GB2229248A - Phase change mechanism - Google Patents

Abstract

A phase change mechanism for a camshaft of an internal combustion engine comprises a drive member 14 to be connected to the camshaft drive train, a driven member 12 to be connected to the camshaft, a coupling disc 20 interposed between the drive and driven members, sliders 24 connecting the coupling disc 20 for rotation with one of the drive and driven members 12, 14 and permitting the coupling disc 20 to slide along a slide axis perpendicular to the rotational axis of the mechanism, first cranking means 36 connecting the coupling disc 20 to the other of the members 12, 14 to cause the relative phase of the members to vary upon movement of the coupling disc 20 along the slide axis and a reaction member 50 connected to the coupling disc 20 by a second cranking means 44 to cause the coupling disc 20 to slide along the slide axis upon application of a torque to vary the speed of rotation of the reaction member 50 relative to the drive and driven members 12, 14. As shown braking means 52 are provided to apply a braking force to the reaction member 50 and detents 60 retain the reaction member in two stable positions. Sensing means 62, which determines the prevailing setting of the phase angle, controls operation of the braking means. <IMAGE>

Description

PHASE CHANGE MECHANISM The invention relates to a phase change mechanism f

or varying the phase of a driven member relative to a drive member. The invention can be used for the camshaft of an internal combustion engine and in particular to varying the relative phase of opening and closing of the inlet and exhaust valves in a dual overhead camshaft internal combustion engine.

is The optimum times for opening and closing the inlet and exhaust valves in an internal combustion engine vary, inter alia, with engine load and speed. In any engine with fixed angles for opening and closing the valves for all engine operating conditions, the valve timing is a compromise which detracts from the engine efficiency in all but a limited range of operating conditions. For this reason, control systems have been proposed which vary the valve timing during engine operation.

Most of the prior art proposals employ a linear actuator to set the desired phase shift and they rely on converting the linear movement of the actuator into a rotary movement of the camshaft relative to its drive pulley or gear. One such example has been to include a helical gear on the camshaft and to move the helical gear axially to cause the phase of the camshaft 'to change.

Phase change mechanisms which convert linear actuation movement into an angular phase shift have certain disadvantages which have prevented their being generally adopted in engine designs intended for mass production. Their space requirements are difficult to satisfy and even more serious problems were presented by the cost, complexity and size of the linear actuating system which they require.

Most previous attempts at actuation have required an external power source. Amongst the proposed sources of force for actuating the phase change mechanism have been electro-mechanical actuators (motors or solenoids), or hydraulic actuators. One complexity resulting from such designs is that supplying current or hydraulic fluid to a rotating actuator is troublesome. If the prime mover is stationarily mounted, then this problem is avoided but creates a new problem in how to couple the force from the prime mover to the phase change mechanism. All such proposals also involve friction losses, exacerbate the packaging problem and add to the manufacturing cost.

To mitigate the foregoing problems, there has been 15 described in copending Patent Application No. 8824612.9 an actuating system for a phase change mechanism which phase change mechanism comprises a rotatable phase change assembly and an actuator operative to rotate at the same speed as the assembly when the phase between a drive and a driven member is to be maintained constant and which is required to be rotated relative to the phase change assembly to bring about a change in phase, wherein the actuating system comprises a reaction member coupled to the actuator and braking means associated with the reaction member, and wherein the reaction member when not braked is free to rotate with the phase change mechanism, and when braked serves to vary the speed of the actuator relative to speed of the phase change mechanism.

Whereas prior art attempts at adjusting the position of the actuator have employed external active sources of power, the invention in the above application relies on the use of the rotation of the phase change mechanism to bring about the desired operation of the actuator, the only external force required being friction.

The preferred embodiment described in the above application enables continuous control over the phase change over a large range and though this is required for some complex applications, in simpler applications a two position control is quite adequate.

The present invention is concerned with a phase change mechanism, intended to be controlled by an actuating system as set forth in the co- pending Patent Application No. 8824612.9 and which allows two position control to be achieved simply and inexpensively.

According to the present invention, there is provided a phase change mechanism for a camshaft of an internal combustion engine, comprising a drive member to be connected to the camshaft drive train, a driven member to be connected to the camshaft, a coupling disc interposed between the drive and driven members, slider means connecting the coupling disc for rotation with one of the drive and driven members and permitting the coupling disc to slide along a slide axis perpendicular to the rotational axis of the mechanism, first cranking means connecting the coupling disc to the other of the members to cause the relative phase of the members to vary upon movement of the coupling disc along the slide axis and a reaction member connected to the coupling disc by a second cranking mechanism to cause the coupling disc to slide along the slide axis upon application of a torque to vary the speed of rotation of the reaction member relative to the drive and driven members.

