Patent Publication Number: US-4582029-A

Title: Valve timing control system for internal combustion engine

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     This invention relates to a valve timing control system for an internal combustion engine, and more particularly to a valve timing control system for an internal combustion engine for changing the valve timing according to the operating condition of the engine. 
     2. Description of the Prior Art 
     Generally it is preferred from the viewpoint of engine performance that the valve timing of the intake valve and/or the exhaust valve be changed according to the operating condition of the engine. For example, during operation of the engine under light load, the valve overlap, i.e., the time that both the exhaust valve and the intake valve are open, is preferred to be short to reduce the amount of residual exhaust gas, whereby stability of combustion in the engine can be ensured. Further, during operation of the engine at a low speed under heavy load, backflow of intake gas can be prevented and the volumetric efficiency can be improved by reducing the valve overlap. On the other hand, in order to improve the volumetric efficiency during heavy load high speed operation of the engine, the valve overlap is preferred to be long. 
     Thus there have been proposed various valve timing changing mechanisms for an internal combustion engine. For example, there is disclosed in Japanese Patent Publication No. 52(1977)-35819 a valve timing changing mechanism in which a planet gear associated with a centrifugal governor is interposed between the output shaft and the camshaft of the engine to change the relative position of the camshaft to the output shaft. In another valve timing changing mechanism, a three-dimensional camshaft is used as the camshaft and the three-dimensional camshaft is slid to change the valve timing. 
     However, the conventional mechanisms are disadvantageous in the they are significantly complicated in structure, are apt to produce loud noise, respond poorly and have low reliability. 
     SUMMARY OF THE INVENTION 
     In view of the foregoing observations and description, the primary object of the present invention is to provide a valve timing control system for changing the valve timing according to the operating condition of the engine which can be realized without significantly changing the structure of the conventional valve trains or valve driving system, and accordingly which is simple in structure. 
     Another object of the present invention is to provide a valve timing control system which can change the valve timing with quick response and high reliability. 
     Still another object of the present invention is to provide a valve timing control system which does not generate loud noise. 
     In accordance with the present invention, the tappet member which transmits the movement of the cam on the camshaft to the valve stem to open and close the valve is slidably received in a tappet receiving hole formed in a swinging member which can be swung about the camshaft along with the tappet member held thereby. A control device for swinging the swinging member about the camshaft is provided. When the swinging member and accordingly the tappet member held thereby are swung with respect to the camshaft and accordingly to the cam thereon, the contacting point between the cam and the tappet member at a given angular position of the camshaft is changed, whereby the valve timing can be changed. The control device swings the swinging member according to the operating condition of the engine. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a schematic plan view of a dual-induction type four-cylinder engine employing a valve timing control system in accordance with an embodiment of the present invention, 
     FIG. 2 is a fragmentary cross-sectional view of FIG. 1, 
     FIG. 3 is an enlarged perspective view of the valve timing changing mechanism employed in the valve timing control system shown in FIG. 1, 
     FIG. 4 is a fragmentary cross-sectional view showing a modification of the embodiment shown in FIG. 1, 
     FIG. 5 is a view illustrating change in the valve timing made in accordance with the present invention, 
     FIG. 6 is a schematic view of an example of a controlling system for controlling the driving motor for actuating the valve timing changing mechanism according to the operating condition of the engine, and 
     FIG. 7 is a flow chart of the operation of the microcomputer employed in the system shown in FIG. 6, 
     FIG. 8 is a schematic plan view of a four-cylinder engine having a single intake valve and a single exhaust valve for each cylinder and employing a valve timing control system of the present invention, 
     FIG. 9 is a fragmentary cross sectional view illustrating another embodiment of the present invention, and 
     FIG. 10 is an enlarged perspective view of the swinging member of the embodiment shown in FIG. 9. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     FIG. 1 shows a dual-induction type four-cylinder engine having a pair of intake ports and a pair of exhaust ports for each cylinder and employing a valve timing control system in accordance with an embodiment of the present invention. In this engine the valve timing control system is used for changing the total intake valve opening time, i.e., the time that at least one intake valve is open, according to the operating condition of the engine. 
