JP3876087B2 - Variable valve operating device for internal combustion engine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a variable valve operating apparatus for an internal combustion engine that can vary the opening / closing timing and valve lift amount of an intake / exhaust valve according to the engine operating state.
[0002]
[Prior art]
As is well known, the intake / exhaust valve opening / closing timing is used to improve fuel efficiency at low engine speeds and low loads, to ensure stable operation, and to ensure sufficient output by improving intake charge efficiency at high speeds and high loads. Various variable valve operating devices that variably control the valve lift amount according to the engine operating state have been conventionally provided. For example, those described in Japanese Patent Application Laid-Open No. 55-137305 are known. .
[0003]
The outline thereof will be described with reference to FIG. 18. A cam shaft 2 is provided at a position near the upper center of the upper deck of the cylinder head 1, and a cam 2 a is integrally provided on the outer periphery of the cam shaft 2. A control shaft 3 is arranged in parallel on the side of the camshaft 2, and a rocker arm 5 is pivotally supported on the control shaft 3 via an eccentric cam 4.
[0004]
On the other hand, a swing cam 8 is disposed at the upper end of an intake valve 6 slidably provided on the cylinder head 1 via a valve lifter 7. The swing cam 8 is pivotably supported on a support shaft 9 disposed above the valve lifter 7 in parallel with the camshaft 2, and a lower cam surface 8 a is in contact with the upper surface of the valve lifter 7. . The rocker arm 5 has one end 5a abutting on the outer peripheral surface of the cam 2a and the other end 5b abutting on the upper end surface 8b of the swing cam 8, thereby lifting the cam 2a. And it is transmitted to the intake valve 6 via the valve lifter 7.
[0005]
The control shaft 3 is rotationally controlled within a predetermined angle range by an actuator (not shown) to control the rotational position of the eccentric cam 4, thereby changing the rocking fulcrum of the rocker arm 5.
[0006]
When the eccentric cam 4 is controlled to a predetermined forward and reverse rotational position, the rocking fulcrum of the rocker arm 5 changes, and the contact position of the other end 5b with the upper end surface 8b of the rocking cam 8 is up and down in the figure. As a result, the swinging locus of the swing cam 8 changes with the change in the contact position of the cam surface 8a of the swing cam 8 with respect to the upper surface of the valve lifter 7. Timing) and valve lift amount are variably controlled. In the figure, reference numeral 10 denotes a spring that elastically urges the upper end surface 8b of the rocking cam 8 against the other end portion 5b of the rocker arm 5.
[0007]
[Problems to be solved by the invention]
However, in the conventional valve operating apparatus, the cam 2a and the swing cam 8 are provided on the camshaft 2 and the support shaft 9, respectively, and the two 2a and 8 are located at positions that are largely separated in the width direction of the engine. It is arranged separately and independently. For this reason, a large arrangement space for the cam 2a and the swing cam 8 is required.
[0008]
Further, since the cam 2a and the swing cam 8 are largely separated in the engine width direction, both end portions 5a and 5b of the rocker arm 5 must be extended in a substantially square shape in the engine width direction. Therefore, along with the increase in the arrangement space, the size of the rocker arm 5 is increased, and the mountability of the valve operating device to the engine is deteriorated, and the size and weight of the engine are inevitably increased.
[0009]
Further, since the camshaft 2 and the support shaft 9 are arranged at different locations, the camshaft 2 and the support shaft 9 are likely to be misaligned with each other, thereby improving the valve timing control accuracy. May decrease.
[0010]
Further, since the end 5b of the rocker arm 5 directly presses the upper end surface 8b of the rocking cam 8 to obtain the rocking of the rocking cam 8, the pressing point (contact position) of the rocker arm 5 is rocked. There is a risk of detachment from the upper end surface 8 b of the moving cam 8. Therefore, the rocking fulcrum position of the rocker arm 5 is restricted, and the rocking locus of the rocking cam 8 and thus the valve timing / lift amount of the intake valve 6 cannot be set large.
[0011]
In addition, the conventional device is applied to an engine having two intake or exhaust valves per cylinder, for example, one valve stop control for stopping the operation of one intake valve and aiming at a swirl effect during idle operation. It was not considered.
[0012]
[Means for Solving the Problems]
The present invention has been devised in view of the problems of the conventional variable valve gear, and the invention according to claim 1 is a drive shaft that is driven to rotate by a crankshaft of an engine and a drive cam is fixed to the outer periphery. A camshaft that is slidably provided on the outer periphery of the drive shaft, a pair of swing cams that are provided on the camshaft to open and close two engine valves per cylinder, and one end A rocker arm whose part is rotatably linked to the drive cam and whose other end is mechanically linked to the at least one rocking cam, and a variable mechanism for changing the rocking fulcrum of the rocker arm in an engine operating state. And a control mechanism that controls in accordance with the camshaft, wherein the swing cam on one side is fixed to the camshaft, the swing cam on the other side is swingably provided, and The other side of the swing cam It is characterized in that a connection switching mechanism for releasing the or coupling for connecting to the cam shaft in accordance with the.
