the configuration and operation of the phase variable mechanism 240 will be described with reference to FIG. 3 again.

  The phase variable mechanism 240 includes a phase angle changing actuator 241 and a hydraulic device 301.

The phase angle changing actuator 241 relatively rotates the sprocket 242 and the drive shaft 213 within a predetermined angle range.

  The hydraulic device 301 controls the phase angle changing actuator 241 based on a control signal from the controller 300 that controls the engine 100 based on the detection result of the operation state of the variable compression ratio engine 100.

  By the hydraulic pressure control to the phase angle changing actuator 241 by the hydraulic device 301, the sprocket 242 and the drive shaft 213 are relatively rotated, and the lift center angle is advanced or retarded.

  Next, the operation of the lift / operating angle variable mechanism 210 will be described in detail with reference to FIGS.

  The lift / operating angle variable mechanism 210 is configured as described above. When the drive shaft 213 rotates in conjunction with the crankshaft 121, the drive cam 215 and the link arm 225 that is rotatably fitted to the outer periphery thereof are used. The rocker arm 217 swings about the axis P1 of the swing shaft 216b. The swing of the rocker arm 217 is transmitted to the swing cam 220 via the link member 226, and the swing cam 220 swings within a predetermined angle range. When the swing cam 220 swings, that is, moves up and down, the valve lifter 219 is pressed and the intake valve 211 is lifted downward. In the present embodiment, it is assumed that the drive shaft 213 rotates in the clockwise direction.

  Here, when the control shaft 216 is rotated within a predetermined rotation angle range by the lift amount changing actuator 250, the position of the axis P1 of the rocking shaft 216b serving as the rocking fulcrum of the rocker arm 217 is the position of the main shaft portion 216a. Changes by rotation around the axis. Then, the support position of the rocker arm 217 with respect to the engine body changes. When the rocker arm 217 is in the middle of rocking, when the rocking cam 220 is pulled up most (when the rocker arm 217 rotates most counterclockwise around the rocking shaft 216b in FIG. 5), the rocking cam 220 is Assuming that the position of the swing cam surface (base surface 220a) closest to the valve lifter 219 is the initial swing position of the swing cam 220, the initial swing is caused by the change in the position of the axis P1 of the swing shaft 216b. The position changes. As a result, the swing amount of the swing cam changes until the initial contact position between the swing cam 220 and the valve lifter 219 when the valve lifter is pressed down (the cam surface 220b comes into contact with the lifter and begins to be pressed down). As a result, even if the swing angle of the swing cam 220 per one rotation of the crankshaft is almost always constant, the swing amount of the swing cam 220 after the push-down starts changes, as shown in FIGS. Maximum lift (operating angle) changes.

  FIGS. 5A and 5B show the positions of the swing cam 220 at the minimum swing and the maximum swing when the operating angle of the intake valve 211 is close to the maximum operating angle (full lift). FIG. 5 (C) and 5 (D) show the positions of the swing cam 220 at the minimum swing and the maximum swing when the operating angle of the intake valve 211 is close to the minimum operating angle (zero lift). FIG.

  FIG. 6 is a diagram in which the axes P1 to P7 and straight lines connecting the axes are extracted from FIGS. 5A to 5D to facilitate understanding of the invention.

  The axis P1 of the swing shaft 216b is rotated around the axis P2 of the main shaft portion 216a between a state located above the shaft center P2 of the main shaft portion 216a and a state located on the lower left side. It moves continuously (trajectory P1 in FIG. 7). As shown in FIGS. 5A and 5B or FIGS. 6A and 6B, when the axis P1 of the swinging shaft 216b is located above the axis P2 of the main shaft portion 216a, it will be described later. The side where the rocker arm 217 turns clockwise around the drive shaft as a whole, rather than the state where the operating angle is near the minimum operating angle (FIGS. 5C, 6D, 6C, and 6D). As a result, the link member 226 is also moved to the side rotated clockwise.

  Therefore, the cam nose 223 of the swing cam 220 connected to the link member 226 is pushed down more greatly than in a state where the operating angle is near the minimum operating angle. As a result, the cam surface 220b is inclined in a direction closer to the valve lifter 219 than when the operating angle is near the minimum operating angle (see FIGS. 5A and 6A).