     In order to improve the engine output by making the volumetric efficiency high, generally it is preferred that the opening time of the intake valve, i.e., the time that the intake valve opens, be longer for a given area of the intake opening when the engine operates at a high rotational speed, and especially when the engine operates at a high speed under heavy load. When the engine operates at a high speed under heavy load, combustion in the engine is not adversely affected even if the opening time of the intake valve is extended and the valve overlap is extended, since the ratio of the residual exhaust gas to the intake gas is small and backflow of the intake gas does not occur because of high inertia speed of the intake gas under such operating condition of the engine. On the other hand, when the opening time of the intake valve is extended during operation of the engine at a low speed under heavy load, backflow of the intake gas occurs since the inertia speed of the intake gas is low, whereby the volumetric efficiency is lowered. 
     Thus it is preferred that the intake valve opening time be variable according to the operating condition of the engine. In the case of an engine having a pair of intake valves for each cylinder, the intake valve opening time can be changed by changing the valve timing of at least one intake valve. For example, when the intake valves are opened in the same timing, the intake valve opening time can be extended by retarding the opening timing of one intake valve with the opening timing of the other intake valve being fixed or advanced. 
     In FIG. 1, first to fourth cylinders 2a to 2d are formed in the engine block 1 in series along the center line l of the engine block 1. Each cylinder is provided with an intake port 3a for light load, an intake port 3b for heavy load, and first and second exhaust ports 4a and 4b. As will become apparent later, the intake port 3b for heavy load is actually used only when the engine operates under heavy load, while the intake port 3a for light load is always actually used irrespective of the load under which the engine operates. The light load intake port (the intake port for light load) 3a and the heavy load intake port (the intake port for heavy load) 3b of each cylinder open in the cylinder on one side of the center line l of the engine block 1 arranged in a line substantially parallel to the center line l. The cross sectional area of the passage leading to the light load intake port 3a is narrow to increase the flow velocity of intake gas passing therethrough and at the same time the passage leading to the light load intake port 3a is curved to produce swirls in the cylinder. On the other hand, the cross sectional area of the heavy load intake port 3b is relatively large to improve the volumetric efficiency. The first and second exhaust port 4a and 4b of each cylinder open in the cylinder on the other side of the center line l of the engine block 1 arranged in a line substantially parallel to the center line l. The light load intake port 3a and the heavy load intake port 3b are respectively opposed to the first exhaust port 4a and the second exhaust port 4b. The light load intake port 3a and the heavy load intake port 3b are arranged in this order from the left as seen in FIG. 1 in the first and third cylinders 2a and 2c, and in the reverse order in the second and fourth cylinders 2b and 2d so that the heavy load intake ports 3b of the first and second cylinders 2a and 2b are adjacent to each other and the heavy load intake ports 3b of the third and fourth cylinders 2c and 2d are adjacent to each other. Similarly, the first and second exhaust ports 4a and 4b are arranged in this order from the left as seen in FIG. 1 in the first and third cylinders 2a and 2c, and in the reverse order in the second and fourth cylinders 2b and 2d so that the second exhaust ports 4b of the first and second cylinders 2a and 2b are adjacent to each other and the second exhaust ports 4b of the third and fourth cylinders 2c and 2d are adjacent to each other. 
     The light load intake port 3a, the heavy load intake port 3b, the first exhaust port 4a and the second exhaust port 4b are provided with a light load intake valve 5a, a heavy load intake valve 5b, a first exhaust valve 6a and a second exhaust valve 6b, respectively, which open and close the corresponding ports in time. 
     The passages leading to the respective heavy load intake ports 3b are provided with a valve 7 which is opened only when the engine operates under heavy load. During light load operation of the engine, intake gas is introduced into each cylinder only through the light load intake port 3a, while during heavy load operation of the engine, intake gas is introduced into each cylinder through both the light load intake port 3a and the heavy load intake port 3b with the valve 7 being opened. 
     On the intake side of the engine block 1 is disposed a first valve driving mechanism 8a for controlling the light load intake valves 5a and the heavy load intake valves 5b of the respective cylinders 2a to 2d. The first valve driving mechanism 8a includes a first camshaft 9 which extends in parallel to the center line l of the engine block 1 on the intake side thereof and is rotated by the crankshaft (not shown) of the engine. The first camshaft 9 is provided with cams 9a for timing the light load intake valves 5a of the respective cylinders 2a to 2d and cams 9b for timing the heavy load intake valves 5b of the respective cylinders 2a to 2d. The cams 9a and the cams 9b are equal to each other in shape and size so that the intake valves 5a and 5b are opened for the same time interval. 