[0013]
According to a second aspect of the present invention, the connection switching mechanism includes an operation hole drilled in a direction perpendicular to the camshaft axis in an inner peripheral portion of the other side swing cam, and an outer periphery of the camshaft facing the operation hole. A sliding hole drilled in the part and slidably accommodated in the operating hole, the first pressing means advances and slides to a position straddling the operating hole and the sliding hole, and swings on the other side A connecting piston for connecting the cam and the camshaft and a second pressing means for sliding the connecting piston back into the operation hole are provided.
[0014]
The invention described in claim 3 is characterized in that the first pressing means is constituted by a spring member, while the second pressing means is constituted by a hydraulic circuit.
[0015]
According to a fourth aspect of the present invention, the connection switching mechanism is capable of swinging via a support shaft at the engaging protrusion extending in the direction perpendicular to the axis from the outer peripheral surface of the camshaft and at the upper end of the other swing cam. And a lever whose one end is engageable with the engaging protrusion, and is provided on the other end side of the lever, and is pressed in a direction to engage one end of the lever with the engaging protrusion. The first pressing means to be energized, and provided on the outer peripheral portion of the other side swing cam on the lever one end side, the other end of the lever is pushed up in the other direction against the pressing force of the first pressing means and engaged. It has the 2nd press means which cancels | releases engagement with a protrusion, It is characterized by the above-mentioned.
[0016]
According to a fifth aspect of the present invention, there is provided a restricting means for restricting free swinging of the other swing cam outside the swing range of the first swing cam when the both swing cams are disconnected. It is said.
[0017]
Therefore, according to the present invention, since the drive cam and the swing cam are provided together on the drive shaft, the apparatus can be made compact, in particular, according to the engine operating state by the connection switching mechanism, for example. The operation of the intake valve on one side can be stopped.
[0018]
That is, for example, at the time of engine start or idle operation, the entire connecting pin is stored and held in the operating hole by the second pressing means. For this reason, the two swing arms are not connected to each other and are in a free state, and the one-side swing cam linked to the drive cam swings via the rocker arm due to the eccentric rotation of the drive cam, and the engine valve Open and close one side. On the other hand, the swing cam on the other side is in a swing stop state, and therefore the opening / closing operation of the engine valve on the other side is stopped. As a result, the starting torque by the crankshaft at the time of start is reduced, the startability is improved, and the fuel efficiency during idling is improved.
[0019]
The swing cam on the other side in the swing stop state is swung freely due to the sliding resistance with the cam shaft as the swing cam on the one side swings. Therefore, the swing range is restricted within the range of the swing locus of the one-side swing cam, so that there will be no hindrance to the connecting action described later.
[0020]
Further, when the engine shifts to, for example, a steady operation and a high rotation / high load region, the pressing force of the first pressing means overcomes the pressing force of the second pressing means to press the connecting pin, and the operation hole and the sliding hole Is held at the position between. Thereby, both rocking cams are integrally connected via the camshaft. For this reason, the eccentric rotational force of the drive cam is transmitted from the swing cam on one side to the swing cam on the other side through the cam shaft, so that both the swing cams swing integrally. Therefore, the engine valve on the other side is also opened and closed, and as a result, the output can be improved by improving the intake charging efficiency.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
1 to 4 show a first embodiment of a variable valve operating apparatus according to the present invention, which is applied to an internal combustion engine having intake valves which are two engine valves per cylinder.
[0022]
In other words, this variable valve operating device is disposed along a longitudinal direction of the engine on the cylinder head 11 and a pair of intake valves 12 and 12 slidably provided on the cylinder head 11 via a valve guide (not shown). A hollow drive shaft 13, a single drive cam 15 fixed to the outer peripheral surface of the drive shaft 13 by press-fitting or the like, and a hollow drive shaft fitted into the outer periphery of the drive shaft 13 so as to be slidable relative to each other. A camshaft 14, a pair of swing cams 17, 27 provided at both ends of the camshaft 14 for pressing and opening the intake valves 12, 12 via valve lifters 16, 16; A rocker arm 18 disposed on the upper side, with one end 18a linked to the drive cam 15 via a link arm 19 and the other end 18b linked to the first swing cam 17 via a pair of link members 20; , Said b A variable mechanism 21 to the swing fulcrum position of Kaamu 18 variable, is composed primarily of a non-illustrated control means for controlling operation in accordance with the variable mechanism 21 to the engine operating state.
[0023]
The drive shaft 13 receives a rotational force from the crankshaft of the engine via a driven sprocket (not shown) provided at one end, a timing chain wound around the driven sprocket, and the like.