If no torque is applied to the reaction member, there will be a torque reaction from the resistance of the valve train tending to act on the second cranking mechanism and the magnitude of the torque reaction will depend upon the angle of the second cranking means relative to the slide axis. However, when the second - 4 cranking means lie on the slide axis, there will be no torque reaction and therefore there are two stable positions in which negligible torque is experienced by the reaction member. A small detent engageable by a spring would suffice to hold the reaction member in either of its two stable positions. In both these position, the phase change mechanism will be solid and will introduce no free play into the camshaft drive train.

An important advantage of the mechanism is that as the reaction member is rotated in the same direction, the phase change will cycle between its two stable positions. consequently, separate actuators are not required for advancing and retarding the phase.

Electrical, magnetic, mechanical, optical or other sensing means may be provided to determine when the reaction member is in one, of the stable positions and which of the two stable positions. A brake band associated with the reaction member can then be operated until such time as it is determined that the phase change mechanism has reached the desired stable position.

C The invention will now be described further, by way of example,-with reference to the accompanying drawings,'in which:

Fig. 1 is a longitudinal schematic section through a phase change mechanism of the invention taken along the line I-I in Fig. 3, Fig. 2 is a similar longitudinal schematic section taken along the line II-II in Fig. 3, and Fig. 3 is a transverse section taken along the line III-III in Fig. 1.

A camshaft 10 has mounted on its end the back plate 12 or driven member of a phase change mechanism. A cog 14 is journalled about the back plate 12 and is connected to a front cover plate 16 of the phase change mechanism. The camshaft 10 is concentric with both the front plate 16 and the back plate 12 of the phase change mechanism but is fast in rotation only with the back plate 12.

A coupling disc 20 is sandwiched between the front plate 16 and the back plate 12 and is coupled to both of these in order to transmit torque from the front plate 16 to the back plate 12. on its side facing the front plate 16, the coupling disc 20 has a guide groove 22 in which two slide blocks 24 are received. The slide blocks 24 are in turn connected to pins 26 which are fixed to the front plate. In this way, torque can be transmitted from the front plate 16 to the coupling disc 20 but the latter may move into an eccentric position relative to the rotational axis of the camshaft 10 along the slide axis of the guide groove 22.

A similar arrangement connects the coupling disc 20 to the back plate 12. The side of the coupling disc 20 facing the back plate 12 is formed with a second guide groove 32 which receives a single slide block 34 rotatably connected by a pin 36 to the back plate 12. The two grooves 22 and 32 in the coupling disc 20 are transverse to one another and preferably mutually orthogonal. The single slide block 34 acts as a crank connecting the coupling disc 20 for rotation with the back plate but permitting both displacement of the coupling disc 20 to an off-centre position and slight rotation of the coupling disc relative to the back plate 12.

If the coupling disc 20 is moved by some external agency along the slide axis of the groove 22 (see Figure 3), it will act on the pin 36 to crank the camshaft, causing - 6 a phase change to be introduced between the f ront and back plates-16 and 12. The angle of phase shift about the camshaft axis is designated by 0 in the drawing and is given by the equation:

vertical displacement crank radius To enable the coupling disc to be moved along the groove 22, a second groove 38 is formed in the side of the coupling disc 20 facing the front plate 16 and extending at right angles to the groove 22. A large slide block 40 is arranged in the groove 38 and is formed with a cylindrical aperture 42 within which there is received an eccentric circular cam 44 formed integrally with a hollow shaft 46 journalled at its ends in the front and back plates 16 and 12.

A braking disc 50 associated with a brake band 52 is keyed onto the end of the hollow shaft 46 and a bolt 18 passing through the centre of the hollow shaft 46 serves to retain the braking disc on the hollow shaft and to secure the phase change mechanism to the camshaft 10.

In the absence of the application of a braking force to the disc 50 the only forces acting on the coupling disc 20 are the reaction torque resulting from the resistance of the valve train. This torque is totally resisted in the two positions in which the lobe of the cam 44 is aligned with the axis of the groove 22. These two are therefore stable positions when negligible effort is required to retain the coupling disc stationary in relation to the front and back plates 16 and 12. Spring biased detents 60 shown in Figure 2 serve to locate the braking disc 50, which is fixed relative to the cam 44, in these two positions.