     Similarly, on the exhaust side of the engine block 1 is disposed a second valve driving mechanism 8b  for controlling the first and second exhaust valves 6a and 6b of the respective cylinders 2a to 2d. The second valve driving mechanism 8b includes a second camshaft 10 which extends in parallel to the center line l of the engine block 1 on the exhaust side thereof, and is rotated by the crankshaft (not shown) of the engine. The second camshaft 10 is provided with cams 10a for timing the first exhaust valves 6a of the respective cylinders 2a to 2d and cams 9b for timing the second exhaust valves 6b of the respective cylinders 2a to 2d. The cams 10a and the cams 10b are equal to each other in shape and size so that the exhaust valves 6a and 6b are opened for the same time interval. 
     The movement of each cam is transmitted to the corresponding valve by way of a tappet member to open the valve when the cam lobe comes around to abut against the tappet member as is well known in the art, and the valve timing is determined by the angular position of the cam lobe with respect to the tappet member. 
     In this embodiment, the tappet member associated with the heavy load intake valve 5b and the tappet member associated with the second exhaust valve 6b are respectively supported by swinging members 14 and 14&#39; which can be swung with respect to the first and second camshafts 9 and 10, respectively. 
     As shown in FIG. 2, the movement of the cam 9b for timing the heavy load intake valve 5b is transmitted to the valve stem 30 of the heavy load intake valve 5b by way of a tappet member 13 to move downward the heavy load intake valve 5b to open the heavy load intake port 3b when the cam lobe of the cam 9b comes around to abut against the tappet member 13. The tappet member 13 is like a box in cross section and has a cam abutting face 13a adapted to abut against the cam 9b and a valve stem abutting face 13b adapted to abut against the top surface of the valve stem 30 of the heavy load intake valve 5b. The heavy load intake valve 5b is urged upward by a coil spring 31 associated with the valve stem 30 to normally close the heavy load intake port 3b. The first camshaft 9 is provided with a longitudinal oil passage 9c which extends in the longitudinal direction of the camshaft 9 and is connected to an oil pump (not shown), and with a radial oil passage 9d through which oil fed through the longitudinal oil passage 9c under pressure flows outside to lubricate the surfaces of the cam 9b and the tappet member 13. The oil lubricating the surfaces drops toward the valve stem abutting face 13b through a central hole 13c in the cam abutting face 13a and lubricates the valve stem abutting face 13b through the small holes 13d formed in the valve stem abutting face 13b near the edges. Since when the swinging member 14 is swung to change the valve timing, the valve stem abutting surface 13b slides on the valve stem 30, it is preferred that the valve stem abutting surface 13b be lubricated. 
     The box-like tappet member is advantageous in that it has a substantial thickness in the direction of the movement of the valve and accordingly the valve stem can be shorter by the amount of thickness of the tappet member, whereby the adverse influence on the valve of forces exerted on the valve in directions other than the direction of the movement of the valve can be reduced. 
     In this particular embodiment, the tappet members 13 respectively associated with the heavy load intake valves 5b which are adjacent to each other are supported by a common swinging member 14. Accordingly, the engine shown in FIG. 1 is provided with a pair of swinging members 14 for changing the timing of the heavy load intake valves, one for changing the timing of the heavy load intake valves 5b of the first and second cylinders 2a and 2b, and the other for changing the timing of the heavy load intake valves 5b of the third and fourth cylinders 2c and 2d. Similarly, the tappet members 13&#39; associated with the second exhaust valves 6b which are adjacent to each other are supported by a common swinging members 14&#39;. Thus there are provided a pair of swinging members 14&#39; for changing the timing of the second exhaust valves 6b. Since the swinging members 14 are identical to each other, only the swing member 14 for the first and second cylinders 2a and 2b will be described here. 