[0024]
The camshaft 14 has a cylindrical shape, and is rotatably disposed on the outer periphery of the drive shaft 13 between the drive cams 15 and 15 provided between the cylinders as shown in FIGS. 2 and 3, and a central portion 14a. Is supported by the bearing 22, and the drive shaft 13 is supported by the inner peripheral surface 14b of the axial hole formed inside.
[0025]
Further, one end 14d of the central portion 14a abuts and supports one side surface of the second rocking cam 27 in order to prevent the second rocking cam 27 described later from tilting in the thrust direction.
[0026]
The bearing 22 is provided at the upper end portion of the cylinder head 11 to support the camshaft 14, and the sub bracket 22b is provided at the upper end portion of the main bracket 22a to rotatably support a control shaft described later. Both brackets 22a and 22b are fastened and fixed to the cylinder head 11 from above by a pair of bolts 22c and 22c.
[0027]
As shown in FIGS. 1 and 3, the drive cam 15 has a main body 15 a having a substantially ring shape, a drive shaft insertion hole 15 c penetratingly formed in the internal axis direction, and an axis X being the drive shaft 13. Is eccentric from the axial center Y by a predetermined amount in the radial direction. Further, a cylindrical portion 15b that is fixedly supported on the outer periphery of the drive shaft 13 is integrally provided on a side portion of the main body 15a. The cylindrical portion 15b abuts and supports the other side surface of the second rocking cam 27 and cooperates with one end 14d of the camshaft 14 to prevent the second rocking cam 27 from tilting. Further, the drive cam 15 is disposed on both outer sides of the drive shaft 13 so as not to interfere with the valve lifters 16 and 16.
[0028]
Each of the valve lifters 16 has a covered cylindrical shape as shown in FIGS. 2 and 3, and includes a cylindrical skirt portion 16a and a curved top wall 16b integrally formed at the upper end portion of the skirt portion 16a. The skirt portion 16a is slidably held in holding holes 11a and 11a formed in the cylinder head 11.
[0029]
Each of the swing cams 17 and 27 has a substantially U shape as shown in FIGS. 1 and 6 to 11, and the first swing cam 17 on one side is a cam as shown in FIG. The second swing cam 27 on the other side is fixed integrally to one end portion of the shaft 14, and is swingably supported on the other end portion side of the camshaft 14 via a support hole 27 b.
[0030]
Further, as shown in FIG. 7, the second swing cam 27 has an annular shape that ensures good lubricity between the second swing cam 27 and the camshaft 14 at the center of the inner peripheral surface of the support hole 27b. An oil groove 27c is formed, and a stopper groove 27d into which a pressing plunger 56b of a stopper mechanism 56 described later is engaged is formed on the upper surface. Further, a pin hole 17 b is formed through the cam nose portion 17 a on the distal end side of the first swing cam 17. Further, the same cam face 25 is formed on the lower surfaces of the swing cams 17 and 27.
[0031]
As shown in FIG. 6, the cam face 25 includes a base circle surface 25a, a cam surface 25b extending from the base circle surface 25a in an arc shape toward the cam nose portions 17a and 27a, and a tip end side of the cam surface 25b, that is, a cam nose. The base lift surface 25a, the cam surface 25b, and the cam lift portion 25c are predetermined on the upper surface of each valve lifter 16 according to the swing position of the swing cam 17. It comes in contact with the position. That is, the predetermined angle range θ1 of the base circle surface 25a is a base circle section, the predetermined angle range θ2 of the cam surface 25b is a so-called ramp section, and the predetermined angle range θ3 from the cam surface 25b to the cam lift portion 25c is a lift section. It is set to be.
[0032]
As shown in FIG. 1, the rocker arm 18 is integrally bent in a substantially U-shape, and is disposed above the drive shaft 13 along the engine width direction. A base portion 18 c at the center is described later. The control shaft 28 is swingably supported, and one end 18 a is rotatably connected to the projecting end 19 b of the link arm 19 via the pin 23, while the other end 18 b is connected via the pin 24. The link member 20 is rotatably connected to one end portion 20a.
[0033]
Each of the link arms 19 includes an annular base 19a having a relatively large diameter and the protruding end 19b projecting at a predetermined position on the outer peripheral surface of the base 19a. A fitting hole 19c is formed in the central position of the base portion 19a so as to be fitted to the outer peripheral surface of the drive cam 15 so as to be freely rotatable. On the other hand, a pin hole 19d through which a pin 23 connected to one end 18a of the rocker arm 18 is rotatably inserted is formed in the protruding end 19b.
[0034]
Each of the link members 20 is disposed on both sides of the other end portion 18b of the rocker arm 18 and is formed in a straight line having a predetermined length as shown in FIG. 1, and the circular end portions 20a and 20b are formed on the rocker arm 18. The other end 18b and the swing cam 17 are rotatably connected via pins 24 and 26. A snap ring 31 for restricting the movement of the link arm 19 and the link member 20 in the axial direction is provided at the end of each pin 23, 24, 26.