  Then, the interval between the initial swing position and the initial contact position of the swing cam 220 is narrowed, and when the swing cam 220 swings with the rotation of the drive shaft 213, a portion that is close to or in contact with the valve lifter 219 is a base. The circular surface 220a immediately shifts to the cam surface 220b. As a result, the maximum lift amount of the intake valve 211 becomes larger than the state in which the operating angle is in the vicinity of the minimum operating angle (see FIGS. 5B and 6B). As a result, the crank angle section from the opening timing to the closing timing of the intake valve 211, that is, the operating angle of the intake valve 211 is also increased.

  On the other hand, as shown in FIG. 5 (C) (D) or FIG. 6 (C) (D), the control shaft 216 is rotated so that the shaft center P1 of the swing shaft 216b becomes lower left of the shaft center P2 of the main shaft portion 216a. The rocker arm 217 is generally counterclockwise around the drive shaft as compared with the state where the operating angle is near the maximum operating angle (FIGS. 5A and 5B or FIGS. 6A and 6B). The link member 226 is moved to the side rotated counterclockwise.

  Therefore, the cam nose 223 of the swing cam 220 connected to the link member 226 is pulled upward as compared with a state where the operating angle is in the vicinity of the maximum operating angle. As a result, the cam surface 220b is tilted away from the valve lifter 219 than when the operating angle is near the maximum operating angle (see FIGS. 5C and 6C).

  Then, the interval between the initial swing position and the initial contact position of the swing cam 220 is increased, and when the swing cam 220 swings with the rotation of the drive shaft 213, the base circle surface 220a is long and close to the valve lifter 219. The period during which the cam surface 220b contacts the valve lifter is shortened. Thereby, the maximum lift amount of the intake valve 211 becomes smaller than the state where the operating angle is in the vicinity of the maximum operating angle (see FIGS. 5D and 6D). As a result, the operating angle of the intake valve 211 is also reduced.

  FIG. 7 is a diagram in which the shaft centers P1 to P7 of the lift / operating angle variable mechanism 210 and straight lines connecting the respective shaft centers are extracted. In FIG. 7, the broken line indicates a state where the operating angle is near the minimum operating angle, and the solid line indicates a state where the operating angle is near the maximum operating angle.

  In the following, a line segment connecting the axis P1 of the swing shaft 216b and the axis P3 of the drive shaft 213 is referred to as “line segment P1P3”. Further, the distance between the axis P1 and the axis P3 is referred to as a “fulcrum distance D”. Furthermore, an angle formed by the line segment P1P3 and the virtual line L passing through the axis P3 indicated by a dotted line in the drawing is referred to as “inter-fulcrum angle θ”.

  As shown in FIG. 7, in order to change the operating angle or the lift amount from the minimum operating angle state to the maximum operating angle state, the control shaft 216 is rotated within a predetermined rotational angle range, and the swing shaft When the axial center P1 of 216b is moved on a circle centered on the axial center P2 of the main shaft portion 216a, the inter-fulcrum angle θ changes and the inter-fulcrum distance D also changes.

  That is, according to the variable lift / operating angle mechanism 210 according to the present embodiment, when the operating angle or the lift amount is changed from the minimum operating angle to the maximum operating angle, the fulcrum angle θ gradually increases from θmin to θmax. Change.

  On the other hand, the inter-fulcrum distance D gradually increases from the minimum operating angle to the intermediate operating angle, and changes from Dmin to Dmax. Then, it gradually decreases from the intermediate operating angle to the maximum operating angle, changes from Dmax to Dmin, and returns to substantially the same length as the distance between the fulcrums at the minimum operating angle.

  Below, with reference to FIG. 8, the effect | action produced by changing the angle (theta) between fulcrums is maintained, maintaining the distance D between fulcrums at the same length. Next, with reference to FIG. 9, a description will be given of the action caused by changing the fulcrum distance D while maintaining the fulcrum angle θ at the same angle.

  FIG. 8A shows the minimum operating angle. FIG. 8B is a diagram showing the maximum operating angle.

  As shown in FIGS. 8A and 8B, when the inter-fulcrum angle θ is changed from θmin to θmax while maintaining the same distance D between the fulcrums (θmin <θmax), the axis P1 Moves clockwise from the lower side to the upper side on the circumference C1 about the axis P3. On the other hand, the shaft center P7 moves from the upper side to the lower side in the clockwise direction on the circumference C2 centered on the shaft center P3. That is, the position of the connecting pin 231 (axial center P7) connected to the cam nose of the swing cam 220 moves downward.

  Then, the initial contact position of the swing cam 220 with the valve lifter 219 and the initial swing position come closer to each other. As a result, the operating angle of the intake valve 211 is expanded.