     As shown in FIG. 3, the swinging member 14 is formed by an upper half having a semicircular recess on the lower end thereof and a lower half having a semicircular recess on the upper end thereof which are secured together by means of bolts 16 (only one bolt 16 is visible in FIG. 3) with the first camshaft 9 being snugly received in the circular opening formed by the semicircular recesses to permit swinging movement of the swinging member 14 about the first camshaft 9. A connecting rod 17 extends through the swinging member 14 at the top thereof above the first camshaft 9. The connecting rod 17 is operatively connected to a control device 15 to swing the swinging member 14 with respect to the first camshaft 9 under the control of the control device 15 as will be described in detail hereinafter. 
     A pair of tappet receiving holes 14a are provided in the horizontal portion of the swinging member 14. The tappet member 13 associated with the heavy load intake valve 5b of the first cylinder 2a is snugly received in one of the tappet receiving holes 14a for sliding movement substantially in the axial direction of the valve stem 30, and the same associated with the heavy load intake valve 5b of the second cylinder 2b is received in the other tappet receiving hole in the same manner. 
     Said connecting rod 17 extends in parallel to the center line l of the engine block 1 to connect both the swinging members 14. The control device 15 (See also FIGS. 1 and 2) comprises a reciprocating shaft 18 which extends in perpendicular to the center line l and is engaged with the connecting rod 17 to swing the connecting rod 17 in response to the reciprocating movement thereof, and a driving motor 19 which drives the reciprocating shaft 18 in reciprocation. An output signal S1 of a rotational speed sensor 20 and an output signal S2 of a load sensor 21 are inputted into the driving motor 19 in order to control it according to the operating condition of the engine. As can be seen from FIG. 2, when the swinging member 14 and accordingly the tappet member 13 held by the swinging member 14 are swung with respect to the first camshaft 9 and the cam 9b thereon, the contacting point between the cam 9b and the tappet member 13 at a given angular position of the first camshaft 9 is changed, whereby the valve timing is changed. For example, when the swinging member 14 is swung in the rotating direction of the first camshaft 9 indicated by the arrow X in FIG. 2, the valve opening timing is retarded, and vice versa. The driving motor 19 is controlled to swing the swinging member 14 and the tappet member 13 in the direction of the arrow X to retard the opening timing of the heavy load intake valve 5b by way of the reciprocating shaft 18 and the connecting rod 17 when it is determined that the engine operates at a high speed under heavy load by way of the output signals S1 and S2. Since both the swinging members 14 associated with the heavy load intake valves 5b of the first to fourth cylinders 2a to 2d are connected to the same connecting rod 17, all the heavy load intake valves 5b are changed in valve timing by the same amount at the same time. The movement of the cam 10b for timing the second exhaust valve 6b is transmitted to the valve stem 30&#39; of the second exhaust valve 6b by way of a tappet member 13&#39; which is identical to the tappet member 13 associated with the heavy load intake valve 5b. The swinging members 14&#39; for changing the timing of the second exhaust valves 6b are identical to those for changing the timing of the heavy load intake valves 5b described above, and therefore will not be described in detail here. Components of the swinging members 14&#39; are denoted by reference numerals in brackets in FIG. 3. The connecting rod 17&#39; connecting the two swinging members 14&#39; is operatively connected to the reciprocating shaft 18 of the control device 15 so that the swinging members 14&#39; are swung in response to the reciprocating movement of the reciprocating shaft 18 together with the swinging members 14. Therefore, the heavy load intake valves 5b and the second exhaust valves 6b are changed in valve timing by the same amount in the same direction at the same time. 
     Again referring to FIG. 1, the first and second camshafts 9 and 10 are supported for rotation by bearing portions 32 which are positioned at the ends and an intermediate portion of the engine block 1 so as not to interfere with the swinging members 14 and 14&#39; and to prevent flex of the camshafts 9 and 10. 
     When the engine is operating under light load, the swinging members 14 and 14&#39; are in a normal position in which the light load intake valve 5a, the heavy load intake valve 5b, and the first and second exhaust valves 6a and 6b of each cylinder are opened and closed in a predetermined valve timing shown by solid lines in FIG. 5. That is, both the exhaust valves 6a and 6b start to open near BDC of the piston and close near TDC, while both the intake valves 5a and 5b start to open near TDC and close near BDC with the valve overlap (the time that the intake valve and the exhaust valve are both open) being kept short. Though the heavy load intake valve 5b is opened and closed during light load operation of the engine, intake gas cannot be fed through the heavy load intake port 3b since the valve 7 is closed. 