[0035]
The variable mechanism 21 includes a control shaft 28 that is supported between the main bracket 22 a and the sub bracket 22 b of the bearing 22, and is press-fitted and fixed to the control shaft 28 in a cam hole 18 d that is provided in a base portion 18 c of the rocker arm 18. The control cam 29 is rotatably inserted into the control cam 29.
[0036]
The control cam 29 has a substantially cylindrical shape, and has an insertion hole 29a that is inserted into and fixed to the control shaft 28 in the inner axial direction. The shaft center P1 of the control cam 29 is the axis P2 of the control shaft 28. Is deviated by α.
[0037]
The control shaft 28 is controlled to rotate within a predetermined rotation angle range by an electromagnetic actuator (not shown) provided at one end, and the electromagnetic actuator is a control means for detecting the operating state of the engine. It is driven by a control signal from an external controller. The controller detects the current engine operating state based on detection signals from various sensors such as a crank angle sensor, an air flow meter, and a water temperature sensor, and outputs a control signal to the electromagnetic actuator.
[0038]
A connection switching mechanism 37 is provided between the camshaft 13 and the second swing cam 27 for appropriately connecting or releasing the connections 13 and 27. The connection switching mechanism 37 includes an operation hole 38 formed in the upper end portion of the second swing cam 27 along the direction perpendicular to the axis of the camshaft 13 as shown in FIGS. 3 and 6 to 11. A connecting hole 39, which is a sliding hole formed in a position facing the operating hole 38 at a predetermined swing position on the outer peripheral portion of the camshaft 13, and a sliding hole is accommodated in the operating hole 38. The distal end portion 40 a is mainly composed of a connecting piston 40 that can advance into the connecting hole 39.
[0039]
The connecting piston 40 is urged in the direction in which the tip end 40 a advances into the connecting hole 39 by the spring force of the coil spring 41 that is the first pressing means elastically mounted on the bottom of the operating hole 38. The whole is moved back into the operation hole 38 by the hydraulic pressure supplied through the hydraulic circuit 43 into the pressure receiving chamber 42 formed on the bottom side of the connection hole 39. Further, the outer peripheral edge of the distal end portion 40a of the connecting piston 40 and the hole edge of the connecting hole 39 are formed in a tapered shape so as to ensure good insertability into the connecting hole 39 of the connecting piston 40. Yes. Note that an air hole 44 is formed in the bottom wall portion 35 of the actuation hole 38 to ensure good slidability of the connecting piston 40.
[0040]
As shown in FIG. 5, the hydraulic circuit 43 has a hydraulic supply passage 48 with one end facing the oil pan 47 through a strainer 46, one end communicating with the downstream side of the hydraulic supply passage 48, and the other end with a pressure receiving chamber. 3 port for switching between the supply / discharge passage 49 and the drain passage 51 provided in the middle of the supply / discharge passage 49, the oil pump 50 provided in the middle of the hydraulic pressure supply passage 48, and the supply / discharge passage 49. And a two-position type electromagnetic switching valve 52. As shown in FIGS. 7, 8 </ b> A, and B, the supply / discharge passage 49 is formed along an axial hole 49 a formed in the direction of the internal axis of the drive shaft 13, and along the radial direction of the drive shaft 13 and the camshaft 14. It is comprised from the provided radial direction holes 49b and 49c.
[0041]
The electromagnetic switching valve 52 is switched based on the control signal from the controller 53 that detects the engine operating state. A pilot-type pressure regulating valve 54 that adjusts the hydraulic pressure supplied to the pressure receiving chamber 42 is provided in the hydraulic pressure supply passage 48 between the oil pump 50 and the electromagnetic switching valve 52.
[0042]
Further, as shown in FIG. 6, the second swing cam 27 is controlled to swing upward by a predetermined amount or more by a stopper mechanism 56 provided on the rocker cover 36 or the like, so that the camshaft 14 rotates forward and backward. It is regulated within the range so as to prevent a large deviation between the operating hole 38 and the connecting hole 39 due to the accompanying rotation due to the sliding frictional resistance with the camshaft 14 due to the swinging (sliding) of the first swinging cam 17. It has become. The stopper mechanism 56 includes a pressing plunger 56b that slides in a sliding hole 56a in the lower part of the rocker cover 36, and a coil spring 56c that biases the pressing plunger 56b downward. The front end of the second engaging cam 27 is engaged with the stopper groove 27d to restrict free swinging of the second swing cam 27.
[0043]
Hereinafter, the operation of this embodiment will be described. First, at the time of engine start and idling operation, the electromagnetic switching valve 52 causes the hydraulic supply passage 48 and the supply / discharge passage 49 to communicate with each other by a control signal from the controller 53. For this reason, the hydraulic pressure is supplied into the pressure receiving chamber 42 and becomes high pressure. Therefore, the entire connecting piston 40 is housed and held in the actuation hole 38 by the high hydraulic pressure in the pressure receiving chamber 42 as shown in FIGS.