  As described above, when the fulcrum angle θ is increased while maintaining the fulcrum distance D at the same length, the operating angle of the intake valve 211 is increased.

  In FIG. 9, the shaft centers P1 to P7 of two variable valve operating devices having the same distance D between the fulcrums, but the other dimensions such as the distance between the shafts, and the straight lines connecting the shaft centers are represented by the drive shaft. It is the figure which compared the rotation angle position of 213 in the substantially the same state. 9A and 9B have the same fulcrum angle θ, but the fulcrum distance D1 in FIG. 9A is shorter than the fulcrum distance D2 in FIG. 9B (D1 <D2). ).

  As shown in FIGS. 9A and 9B, when the fulcrum distance D is increased, the axis P1 of the swing shaft 216b is further away from the drive shaft center P3 than when the fulcrum distance D is short. Located above. Then, the positions of the center P3 of the drive shaft and the center P4 of the drive cam, and the lengths of the line segment P1P5 and the line segment P5P4 are equal to each other. Therefore, the angle formed by the line segment P1P5 and the line segment P5P4 is the distance between the fulcrums D. Increased when lengthened. Therefore, when the distance D between the fulcrums is increased, the inclination of the line segment P1P5 is changed in the same way as when it is rotated clockwise. At this time, the connecting portion 217b (axial center P6) that is farther away from the swinging shaft center P3 than the connecting pin portion 217a (axial center P5) is based on the lever principle (the position of the axial center P5 does not change greatly, Since the axis P1 moves upward), it moves downward in the figure.

  As a result, the shaft center P7 of the connecting pin 231 that connects the link member 226 and the cam nose of the swing cam 220 is pushed downward relatively, so that the initial contact position of the swing cam 220 with the valve lifter 219 and the initial swing are reduced. The moving positions come closer to each other. As a result, the operating angle of the intake valve 211 is expanded.

  As described above, when the inter-fulcrum distance D is increased while the inter-fulcrum angle θ is maintained at the same angle, the operating angle of the intake valve 211 is expanded.

  Thus, the lift / operating angle variable mechanism 210 according to the present embodiment changes the operating angle of the intake valve 211 by changing the inter-fulcrum angle θ and the inter-fulcrum distance D.

  Next, the operation of the lift / operating angle variable mechanism 210 according to this embodiment will be described.

  FIG. 10 is a view showing the valve lift characteristics by the variable lift / operating angle mechanism 210 according to the present embodiment. FIG. 11 is a diagram showing the relationship between the intake valve opening timing (IVO) and the intake valve closing timing (IVC) of each valve lift characteristic shown in FIG. In either figure, the operating angle center is not changed by the phase variable mechanism 240, and the valve lift characteristic is changed only by the lift / operating angle variable mechanism 210.

  As shown in FIGS. 10 and 11, according to the variable lift / operating angle mechanism 210 according to the present embodiment, when the operating angle is changed from the minimum operating angle to the maximum operating angle, the minimum operating angle is predetermined. Up to the operating angle, the operating angle increases as before and the intake valve opening timing (IVO) advances. However, from the predetermined operating angle to the maximum operating angle, the movement of the intake valve opening timing in the advance direction can be suppressed or the intake valve opening timing can be delayed while increasing the operating angle.

  This is because when the operating angle is changed from the minimum operating angle to the maximum operating angle, the fulcrum distance D gradually increases from the minimum operating angle to the intermediate operating angle, but from the intermediate operating angle to the maximum operating angle. This is because it gradually decreases to the corner.

  That is, when the operating angle is changed from the minimum operating angle to the maximum operating angle, the operating angle is increased by increasing the inter-fulcrum angle θ, so that the intake valve opening timing is advanced. Further, from the minimum operating angle to the intermediate operating angle, the distance D between the fulcrums also becomes longer, and this increases the operating angle, so that the intake valve opening timing is advanced.

  Thus, since the fulcrum angle θ and the fulcrum distance D both increase from the minimum operating angle to the intermediate operating angle, the operating angle increases and the intake valve opening timing advances.

However, from the intermediate operating angle to the maximum operating angle, the fulcrum angle θ increases, but the fulcrum distance D decreases. Therefore, while the intake valve opening timing is advanced by increasing the fulcrum angle θ, the operating angle is decreased by decreasing the fulcrum distance D, and the intake valve opening timing is retarded accordingly.