     Thus during light load operation of the engine, intake gas is introduced into each cylinder only through the light load intake port 3a. Therefore, intake gas is drawn into the cylinder at a high speed to generate a swirl therein, whereby the combustion rate in the combustion chamber can be increased to improve combustion therein. Further, the short valve overlap reduces the amount of residual exhaust gas, which contributes to improvement in combustion during light load operation of the engine. 
     When the engine is operating at a low speed under heavy load, the valve 7 in each heavy load intake port 3b is opened though the valve timing is kept as shown by the solid lines in FIG. 5, i.e., the control device 15 does not act on the swinging members 14 and 14&#39;. Thus intake gas is introduced into the cylinder through both the light load intake port 3a and the heavy load intake port 3b. However, backflow of the intake gas does not occur since the total opening time of the intake ports is still kept relatively short and the intake ports are closed comparatively earlier. Accordingly, the volumetric efficiency is highly improved during heavy load low speed operation of the engine. Further, since exhaust gas is scavenged from the cylinder through the two exhaust ports 4a and 4b in this embodiment, the scavenging efficiency is increased as compared with the case where exhaust gas is scavenged through a single exhaust port. This also contributes to improvement in the volumetric efficiency. 
     When the engine is operating at a high speed under heavy load, the valve 7 in each heavy load intake port 3b is opened and at the same time the control device 15 acts on the swinging members to swing them to retard the valve timing of the heavy load intake valve 5b and the second exhaust valve 6b as shown by chained-lines in FIG. 5. At this time, the valve timing of the light load intake valve 5a and the first exhaust valve 6a is not changed. Thus the total intake valve opening time, i.e., the time that at least one of the light load intake valve 5a and the heavy load intake valve 5b is open, is extended by the amount by which the opening timing of the heavy load intake valve 5b is retarded. This, in addition to the fact that the total intake valve opening time is extended in the direction of retardation when the inertia of the intake gas is large, highly improves the volumetric efficiency, thereby increasing the power output of the engine during heavy load high speed operation of the engine. 
     At the same time, the total exhaust valve opening time is also extended in the exhaust stroke and the scavenging efficiency is improved, which also contributes to improvement in the volumetric efficiency. Further, since the amount of intake gas is large and the inertia velocity of the intake gas is high during heavy load high speed operation of the engine, the amount of residual exhaust gas can be made small and backflow of intake gas does not occur even if the valve overlap is extended and the opening time of the intake valve is retarded into the compression stroke. Accordingly, combustion in the engine is not be adversely affected. 
     As described above, the swinging members 14 and 14&#39; are swung to change the valve timing by the driving motor 19 by way of the reciprocating shaft 18 and the connecting rods 17 and 17&#39;. Now an example of a control system for controlling the driving motor 19 will be described referring to FIGS. 6 and 7. 
     Again referring to FIG. 2, the valve stem abutting surface 13b (13&#39;b) of the tappet member 13 (13&#39;) is convex toward the valve stem 30 (30&#39;) and the center of curvature of the valve stem abutting surface 13b (13&#39;b) is on the central axis of the camshaft 9 (10). This is desirable to keep the optimal valve clearance even when the swinging member 14 (14&#39;) is swung while the valve 5b (6b) is closed. At the same time the valve stem abutting surface is preferred to have a large radius of curvature since as the radius of curvature becomes small the contact area between the valve stem abutting surface and the top surface of the valve stem becomes small and the contact pressure therebetween is increased. As is well known when the contact pressure increases, the so-called PV value, i.e., the product of the sliding velocity V between the sliding surfaces, and the contact pressure P therebetween, is increased and wear of the surfaces is increased. The box-like tappet member is preferable in this respect since it has a substantial thickness as described above and accordingly the valve stem abutting surface is remote from the central axis of the camshaft, whereby the radius of curvature of the valve stem abutting surface can be made relatively large with the center of curvature being on the central axis of the camshaft. 
     As described above, the swinging members 14 and 14&#39; are swung to change the valve timing by the driving motor 19 by way of the reciprocating shaft 18 and the connecting rods 17 and 17&#39;. Now an example of a control system for controlling the driving motor 19 will be described referring to FIGS. 6 and 7. 