0 Having now defined a mechanism with only two stable angles of relative phase shift, it remains only to describe how one or other of these two positions may be selected.

Considerable torque is required to rotate the camshaft of an engine and to do so rapidly has hitherto required the expending of considerable effort. In the described embodiment, the necessary torque is derived from the rotation of the camshaft itself. A braking force is applied to the braking disc 50 by the brake band 52 (a brake calliper may alternatively be employed). This causes the disc 50 to slow down relative to the phase change mechanism and therefore rotate the cam 44 to move the coupling disc. on reaching the new stable position, the brake is released and once again all the components of the phase change mechanism rotate in unison. If full braking is applied, the entire phase-change can be brought about in one half of a rotation of the camshaft but a more gradual and better controlled change-over takes place if the disc 50 is braked more gently.

It can be seen that continuous rotation of the cam 44 in the same direction will result in the phase being cyclically advanced and retarded. There is no requirement for reversal of the direption of relative notion of the braking disc and continued braking will achieve both advance and retard of the phase angle.

Any of a variety of means may be used to determine the prevailing setting of the phase angle, to permit feedback for the control of the braking. In the embodiment illustrated, two magnets 62 and 64 of opposite polarity are fitted to the pins 26 and a hole 68 in the braking disc 50 allows a sensor 66 to determine the polarity of the magnets align with the hole. of course, electrical contacts or other forms of transducer may be used to achieve the same result.

The phase change mechanism is a bistable device with the same operation required for switching from either state to the other. The change operation requires the application of a braking force to the brake disc and removal of the braking force when the other stable state has been detected.

The total amount of phase change, corresponding to twice the angle 0 in the drawing, depends on the cranking radius of pin 36 and on the eccentricity of the cam 44. The former parameter cannot readily be changed and in any event contributes relatively little to the phase angle. on the other hand, it is a relatively simple matter to substitute for the cam 44 one with different eccentricity and this allows considerable economies in production to be achieved since the only component that needs to be changed in the phase change mechanism to permit it to suit a wide range of applications is the can 44.

Because of the resemblance between the phase change mechanism and a socalled Oldham coupling, it is inherently tolerant of misalignment between the various rotating components. The tolerance in the manufacture of the individual components is not critical and for smooth quiet operation, it is only important that the various slide blocks should fit their respective groves with accuracy. Even there, because of the little relative movement that occurs in use, nylon bearing surfaces may be used to achieve long term reliability.

As described above, the phase change mechanism is mounted on the end of the camshaft, but it is alternatively possible for it to be mounted on the crankshaft. In this case, the phase of both camshafts would be altered at the same time. This may be desirable for certain applications, such as control of exhaust gas recirculation.

1 - 9 f It is further possible to provide phase change mechanisms both on the camshafts and the crankshaft to afford a greater degree of control.

1

Claims (6)

1. A phase change mechanism for a camshaft of an internal combustion engine, comprising a drive member to be connected to the camshaft drive train, a driven member to be connected to the camshaft, a coupling disc interposed between the drive and driven members, slider means connecting the coupling disc for rotation with one of the drive and driven members and permitting the coupling disc to slide along a slide axis perpendicular to the rotational axis of the mechanism, first cranking means connecting the coupling disc to the other of the members to cause the relative phase of the members to vary upon movement of the coupling disc along the slide axis and a reaction member connected to the coupling disc by a second cranking mechanism to cause the coupling disc to slide along the slide axis upon application of a torque to vary the speed of rotation of the reaction member relative to the drive and driven members.

2. A phase change mechanism as claimed in claim 1, further comprising braking means for applying a braking force to the reaction member.

3. A phase change mechanism as claimed in claim 1 or claim 2, wherein detent means. are provided for retaining the reaction member in two stable positions.

4. A phase change mechanism as claimed in claim 3, further comprising sensing means for determining the. position of the coupling disc relative to the drive and driven members.

5. A phase change mechanism as claimed in claim 4, wherein the sensing means fdrms part of a control loop for releasing the braking force applied to the reaction member when the coupling disc is near a stable position.

11 -

6. A phase change mechanism constructed arranged and adapted to operate substantially as herein described with reference to and as illustrated in the accompanying drawings.

1 Published 1990 at 7nePatentOtrice, State House. 6671 High Holborn. London WC1R4TP.Purther copies maybe obtained from The Patent Office flales Branch, St Mary Cray. Orpiffigton, Kent BR5 3RD. PrInted by Multiplex tecbxjques 1UL St MLry Cray, Kent, Con. V87