  Accordingly, from the intermediate operating angle to the maximum operating angle, the movement of the intake valve opening timing in the advance direction can be suppressed or the intake valve opening timing can be delayed while increasing the operating angle. When the operating angle or lift amount of the intake valve 211 increases, the lift operating angle center moves to the retard side, and the amount of movement of the lift operating angle center to the retard side with respect to the increase of the operating angle or lift amount Is larger in a range where the operating angle or lift amount is larger than the predetermined operating angle or lift amount than in a range where the operating angle or lift amount is smaller than the predetermined operating angle or lift amount.

  As described above, in the intake valve variable valve mechanism according to the present embodiment, when the operating angle increases near the maximum operating angle, the movement of the intake valve opening timing in the advance direction is suppressed, and the intake valve opening timing is retarded. The valve characteristics are Therefore, it is possible to reduce the degree of approach between the valve and the piston in the state where the operating angle of the intake valve 211 is set to the maximum operating angle and the lift center angle is set to the maximum advance angle. On the other hand, at the minimum operating angle, the intake valve opening timing is retarded (compared to the intermediate operating angle), that is, the advance angle of the entire operating angle range is suppressed, so the intake valve closing timing is also retarded. Stay close. As a result, the intake valve closing timing is kept as late as possible in the intake stroke, and it is not necessary to leave as far as possible from the bottom dead center. Therefore, a sufficient in-cylinder inflow air amount at the time of starting is ensured and the engine startability is improved. .

  Here, the valve recess of the piston is provided at a depth with a certain margin on the basis of a state in which the amount of interference between the valve and the piston is maximized in consideration of a failure time of the intake valve variable valve mechanism. Therefore, the surface area of the valve recess is reduced by reducing the possibility of interference between the valve and the piston in the state in which the operating angle of the intake valve 211 is set to the maximum operating angle and the lift central angle is set to the maximum advance angle. Can be reduced. Thereby, cooling loss can be reduced. In addition, fuel efficiency can be improved by increasing combustion efficiency.

  Next, control of the intake valve variable valve mechanism 200 according to the present embodiment will be described.

  FIG. 12 is a control map for determining the intake valve opening timing (IVO) and the intake valve closing timing (IVC) in each operation state.

  As shown in FIG. 12, at the time of full engine load and low speed, the operating angle is set to an intermediate operating angle just between the minimum operating angle and the maximum operating angle, and IVO is set after the top dead center. When the engine is at full load / medium speed (operating state A), the lift / operating angle variable mechanism increases the operating angle compared to when the engine is fully loaded / low speed, and the phase variable mechanism allows the IVO to reach the top dead center. Is set. When the engine is fully loaded and at high speed (operation state B), the operating angle is set to the maximum operating angle by the variable lift / operating angle mechanism, and the IVO is further increased by the phase variable mechanism than when the engine is fully loaded and medium speed. Set to the advance side.

  Here, in the present embodiment, the following control is executed when shifting from the operating state A to the operating state B or when shifting from the operating state B to the operating state A.

  When shifting from the driving state A to the driving state B, that is, when the vehicle is in an accelerating state and the valve timing is such that the operating angle increases and the IVO advances, the intake valve closing timing (IVC) Until the target IVC is reached, the driving of the phase variable mechanism 240 is prohibited, and only the variable lift / operating angle mechanism 210 is driven. After the IVC reaches the target IVC, cooperative control for simultaneously driving the lift / operating angle variable mechanism 210 and the phase variable mechanism 240 is performed to control the valve timing of the intake valve 211 to the optimal valve timing. To do.

  That is, as shown in FIG. 13, only the lift / operating angle variable mechanism 210 is first driven, and after the transition from the operating state A to the operating state C and the IVC reaches the target IVC, the lift / operating angle variable mechanism 210. Then, the phase variable mechanism 240 is simultaneously driven to shift to the operation state B.

  Since the lift / operating angle variable mechanism 210 is driven by an electric lift amount changing actuator 250, the response speed is faster than that of the phase variable mechanism 240 driven by hydraulic pressure. Therefore, at the time of acceleration, first, the lift / operating angle variable mechanism 210 is driven to quickly reach the target IVC, whereby the IVC can be prevented from being transiently retarded from the target IVC. For this reason, it is possible to prevent a decrease in filling efficiency and a deterioration in driving performance.

  On the other hand, when shifting from the driving state B to the driving state A, that is, when the vehicle is in a decelerating state, and when the valve timing is such that the operating angle decreases and the IVO is retarded, the IVO becomes the target IVO. Until reaching, the drive of the lift / operating angle variable mechanism 210 is prohibited and the phase variable mechanism 240 is driven preferentially. Then, after the IVO reaches the target IVO, the lift / operating angle variable mechanism 210 and the phase variable mechanism 240 are cooperatively controlled to control the valve timing of the intake valve 211 to the optimal valve timing.