     As shown in FIG. 6, the driving motor 19 is controlled by a microcomputer 40 into which the output signals S1 and S2 from the rotational speed sensor 20 and the load sensor 21 are inputted. A position sensor 41 is provided for detecting the position of the reciprocating shaft 18. The output signal S3 of the position sensor 41 is inputted into the microcomputer 40. 
     FIG. 7 shows the flow chart of the operation of the microcomputer 40. The computer 40 first determines the rotational speed R of the engine from the output signal S1 of the rotational speed sensor 20 and then determines engine load P from the output signal S2 of the load sensor 21. The microcomputer 40 has a ROM in which is stored a map representing the relationship of the target position T of the reciprocating shaft 18 to the rotational speed R and the engine load P, and the computer 40 reads out the target position T of the reciprocating shaft 18 corresponding to the rotational speed R and the engine load P determined. Then the actual position Ps of the reciprocating shaft 18 is determined from the output signal S3 of the position sensor 41. The difference D between the target position T and the actual position Ps of the reciprocating shaft 18 is calculated subsequently. When the difference D is nil, the driving motor 19 is not actuated and the reciprocating shaft 18 is held in the position. When the difference D is positive or negative the driving motor 19 is actuated to rotate in one direction or the other direction to move the reciprocating shaft 18 by an amount corresponding to the absolute value of the difference D back or forth according to the sign of the difference D. When the map stored in the ROM is appropriately arranged, the valve timing can be continuously changed with increase in load and/or rotational speed. 
     Though in the above embodiment, the movement of each cam is transmitted to each valve by way of the box-like tappet member, the tappet member may be of various other types. For example, a hydraulic tappet device as shown in FIG. 4 may be used. The hydraulic tappet device is advantageous in that it is always in contact with the cam without generating a so-called valve clearance therebetween even when the engine is operating at a high speed, and therefore the movement of the cam can be transmitted to the valve stem in an optimal manner. 
     In FIG. 4, the hydraulic tappet device 113 includes a first member 120 which has a cylindrical side wall 120a and a base wall 120b on one end of the side wall 120a and is open at the other end of thereof. The first member 120 is snugly received in the tappet receiving hole 114a formed in the swinging member 114 for sliding movement in the axial direction of the valve stem 130 with the open end directed toward the valve stem 130. A second member 121 which has a cylindrical side wall 122 having a diameter smaller than that of the first member 120 is received in the first member 120. The second member 121 is substantially H-shaped in cross section and has a partition wall 123. The partition wall 123 is provided with a central orifice 123a, the purpose of which will become apparent later. A third member 124 has a cylindrical side wall 125 and a base wall 126 at one end, and is open at the other end. The open end of the third member 124 is inserted into the open end of the first member 120 with one end of the second member 121 being received in the open end of the third member 124 so that the third member 124 can be telescopically slid in liquid-tight fashion with respect to both the first and second members 120 and 121. A coil spring 128 is compressed between the inner surface of the base wall 126 of the third member 124 and the outer surface of the partition wall 123 of the second member 121 remote from the base wall 120b of the first member 120, whereby the second member 121 is resiliently pressed against the base wall 120b of the first member 120. Between the inner surface of the base wall 120b of the first member 120 and the inner surface of the partition wall 123 of the second member 121 is formed an oil well 129. A hydraulic pressure chamber 131 is formed between the inner surface of the base wall 126 of the third member 124 and the outer surface of the partition wall 123 of the second member 121. Said central orifice 123a in the partition wall 123 communicates the oil well 129 with the hydraulic pressure chamber 131. A check valve 132 comprising a ball 133 and a coil spring 134 for urging the ball 133 against the outer surface of the partition wall 123 to close the central orifice 123a is disposed on the outer surface of the partition wall 123. The camshaft 119 having a cam 119b mounted thereon is provided with a longitudinal oil passage 140 extending in the longitudinal direction of the camshaft 119 and an annular oil passage 141 formed on the outer periphery thereof, the annular oil passage 141 being connected with the longitudinal oil passage 140 by way of a radial oil passage 142. The longitudinal oil passage 140 is connected to an oil pump (not shown). The swinging member 114 supporting the hydraulic tappet device 113 is provided with an oil passage 114b which is opposed to the annular oil passage 141 at one end and opens in a communicating opening 120c formed in the side wall 120a