[0044]
For this reason, the second rocking cam 27 is released from the connection with the camshaft 14, is in a free rocking state, and is almost in a rocking stop state. Therefore, the second valve lifter 16 is not pressed by the second swing cam 27, and the opening / closing operation of one intake valve 12 is stopped.
[0045]
On the other hand, the first rocking cam 17 rocks the rocker arm 18 by the eccentric rotation of the drive cam 15 and rocks via the link member 20, thereby pressing the valve lifter 16 by the cam face 25 and sucking the other intake air. The valve 12 is opened and closed.
[0046]
Therefore, when the intake valve 12 on one side is deactivated, the starting torque (cranking torque) by the crankshaft at the time of starting is reduced, the starting performance is improved, the intake swirl is strengthened, and combustion during idling is performed. In addition, the fuel efficiency can be improved by reducing mechanical drive loss. Further, the engine noise can be reduced by stopping the single valve.
[0047]
Thereafter, when the vehicle is started to shift to a steady operation with a low rotation and a low load and an intermediate rotation load, the switching operation of the electromagnetic switching valve 52 cuts off the communication between the hydraulic supply passage 48 and the supply / discharge passage 49. Since the supply / discharge passage 49 and the drain passage 51 communicate with each other, the hydraulic pressure in the pressure receiving chamber 42 is returned into the oil pan 47 and becomes a low pressure. Therefore, the connecting piston 40 has an operating hole 38 and a connecting hole 39 in the base circle region of the swing cam 17 in the swing trajectory of the first swing cam 17 as shown in FIGS. At the position where the coil springs 41 match each other, the tip 40a moves toward the bottom of the connecting hole 39 and moves forward to the bottom of the connecting hole 39. 38 and 39. Thus, the swing cams 17 and 27 are integrally connected to each other via the camshaft 14.
[0048]
For this reason, when the rocker arm 18 swings due to the eccentric rotational force of the drive cam 15, the second swing cam 27 also swings, and the one intake valve 12 is also opened and closed. Therefore, the opening / closing operation of the two intake valves 12, 12 can improve the output by improving the intake charging efficiency.
[0049]
Further, even when the engine is running at a high speed and a high load, the connected state of the swing cams 17 and 27 is maintained as in the low / medium speed / low / medium load range, so that the output can be improved.
[0050]
Further, at the time of the engine low speed and low load, the electromagnetic actuator is rotationally driven to one side by the control signal from the controller, and accordingly, the control shaft 28 is also rotated by a predetermined amount in the same direction, and the control cam 29 is shown in FIG. As described above, the shaft center P1 is held at the rotational position in the upper left direction from the shaft center P of the control shaft 28, and the thick portion 29b moves away from the drive shaft 13 upward. Accordingly, the entire other rocker arm 18 moves downward with respect to the drive shaft 13, and the link member 20 is pulled upward by the other end 18b. For this reason, the first swing cam 17 is forcibly slightly lifted at one end 24, while the second swing cam 27 is entirely rotated counterclockwise as shown in the figure via the cam shaft 14. Retained.
[0051]
Therefore, the rotation of the drive cam 15 causes the rocker arm 18 to swing with the control cam 29 as a swing fulcrum via the link arm 19, and the swinging force is transmitted to the swing cams 17 and 27 via the link member 20. The The rocking cams 17 and 27 are pressed or released while the base circular surface 25a, the cam surface 25b, and the cam lift portion 25c are rolling on the top surfaces 16c and 16c of the valve lifters 16 and 16, respectively. The lift amount is relatively small.
[0052]
Therefore, in such a low speed and low load region, the valve lift amount becomes small, the opening timing of each intake valve 12 becomes late, and the valve overlap with the exhaust valve becomes small. For this reason, further improvement in fuel consumption and stable rotation of the engine can be obtained.
[0053]
On the other hand, when shifting to the engine high speed and high load range, the electromagnetic actuator is rotationally driven in the other direction by a control signal from the controller. Therefore, the control shaft 28 rotates a predetermined amount clockwise (in the direction of the arrow in the figure) to rotate the control cam 29 counterclockwise by a predetermined amount from the position shown in FIG. 1, and the shaft center P1 (thick portion 29b). ) Down. For this reason, the rocker arm 18 moves in a direction away from the drive shaft 13 this time, and presses the cam nose 17a of the first rocking cam 17 downward via the link member 20, whereby both rocking cams 17 and 27 are rotated clockwise by a predetermined amount.
[0054]
Therefore, the rolling contact position of the swing cams 17 and 27 with respect to the upper surfaces of the valve lifters 16 and 16 moves to the right edge position on the cam nose portions 17a and 27a. For this reason, if the drive cam 15 rotates to swing the rocker arms 18 and 18 to swing the swing cams 17 and 17 within a predetermined range, the lift amount with respect to the valve lifters 16 and 16 increases.
