This patent application claims priority to PCT application number PCT/IB2011/050391, filed on Jan. 28, 2011.
The present invention relates to a valve mechanism for a cylinder of an internal combustion engine, comprising two gas exchange poppet valves mounted in a cylinder head, a bridge acting on the two valves, a cam for actuating the two valves, a slider movable by the cam and slidable relative to the bridge, and a hydraulically controlled locking system having a latched position in which the slider transmits the force of the cam to the bridge to actuate the two valves and a released position in which the valves are deactivated and the slider slides freely relative to the bridge.
A valve mechanism as set out above is known from JP-2004360485. In this prior art reference, a post with an oil passageway projects from the cylinder head. A bridge assembly straddling the stems of the two poppet valves includes a cylinder housing. The post which projects from the cylinder head passes through a hole in the lower end of the cylinder and guides the bridge assembly to slide parallel to the post and to the valve stems. An annular piston, which serves the purpose of the slider mentioned above, is disposed within the cylinder and is moved by the cam that operates the two valves. The outer wall of the piston seals against and slides relative to the inner wall of the cylinder and its inner wall seals against and slides relative to the outer wall of the post. A working chamber is defined within the piston that receives hydraulic fluid (engine oil) through the passageway in the post. The pressure in the working chamber operates a locking system which selectively locks the piston to the bridge.
In this way, when the piston is locked to the bridge the valves are opened and closed by the cam whereas when the locking system is released, the annular piston moves with the cam but is uncoupled from the bridge so that the valves remain stationary. This allows the valves to be deactivated hydraulically.
To maintain the annular piston in contact with the cam and the bridge in contact with the valve stems, a spring is housed within the cylinder, surrounding the post, to urge the piston and the cylinder apart.
The present invention recognises certain problems with such a construction. In order to be able to push the piston against the cam and prevent the bridge from lifting off the poppet valves the spring needs to be fairly substantial. A first problem in meeting this requirement is that of space. The maximum dimensions of the cylinder in the bridge assembly are determined by the limited space between the poppet valves and it is difficult to provide enough space in the cylinder to accommodate a spring of the size required. Furthermore, if a large spring is used and the bridge assembly is somehow enlarged to accommodate it, then this results in a significant increase in the inertial mass of the bridge assembly and larger valve springs are then required to cope with this increased mass that the valves have to lift as they close.
With a view to mitigating the foregoing disadvantages, the present invention provides a valve mechanism for a cylinder of an internal combustion engine, comprising two gas exchange poppet valves mounted in a cylinder head, a bridge acting on the two valves, a cam for actuating the two valves, a slider movable by the cam and slidable relative to the bridge, and a hydraulically controlled locking system having a latched position in which the slider transmits the force of the cam to the bridge to actuate the two valves and a released position in which the valves are deactivated and the slider slides freely relative to the bridge, wherein the slider is urged towards the cam by a spring acting between the slider and the cylinder head.
Preferably the slider is supported by the cylinder head for movement towards and away from the cam.
A further problem encountered by JP-2004360485 is that a pressure relief is required to limit the pressure in the working chamber and during normal operation the volume of the working chamber is constantly changing and work is done to pump oil in any out of the working chamber.
In a preferred embodiment of the present invention, the support in the cylinder head for the slider includes an oil passageway for pressurising the locking mechanism which is only open when the slider is aligned with the base circle of the cam. Thus the state of the locking system can only be changed during minimum valve lift but the volume of the working chamber remains constant during the reciprocation of the slider.
Because the spring in the present invention acts between the cylinder head and the slider, it cannot itself ensure that the bridge remain in contact with the valves at all times. It is therefore convenient for clips to be provided for securing the bridge to the ends of the poppet valves.
It is sometimes desirable to be able to open one of the valves in a pair independently of the other using a separate mechanism. This may be achieved by arranging for the stem of one of the poppet valves to project through a hole in the bridge.
In the latter case, the poppet valve of which the stem projects through the hole in the bridge may preferably be connected to the bridge by a spring biased lost motion coupling.
The invention will now be described further, by way of example, with reference to the accompanying drawings, in which:
In
This is achieved by substituting for the bridge 20 a bridge assembly 120 as shown in
A locking mechanism 126 housed in the bridge piece 122 is used to lock the bridge piece 122 for movement with the slider 124. In a latched position of the locking mechanism 126, the bridge piece and the slider 124 move in unison and the valves are operated in the usual manner, whereas in a released position of the locking mechanism 126 the slider 124 is free to slide relative to the bridge piece 122 so that the valves 10,12 can remain closed as the rocker 18 moves up and down.
The locking mechanism in the embodiment of
Pressure medium is supplied to the locking mechanism 126 to activate and deactivate the valves 10 and 12, by way of a hollow tube 130 that is secured to and moves with the slider 124 and which moves relative to and sealingly engages a hollow pedestal 132. The pedestal 132 is securely located relative to the engine cylinder head and communicates with an oil passageway in the cylinder head. A spring 134 acts to force the pedestal 132 against a locating formation (not shown) in the cylinder head and to push the slider 124 against the rocker 18.
The lower end, as viewed, of the tube 130 is closed off by a blanking screw 136. Near its lower end, the tube 130 has a holes 138 which admit a hydraulic fluid, usually engine oil, into the tube 130 from passages 140 formed in the pedestal 132. Thus oil can be supplied to and discharged from the locking mechanism 126 when the slider 124 is in the position illustrated but as soon as the slider 124 is pushed down by the cam 14, the locking mechanism is hydraulically isolated. The state of the locking mechanism 126 can thus only be changed when the slider is in the illustrated position, that is to say when the cam follower 16 is on the base circle of the cam 14 (minimum lift).
The spring 134 always urges the slider 124 against the rocker 18 but additional steps need to be taken to maintain the bridge piece 122 in contact with the ends of the poppet valves. This is achieved in the embodiments of the
To set the locking mechanism 126 in the position illustrated in
When the roller follower 16 next moves onto the ramp of the cam 14 the downward movement of the slider 124 relative to the pedestal 132 isolates the working chambers of the hydraulic locking mechanism from the passages 140 and the locking mechanism remains in the locked position. The movement of the slider 124 is therefore transmitted to the bridge piece 122 and the valve 10, 12.
Deactivation cannot now take place until the valves are once again fully closed and the cam is in the minimum lift position shown in
The embodiment of
The lower of the spring 130 always rest on the cylinder head and it does not form part of the mass of the bridge assembly that moves with the valves. As such, when the locking mechanism is engaged, the valve springs do not have to perform additional work to displace the centre of mass of the spring and on the contrary the spring 134 assists the valve springs in raising the weight of the bridge assembly. There is furthermore nothing to preclude the use of a spring that is comparable in strength and mass with one of the valve springs, thereby ensuring that the slider is at all times urged firmly towards the rocker 18.
There are occasions when it is desired to override the cam operation of one of the two valves and maintain it permanently open by operation of a separate actuator. In the modification shown in
This lost motion coupling between the valve and the bridge would, on its own, allow the bridge piece to lift off the valve stem. To prevent such separation from occurring, the bridge piece 222 is urged down against the shoulder on the valve stem by a spring 230 that acts between the bridge piece 222 and a circlip 232 secured to the stem of the valve 10′.
Number | Date | Country | Kind |
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1003389.2 | Mar 2010 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/IB2011/050391 | 1/28/2011 | WO | 00 | 12/4/2012 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2011/107891 | 9/9/2011 | WO | A |
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8210144 | Langewisch | Jul 2012 | B2 |
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Number | Date | Country | |
---|---|---|---|
20130098319 A1 | Apr 2013 | US |