of the first member 120 at the other end. Oil fed through the longitudinal oil passage 140 in the camshaft 119 under pressure is introduced into the annular space 135 formed between the outer surface of the side wall 122 of the second member 121 and the inner surface of the side wall 120a of the first member 120 by way of the radial oil passage 142, the annular oil passage 141, the oil passage 114b in the swinging member 114 and the communicating opening 120c, and into the oil well 129 through a communicating passage 129a formed between the inner surface of the base wall 120b of the first member 120 and the outer end of the side wall 122 of the second member 121. Further, the oil introduced into the oil well 129 is fed to the hydraulic pressure chamber 131 under pressure through the central orifice 123a of the second member 121. The check valve 132 permits the oil to flow into the pressure chamber 131 but prevents flow of oil from the pressure chamber 131 to the oil well 129. As oil is introduced into the pressure chamber 131 the third member 124 moves away from the base wall 120b of the first member 120 to extend the overall length of the tappet device 113 and finally the outer surface of the base wall 120b of the first member 120 and the outer surface of the base wall 126 of the third member 124 abut against the cam 119b and the top surface of the valve stem 130, respectively. 
     When the cam lobe of the cam 119b comes around and the tappet device 113 is pushed downward, the tappet device 113 acts like a solid tappet member to push the valve stem 130 downward, since the oil in the pressure chamber 131 cannot escape from the chamber 131 under the action of the check valve 132. When a clearance is generated between the cam 119 and the outer surface of the base wall 120b of the first member 120, the hydraulic pressure in the pressure chamber 131 is reduced. Accordingly, oil flows into the pressure chamber 131 through the central orifice 123a to lift the first member 120 by way of the second member 121, whereby the clearance is taken up. 
     Reference numeral 143 in FIG. 4 indicates an oil passage for lubricating the surface of the cam 119 and the outer surface of the base wall 120b in contact with the cam 119. 
     Though in the embodiment shown in FIG. 1, the present invention is applied to a dual-induction type internal combustion engine in which a valve 7 is provided in the heavy load intake port so that intake gas is actually fed through the heavy load intake port only during heavy load operation of the engine, the present invention can be applied to any type of engine. For example, the valve 7 need not be provided in the heavy load intake port. The present invention may be applied even to a single cylinder-engine. 
     Further, in the above embodiment, only the timing of the heavy load intake valve is changed with the timing of the light load intake valve being fixed. However, both the intake valves may be changed in their respective timings according to the operating condition of the engine. For example, the timing of the light load intake valve may be advanced with the timing of the heavy load intake valve being retarded to further extend the total intake valve opening time during heavy load high speed operation of the engine. The valve timing may be continuously changed with change in operating condition of the engine such as the rotational speed or load. For example, when the timing of the heavy load intake valve and the second exhaust valve is gradually retarded with increase in the rotational speed of the engine, torque-shock which could occur if the total intake valve opening time is abruptly changed by a large amount can be avoided. 
     Further in the embodiment shown in FIG. 1, all the intake valves of the four cylinders are arranged on one side of the center line of the engine block and all the exhaust valves of the four cylinders are arranged on the other side of the same, and the order of the intake valves and the exhaust valves in each cylinder is arranged so that the heavy load intake valves of the first and second cylinders, and the third and fourth cylinders are positioned adjacent to each other in the respective cylinder pairs, and so that the second exhaust valves are positioned adjacent to each other in the respective cylinder pairs. This arrangement is advantageous in that the timing of the heavy load intake valves and the second exhaust valves of the two cylinders can be changed using a single swinging member without interfering with the bearing portions supporting the camshafts at three points. However, any other arrangements of the valves may be used instead. 
     Further, though in the above embodiment, the swinging members 14 and 14&#39; are normally held in the position in which valve timings shown by the solid line in FIG. 5 are given, and are moved to the position in which valve timings shown by the chained line in FIG. 5 is given during heavy load high speed operation of the engine, the swinging members 14 and 14&#39; may be normally held in the latter position to be moved to the former position during operation of the engine under other conditions. If necessary, the total intake valve opening time may instead be changed according to any other operating condition of the engine. 