[0055]
Therefore, in such a high rotation and high load region, the cam lift characteristic becomes larger than that in the low speed and low load region, the valve lift amount increases, and the opening timing of each of the intake valves 12 and 12 is advanced, while the closing timing is delayed. Become. As a result, the intake charging efficiency is improved and a sufficient output can be secured.
[0056]
Further, according to this apparatus, since the drive cam 15 and the swing cams 17 are provided coaxially on the drive shaft 13 via the cam shaft 14, the arrangement space in the engine width direction can be sufficiently reduced.
[0057]
Further, by providing the drive cam 15 and the first and second swing cams 17 and 27 coaxially with the drive shaft 13, the drive shaft 13 and the swing cams 17 and 27 are not displaced from each other. Therefore, it is possible to prevent a decrease in valve timing control accuracy.
[0058]
In addition, since the drive cam 15 is offset from each valve lifter 16 and disposed at a position where they do not interfere with each other, the outer shape of the drive cam 15 can be increased, and the degree of freedom in designing the outer peripheral surface of the drive cam 15 can be improved. This makes it possible to secure a sufficient lift amount for securing the amount of rocking of the rocking cams 17 and 27 and a sufficient cam width for reducing the driving surface pressure of the driving cam 15.
[0059]
In particular, the drive cam 15 is formed in a ring shape, and the entire outer peripheral surface is in sliding contact with the entire inner peripheral surface of the fitting hole 19c of the link arm base 19a, so that the surface pressure of the outer peripheral surface is dispersed and the surface pressure is reduced. It can be reduced sufficiently. Therefore, the occurrence of wear between the inner peripheral surfaces of the fitting holes 19c can be suppressed, and lubrication can be easily performed. Furthermore, as the surface pressure decreases, the degree of freedom in selecting the material of the drive cam 15 is improved, and a material that is easy to process and low in cost can be selected.
[0060]
In addition, since this apparatus is a so-called 6-link system as a whole, it is possible to increase the rocker ratio of the rocker arm 18, so that even if the offset amount of the drive cam 15 with respect to the drive shaft 13 is not set large. That is, even if the outer diameter of the drive cam 15 is not set large, a large swing angle of the swing cam 17 can be obtained. As a result, the overall apparatus can be further reduced in size.
[0061]
Further, since the rocker arm 18 and the first swing cam 17 are linked via the link members 20, 20, even if the rocker ratio of the rocker arms 18, 18 is set to be relatively large, the rocker arm 18 and the swing cam 17. The linkage state with is always maintained. Therefore, by obtaining a large swing angle of the swing cams 17 and 27, the ramp section θ2 of the swing cams 17 and 27 can be increased, thereby swinging with the valve lifters 16 and 16. The collision speed of the cams 17 and 27 can be reduced, and as a result, the generation of drive noise can be suppressed.
[0062]
Furthermore, since the control shaft 28 can be supported together with the bearing 22 provided between the two intake valves 12, 12, the present apparatus can be directly mounted on a conventional internal combustion engine. The shape of the cylinder head 11 does not need to be changed, and the manufacturing cost can be prevented from rising. Further, since the drive shaft 13 can also be set at the same position as the conventional one, it is not necessary to change the shape of the cylinder in this respect.
[0063]
In addition, since the present apparatus only disposes the rocker arm 18 above the drive shaft 13, the overall height can be made sufficiently low.
[0064]
12 to 17 show a second embodiment of the present invention, in which the structure of the connection switching mechanism 37 is changed.
[0065]
That is, as shown in FIGS. 12 and 13, the connection switching mechanism 37 has a long plate-like shape that extends along the axial direction of the camshaft 14 on the outer peripheral surface of the camshaft 14 on the side of the second swing cam 27. A protrusion 58, a pair of brackets 59, 59 erected on both sides of the upper end of the second swing cam 27, and a lever swingably supported by a support shaft 60 pivotally supported by the brackets 59, 59. 61, a lost motion mechanism 62 which is provided on one end 61a side of the lever 61 of the second swing cam 27 and is a first pressing means for tilting the lever 61 in one direction, and the second swing cam 27 The lever 61 is provided in a sliding hole 63 drilled along the vertical direction on the other end 61 b side of the lever 61, and the lower surface of the other end 61 b of the lever 61 is used as a pressing force and sliding hole 63 for the lost motion mechanism 62. It was loaded through the annular retainer 66. Oil pressure is supplied to the plunger 64 that is the second pressing means that pushes up against the spring force of the spring 65 and tilts in the other direction, and the pressure receiving chamber 63 a formed inside the sliding hole 63 to supply the plunger 64. And a hydraulic circuit 43 that moves forward against the spring force of the return spring 62c of the lost motion mechanism 62.
[0066]
The lever 61 has a substantially triangular side surface, and the support shaft 60 is inserted into a support hole 61c penetratingly formed along the axial direction of the camshaft 14 at the center portion. The piston 62b of the lost motion mechanism 62 is in elastic contact with the flat lower surface of the portion 61a, while the head 64a of the plunger 64 is in contact with the flat lower surface of the other end portion 61b.