  That is, as shown in FIG. 14, first, only the phase variable mechanism 240 is driven, and after the IVO reaches the target IVO after shifting from the operating state B to the operating state D, the phase change mechanism 210 and the phase The variable mechanism 240 is simultaneously driven to shift to the operation state A.

  If the lift / operating angle variable mechanism 210 is driven at the valve timing at which the operating angle is reduced and the IVO is advanced, the IVO is excessively advanced. If it does so, since it is necessary to expand the valve recess for avoiding interference with a valve and a piston, cooling performance etc. will deteriorate.

  Therefore, in such an operating state, the phase variable mechanism 240 is first driven to reach the target IVO, and then the lift / operating angle variable mechanism 210 and the phase variable mechanism 240 are cooperatively controlled. Thus, it is possible to prevent the IVO from being excessively advanced. Therefore, deterioration of cooling loss etc. can be prevented.

  According to the present embodiment described above, the valve lift characteristic of the intake valve increases the operation angle from the predetermined operation angle to the maximum operation angle and suppresses the movement of the intake valve opening timing in the advance direction, or The valve lift characteristics are such that the intake valve opening timing is retarded.

  As a result, the degree of approach between the valve and the piston can be reduced when the operating angle of the intake valve 211 is set to the maximum operating angle and the lift center angle is set to the maximum advance angle. Therefore, the surface area of the valve recess can be reduced, and the cooling loss can be reduced. In addition, fuel efficiency can be improved by increasing combustion efficiency.

  Further, when the vehicle is in an accelerating state and the valve timing is such that the operating angle increases and the intake valve opening timing (IVO) is retarded, the intake valve closing timing (IVC) reaches the target IVC. In the meantime, the driving of the phase variable mechanism 240 is prohibited and only the lift / operating angle variable mechanism 210 is driven.

  Thereby, at the time of acceleration, first, the lift / operating angle variable mechanism 210 having good operation responsiveness is driven to quickly reach the target IVC, so that the IVC is transiently retarded from the target IVC. Can be prevented. For this reason, it is possible to prevent a decrease in filling efficiency and a deterioration in driving performance.

Further, when the vehicle is in a deceleration state and the valve timing is such that the IVO is retarded as the operating angle increases, that is, the valve timing when the IVO is advanced as the operating angle decreases, the IVO reaches the target IVO. Until it reaches, variable lift / operating angle mechanism 2
10 is prohibited, and the phase variable mechanism 240 is preferentially driven.

  Thereby, it can prevent that IVO will advance too much. Therefore, deterioration of cooling loss etc. can be prevented.

  Furthermore, in the case of a variable compression ratio engine, the higher the compression ratio, the larger the ratio (S / V ratio) between the combustion chamber volume and the surface area and the greater the cooling loss. However, by combining with the variable lift / operating angle mechanism 210 according to the present embodiment, the surface area of the valve recess can be reduced and the surface area can be reduced. Thereby, the increase in S / V ratio accompanying high compression can be suppressed, and cooling loss can be reduced.

  Note that the present invention is not limited to the above-described embodiment, and it is obvious that various modifications can be made within the scope of the technical idea. For example, when combined with a phase variable mechanism that moves differently from that described in the embodiment, the operating angle increases, the movement of the intake valve opening timing in the advance direction is suppressed, or the intake valve opening timing is delayed. The range of the operating angle or lift amount to be angled can be set in a range that is not near the maximum operating angle (maximum lift amount) according to the required conditions. Further, the variable valve device according to the present invention can be applied to an exhaust valve to suppress the close timing of the exhaust valve, thereby suppressing the approach between the exhaust valve and the piston.