     Though in the above embodiment the valve timing control system of the present invention is used for changing the total valve opening time, the valve timing control system of the present invention may, of course, be used to retard or advance the valve timing of an engine having a single intake valve and a single exhaust valve for each cylinder. The engine shown in FIG. 8 has four cylinders 2a to 2d, each of which is provided with a single intake valve 133 and a single exhaust valve 134. The intake valve 133 and the exhaust valve 134 are arranged in a line along the central axis S of the camshaft in this order as seen from the left in the second and fourth cylinders 2b and 2d and in the reverse order in the first and third cylinders 2a and 2c, so that the intake valves 133 of the first and second cylinders 2a and 2d are adjacent to each other, and those of the third and fourth cylinders 2c and 2d are adjacent to each other. The tappet members (not shown) associated with the intake valves 133 of the first and second cylinders 2a and 2b are supported by a common swinging member 135 similar to the swinging member 14 shown in FIG. 3. Similarly, the tappet members associated with the intake valves 133 of the third and fourth cylinders 2c and 2d are supported by another swinging member 135. The swinging members 135 may be driven in the manner described above. When the valve timing of the exhaust valves is to be changed, the order of the intake valve 133 and the exhaust valve 134 in each cylinder is reversed so that the exhaust valves 134 of the first and second cylinders 2a and 2b, and those of the third and fourth cylinders 2c and 2d are respectively adjacent to each other. Further, if desired, each intake valve 133 (each exhaust valve 134) may be supported by a separate swinging member 135. 
     In the embodiment described above, the swinging members 14 and 14&#39; are suspended from the camshafts 9 and 10. However, the swinging members may be supported on the engine block as shown in FIGS. 9 and 10. 
     In FIGS. 9 and 10, the engine block 1 is provided with an arcuate guide surface 1a having its center of curvature on the central axis of the camshaft 149. The swinging member 144 comprises a horizontal portion 145 which is semicylindrical in cross section and an annular vertical portion 146 vertically extending from the horizontal portion 145 at the center thereof. The horizontal portion 145 is provided with a pair of tappet receiving holes 145a on opposite sides of the vertical portion 146. The outer surface 145b of the horizontal portion 145 has a curvature conforming to the guide surface 1a of the engine block 1. The vertical portion 146 is provided with a camshaft receiving bore 146a and sector gear 146b. The swinging member 144 is supported on the engine block 1 with the outer surface 145b of the horizontal portion 145 being in contact with the guide surface 1a of the engine block 1 and the camshaft receiving bore 146a of the vertical portion 146 receiving therein the camshaft 149. A tappet member 147 is snugly received in each tappet receiving hole 145a to transmit the movement of the cam 149a on the camshaft 149 to the valve stem 148. The control device 155 comprises a gear 150 fixed to a rotational shaft 151 and meshed with the sector gear 146b on the vertical portion 146, and a driving motor (not shown) for rotates the gear 150 by way of the rotational shaft 151. When the gear 150 is driven by the driving motor, the swinging member 144 is swung or rotated about the camshaft 149 by way of the engagement between the gear 150 and the sector gear 146b guided by the guide surface 1a of the engine block 1, whereby the relative position of the tappet member 147 to the cam 149a at a given angular position of the camshaft 149 is changed and the valve timing is changed. 
     As can be seen from FIG. 9, the tappet member 147 in this embodiment is in the form of a cylindrical member which has a thickened bottom wall 147a and a cylindrical side wall 147b and opens at one end. The outer surface of the bottom wall forms the cam abutting surface and the inner surface of the same forms the valve stem abutting surface, the valve stem 148 extending into the side wall 147b to abut against the inner surface of the bottom wall 147a. The inner surface of the bottom wall is curved and the center of curvature is on the central axis of the camshaft 149 for the reason described above in conjunction with the box-like tappet member shown in FIG. 2. The tappet member 147 is further provided with an oil hole 147c extending through the bottom wall 147a. Oil discharged from the oil passage 149b formed in the camshaft 149 flows to the inner surface of the bottom wall 147a to lubricate the surface in contact with the valve stem 148.