[0067]
14A to 14C, the lever 61 is integrally provided with an engagement piece 67 formed by bending an elongated plate in an arc shape on one side, and one end 67a of the engagement piece 67 is provided. An engaging groove 67b is formed on the lower surface to engage with the protrusion 58 as appropriate.
[0068]
As shown in FIGS. 16 and 17, the lost motion mechanism 62 includes an operation hole 62a formed in the upper portion of the second swing cam 27 on the one end 61a side of the lever 61 along the vertical direction, and the operation hole. The piston 62b extends upward from 62a and pushes up the lower surface of the one end 61a of the lever 61, and a return spring 62c that biases the piston 62b upward.
[0069]
The plunger 64 has a spherical head portion 64 a whose upper end surface is always in contact with the lower surface of the other end portion 61 b of the lever 61 due to the relative pressure with the lost motion mechanism 62, and the lower end portion 64 b receives the hydraulic pressure in the pressure receiving chamber 65. It functions as a pressure receiving part.
[0070]
The second swing cam 27 is prevented from being tilted in the thrust direction by a thrust regulating bush 70 inserted between the central portion 14a of the camshaft 14 and the large-diameter support hole 27b. The center slit 70a is engaged with a plate-like restricting member 71 press-fitted into a rectangular hole 14e formed at one end 14d of the camshaft 14, and free rotation is restricted.
[0071]
The hydraulic circuit 44 is substantially the same as that of the first embodiment, and an axial hole 49a in which a supply / discharge passage 49 is formed in the direction of the internal axis of the drive shaft 13, the drive shaft 13 and the camshaft 14 is provided. The passage hole 49b is formed continuously in the radial direction.
[0072]
Therefore, according to this embodiment, at the time of engine start or idle operation, the hydraulic pressure supply passage 48 and the supply / discharge passage 49 are communicated with each other by a current switching valve (not shown) to supply hydraulic pressure into the pressure receiving chamber 63a. As shown in FIG. 16, 64 moves upward in the sliding hole 63. For this reason, the lever 61 and the engagement piece 67 are pushed up at the one end portions 61a and 67a against the spring force of the return spring 62c of the lost motion mechanism 62, and the engagement between the one end portion 67a and the projection 58 is released. Thus, the camshaft 14 and the second swing cam 27 are not connected to each other and are in a free state. At this time, needless to say, the second swing cam 27 is restricted from swinging more than a predetermined amount by the stopper mechanism 56.
[0073]
Therefore, the same effect as that of the first embodiment can be obtained such that the startability is improved and the fuel consumption is improved.
[0074]
On the other hand, when the engine shifts to a steady state or a high rotation / high load region, the operation of the electromagnetic switching valve causes the supply / discharge passage 46 and the drain passage to communicate with each other to discharge the hydraulic pressure in the pressure receiving chamber 65 to a low pressure. Accordingly, the plunger 64 pushes up the other end 61b of the lever 61 by the spring force of the return spring 62c of the lost motion mechanism 62 as shown in FIG. The one end portion 67a and the projection portion 58 are engaged with each other so that the camshaft 14 and the second swing cam 27 are integrally connected. As a result, the same operational effects as in the first embodiment can be obtained, such as the intake valves 12 and 12 being opened and closed to improve the engine output.
[0075]
Note that the valve timing and the valve lift can be variably controlled by changing the rocking fulcrum of the rocker arm 18 by the variable mechanism 21 according to the operating state, as in the first embodiment.
[0076]
The present invention is not limited to the configuration of each of the above embodiments. For example, the connection switching mechanism can be further different, and the configuration of the stopper mechanism can be changed. Further, the present apparatus can be applied not only to two engine valves per cylinder but also to one engine valve, and can also be applied to the exhaust valve side in addition to the intake valve.
[0077]
【The invention's effect】
As apparent from the above description, according to the present invention, the valve timing and valve lift amount of the engine valve can be variably controlled, and the drive cam and the swing cam are coaxially connected to the drive shaft via the camshaft. Since it is provided above, the arrangement space in the engine width direction can be made sufficiently small, and the rocker arm need not be extended in the engine width direction, so that the entire apparatus can be made compact. As a result, the mountability of the apparatus to the engine is improved.
[0078]
Further, by providing the swing cam coaxially with the drive shaft together with the drive cam, the shaft center of the drive shaft and the swing cam does not deviate from each other, so that the valve timing control accuracy can be prevented from being lowered.
[0079]
In addition, according to the present invention, the engine valve can be operated or stopped by connecting or releasing the swing cam by the connection switching mechanism according to the engine operating state. As a result, the starting torque can be reduced and the fuel efficiency during idling can be greatly improved.