It is a figure which shows a compression ratio variable engine. It is a figure explaining the compression ratio change method by a compression ratio variable engine. It is a perspective view which shows the intake valve variable valve mechanism of a compression ratio variable engine. It is a drive shaft direction view of the lift / operating angle variable mechanism that constitutes a part of the intake valve variable valve mechanism. It is a figure which shows the position at the time of the minimum rocking | swiveling of the rocking | fluctuation cam at the time of the full lift (maximum working angle) and (minimum working angle) of an intake valve. It is the figure which extracted and extracted the framework of Drawing 5 (A)-(D) typically. It is the figure which represented typically the framework of the lift and the working angle variable mechanism. It is the figure which represented typically the framework of the lift and the working angle variable mechanism at the time of the minimum working angle and the maximum working angle. It is the figure which represented typically the framework of the two variable valve mechanisms from which the distance D between fulcrums differs. It is the figure which showed the valve lift characteristic of the intake valve variable valve mechanism by this embodiment. It is the figure which showed the relationship between the intake valve opening timing of each valve lift characteristic shown in FIG. 10, and an intake valve closing timing. It is the figure which showed the relationship between the intake valve open timing in each driving | running state, and an intake valve close timing. It is a figure explaining control of the intake valve variable valve mechanism by this embodiment. It is a figure explaining control of the intake valve variable valve mechanism by this embodiment.

Explanation of symbols

100 Compression ratio variable engine (internal combustion engine)
121 Crankshaft 211 Intake valve (engine valve)
213 Drive shaft 215 Drive cam 216b Oscillating shaft 217 Rocker arm 220 Oscillating cam 223 Cam nose 225 Link arm (first link)
226 Link member (second link)
241 Phase angle change actuator (phase change means)
250 Lift amount changing actuator (oscillating shaft position changing means)
300 controller

Claims (8)

A drive shaft that rotates in synchronization with the crankshaft of the internal combustion engine;
A drive cam provided on the drive shaft;
A swing cam that is swingably supported by the drive shaft;
An intake valve that is opened and closed by swinging the swing cam;
A swing shaft parallel to the drive shaft;
A rocker arm that is swingably supported by the swing shaft;
A first link that links the rocker arm and the drive cam;
A second link that links the rocker arm and the swing cam;
Oscillating shaft position changing means for changing the operating angle or lift amount of the intake valve by changing the relative position of the oscillating shaft to the drive shaft;
With
While the operating angle or lift amount of the intake valve is changed within a predetermined small operating angle range or small lift amount range, the opening timing of the intake valve is advanced as the operating angle or lift amount of the intake valve is increased. On the other hand, while the operating angle or lift amount of the intake valve is changed within a predetermined large operating angle range or large lift amount range, the center of the drive shaft and the swing are increased as the operating angle or lift amount of the intake valve increases. The opening timing of the intake valve is retarded by shortening the distance from the center of the dynamic axis,
A variable valve operating apparatus characterized by that. The variable valve operating apparatus according to claim 1,
The predetermined large operating angle range or large lift amount range is a range from a predetermined operating angle or lift amount to a maximum operating angle or maximum lift amount .
A variable valve operating apparatus characterized by that. In the internal combustion engine provided with the variable valve operating apparatus according to claim 1 or 2 ,
The variable valve operating device includes phase changing means for continuously changing the center phase of the operating angle of the intake valve,
A controller that drives the swing shaft position changing means and prohibits the phase changing means from being driven until the intake valve closing timing reaches the target intake valve closing timing during vehicle acceleration;
An internal combustion engine characterized by that. The internal combustion engine according to claim 3,
The controller is
After the intake valve closing timing reaches the target intake valve closing timing during vehicle acceleration, the swing shaft position changing means and the phase changing means are simultaneously driven so that the intake valve closing timing becomes the target intake valve closing timing. Control the operating angle to the target operating angle while fixing it,
An internal combustion engine characterized by that. In the internal combustion engine according to claim 3 or 4 ,
The controller is
When the vehicle is decelerated, the phase changing means is driven until the intake valve opening timing reaches the target intake valve opening timing, and the driving of the swing shaft position changing means is prohibited.
An internal combustion engine characterized by that. The internal combustion engine according to claim 5 ,
The controller is
After the intake valve opening timing reaches the target intake valve opening timing when the vehicle decelerates, the swing shaft position changing means and the phase changing means are simultaneously driven so that the intake valve opening timing becomes the target intake valve opening timing. Control the operating angle to the target operating angle while fixing it,
An internal combustion engine characterized by that. In the internal combustion engine according to any one of claims 3 to 6,
The controller is
When the target operating angle is set to a value between a predetermined operating angle and a maximum operating angle, the control for prohibiting driving of either the swing shaft position changing means or the phase changing means is performed. carry out,
An internal combustion engine characterized by that. In the internal combustion engine according to any one of claims 3 to 6,
The controller is
Carrying out control for prohibiting driving of either one of the swing shaft position changing means and the phase changing means at the time of full engine load;
An internal combustion engine characterized by the above.

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