[0080]
In addition to single valve stop, in the case of one valve type per cylinder, control such as stopping of any engine valve of each cylinder in the thinned-out state is possible, so that pumping loss can be reduced and drive loss can be achieved. The startability and fuel efficiency can be greatly improved.
[0081]
In particular, since the valve timing and valve lift can be varied by the variable mechanism, the engine performance can be greatly improved and the startability and fuel consumption can be further improved.
[Brief description of the drawings]
FIG. 1 is a view taken in the direction of an arrow A in FIG. 2 showing a first embodiment of the present invention.
FIG. 2 is a side view of an essential part of the present embodiment.
FIG. 3 is an essential part cross-sectional view of the same embodiment;
FIG. 4 is a plan view of the embodiment.
FIG. 5 is a schematic diagram showing a hydraulic circuit of the present embodiment.
FIG. 6 is a cross-sectional view showing a state where the connection between the camshaft and the second swing cam is released.
FIG. 7 is an exploded perspective view of the camshaft and the second swing cam.
8A is a cross-sectional view taken along the line A-B in FIG.
FIG. 9 is a cross-sectional view showing a state where the connection between the camshaft and the second swing cam is released.
FIG. 10 is a cross-sectional view showing a state in which the camshaft and the second swing cam are connected.
FIG. 11 is a sectional view showing a state where the camshaft and the second swing cam are connected.
FIG. 12 is a plan view partially showing a second embodiment of the present invention.
FIG. 13 is an exploded perspective view of a drive shaft, a cam shaft, and a second swing cam.
14A is a perspective view of the lever, B is a front view of the lever, and C is a bottom view of the lever. FIG.
FIG. 15 is an essential part cross-sectional view of the second embodiment;
FIG. 16 is a cross-sectional view showing a state where the connection between the camshaft and the second swing cam of the second embodiment is released.
FIG. 17 is a cross-sectional view showing a state in which the camshaft and the second swing cam of the second embodiment are connected.
FIG. 18 is a sectional view showing a conventional variable valve operating apparatus.
[Explanation of symbols]
11 ... Cylinder head
12 ... Intake valve
13 ... Drive shaft
14 ... Camshaft
15 ... Driving cam
16 ... Valve lifter
17 ... First swing cam
18 ... Rocker arm
18a ... one end
18b ... the other end
19 ... Link arm
20 ... Link member
21 ... Variable mechanism
27. Second swing cam
37. Connection switching mechanism
38 ... Hole for operation
39 ... Connecting hole
40. Connection piston
41 ... Coil spring
42 ... pressure receiving chamber

Claims (5)

A drive shaft that is rotationally driven by the crankshaft of the engine and has a drive cam fixed on the outer periphery;
A camshaft slidably provided on the outer periphery of the drive shaft;
A pair of oscillating cams provided on the camshaft, each for opening and closing two engine valves per cylinder;
A rocker arm having one end rotatably linked to the drive cam and the other end mechanically linked to the at least one swing cam;
A variable valve operating apparatus comprising a control mechanism for controlling a variable mechanism for changing a rocking fulcrum of the rocker arm according to an engine operating state,
The swing cam on one side is fixed to the camshaft, the swing cam on the other side is swingably provided, and the swing cam on the other side is connected to the camshaft according to the engine operating state. Or a variable valve operating apparatus for an internal combustion engine, characterized in that a connection switching mechanism for releasing the connection is provided. The connection switching mechanism includes an operation hole bored in a direction perpendicular to the camshaft axis on the inner peripheral portion of the other side swing cam;
A sliding hole drilled in the outer periphery of the camshaft facing the operating hole;
A connecting piston that is slidably accommodated in the operating hole, slides forward to a position straddling the operating hole and the sliding hole by the first pressing means, and connects the other-side swing cam and the camshaft; 2. A variable valve operating apparatus for an internal combustion engine according to claim 1, further comprising a second pressing means for reversing and sliding the connecting piston into the operating hole. 3. The variable valve operating apparatus for an internal combustion engine according to claim 2, wherein the first pressing means is constituted by a spring member, and the second pressing means is constituted by a hydraulic circuit. The connection switching mechanism is provided with an engagement protrusion extending in a direction perpendicular to the axis from the outer peripheral surface of the camshaft and an upper end of the other side swing cam so as to be swingable via a support shaft. A lever that can be engaged with the engaging protrusion, and a first pressing means that is provided on the other end side of the lever and presses and urges the lever in a direction to engage one end of the lever with the engaging protrusion; Provided on the outer periphery of one end of the lever on the other side swing cam, the other end of the lever is pushed up in the other direction against the pressing force of the first pressing means, and the engagement with the engaging protrusion is released. The variable valve operating apparatus for an internal combustion engine according to claim 1, further comprising: a second pressing unit that performs the operation. A restriction means is provided for restricting free swinging of the other swing cam outside the swing range of the first swing cam when the two swing cams are disconnected. 5. A variable valve operating apparatus for an internal combustion engine according to 3 or 4.

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