EP0761936A2 - Actuating unit for an adjusting device, preferably for a valve lift adjusting device of internal combustion engines - Google Patents

Abstract

An actuator for a valve stroke adjusting device in a vehicle has a pressure relieving tank connection (12), and a pressurised tank connection (13) which is fitted with a pressure limiting valve (15). The pressure relieving tank connection is connected to the operating joint (11), as the valve piston (8) slides until just before the end position, and in the end position the operating connection is connected to the pressurised tank connection. The valve piston has a circular plug, which separates the pressure relieving connection from the operating connection.

Description

The invention relates to an actuation unit for an adjustment device, preferably for a valve lift adjustment device of motor vehicles, according to the preamble of claim 1.

In valve lift adjustment devices of motor vehicles, it is known to use a bolt as the coupling element, which, if necessary, is displaced hydraulically in such a way that an adjusting element forming a fixed component, which is assigned to a second cam of the camshaft, is coupled to a control element. As a result of the second cam, the corresponding valve lifter of the motor vehicle performs a modified stroke, as a result of which the opening cross section is changed, so that a particularly metered amount of the fuel-air mixture can flow into the cylinder space of the engine. So that the coupling element is displaced, the hydraulic medium must be pressurized by means of a pump. There is a brief drop in pressure within the system until the pump has built up the required hydraulic pressure. Then there is a risk that the coupling element is not pushed far enough into the locking hole and there is frequent wear on the bolt edge with increased surface pressure and increased wear.

The invention has for its object to design the generic actuating unit so that the coupling element is suddenly moved into its coupling position, without the risk that there is power transmission on a narrow edge area of the coupling element.

This object is achieved according to the invention in the generic actuating unit with the characterizing features of claim 1.

The actuation unit according to the invention has two tank connections, one of which is pressure-relieved and the other is pressure-loaded. When moving the valve piston, the hydraulic medium is discharged via the pressure-relieved tank connection until shortly before the end position is reached, since it is connected to the work connection. The hydraulic medium can be displaced quickly in this way. The pressure relief valve of the pressure-loaded tank connection ensures that a residual pressure determined by the pressure relief valve remains in the entire system, thereby reliably preventing the system from running dry. If the coupling process is to be triggered, a correspondingly large amount of hydraulic medium can thus be made available suddenly, so that a drop in pressure at the start of the coupling process is reliably avoided. The coupling element is therefore suddenly moved into its coupling position. It doesn't happen a power transmission on a narrow edge area of the coupling element.

Further features of the invention result from the further claims, the description and the drawings.

Fig. 1

im Axialschnitt eine als Ventil ausgebildete erfindungsgemäße Betätigungseinheit,

Fig. 2

im Schnitt und in schematischer Darstellung eine Ventilhubverstelleinrichtung, die durch die Betätigungseinheit gemäß Fig. 1 betätigt wird,

Fig. 3

im Axialschnitt eine zweite Ausführungsform einer erfindungsgemäßen Betätigungseinheit.

The invention is explained in more detail using two exemplary embodiments shown in the drawings. Show it

Fig. 1

in axial section an actuating unit according to the invention designed as a valve,

Fig. 2

in section and in a schematic representation a valve lift adjustment device which is actuated by the actuation unit according to FIG. 1,

Fig. 3

in axial section a second embodiment of an actuating unit according to the invention.

The actuation unit is preferably provided for the valve lift adjustment of motor vehicles. In such valve lift adjustment devices, cams of a camshaft interact with rocker arms or hydraulic cups as control elements, which act directly on the respective valve tappet. The valves are opened and closed controlled by the corresponding cams. In addition, the actuation unit can be used in the low-pressure range in systems with residual pressure.

FIG. 2 schematically shows a valve lift adjustment device which is operated with the actuation unit according to FIG. 1 becomes. A coupling element 1 designed as a piston is slidably mounted in a fixed component 2. A movable component 3 is provided adjacent to this, in which a piston 4 is slidably mounted. It is under the force of at least one compression spring 5 or a hydraulic pressure.

In order to couple the two components 2 and 3 to one another, the coupling element 1 is acted upon hydraulically, as a result of which it is shifted to the right in FIG. 2 and pushes the piston 4 back against the force of the spring 5. The coupling element 1 is displaced until it engages in a bore 6 receiving the piston 4. Then both parts are positively connected to one another transversely to the axis of the coupling element 1 and the piston 4.

The actuating unit according to FIG. 1 is used for hydraulic loading of the coupling element 1. It is designed as a switching valve and has a housing 7 in which a valve piston 8 is displaceably mounted. It is slidably mounted in a bore 9 into which a pressure connection 10, a working connection 11, a pressure-relieved tank connection 12 and a pressure-loaded tank connection 13 open. The working connection 11 is connected to the pressure connection 10 via a throttle point 14. The diameter play of the valve piston 8 in the bore 9 could also be used as the throttle point 14a. In this case, the throttle point 14 would not be required. As a result of the diameter play, the hydraulic medium could also get from the pressure connection 10 to the working connection 11. The pressure-loaded tank connection 13 is closed against the tank (not shown) by a pressure relief valve 15 which opens in the direction of the tank.

The valve piston 8 can be axially displaced by a plunger 16 of an electromagnet 26 against the force of at least one spring 18 in the bore 9. The valve piston 8 has two annular grooves 20 and 21 which are separated from one another by an annular web 19. The annular groove 20 is connected by a radial bore 22 to a bore 23 axially penetrating the valve piston 8. These bores 22 and 23 serve to hydraulically relieve the space 24 and 25 located in front of and behind the valve piston 8. The resulting leakage oil is discharged via the bores 22, 23, the annular groove 21 and the tank connections 12 and 13.

In Fig. 1 the valve piston 8 is shown in the upper half in its open position, in which the electromagnet 26 is energized and the plunger 16 is extended, so that the valve piston 8 is displaced against the force of the compression spring 18. The pressure connection 10 and the working connection 11 are connected to the annular groove 20, while the working connection 11 is separated from the pressure-relieved tank connection 12 and from the pressure-loaded tank connection 13 by the ring web 19 of the valve piston 8. The working connection 11 is also connected to the pressure connection 10 via the throttle point 14.

In the lower half of FIG. 1, the valve piston 8 is shown in its closed position, in which the electromagnet 26 is not energized. The plunger 16 is retracted while the valve piston 8 has been pushed back into its closed position by the force of the spring 18. In this switching position, the working connection 11 is connected to the pressure-loaded tank connection 13 via the annular groove 21. The hydraulic medium can in this closed position via the throttle 14 from the work connection 11 get into the pressure port 10. This measure prevents the system from idling while the engine is running. This compensates for leaks, for example caused by lubrication points. From the working connection 11, the hydraulic medium can flow back to the tank via the annular groove 21 of the valve piston 8 and the tank connection 13.

A working line 30 (FIG. 2) of the fixed component 2 is connected to the working connection 11, so that the coupling element 1 is also under this prestressing pressure of the hydraulic medium. However, this pressure is less than the counterforce exerted by the compression spring on the piston 4 and thus on the coupling element 1. As a result, the coupling element 1 remains in its stop position shown in FIG. 2, in which it bears against the bottom 31 of a bore 32 which receives the coupling element.

The valve piston 8 has at its end facing the compression spring 18 a further annular web 27 which, together with the annular web 19, axially delimits the annular groove 21. In the closed position of the valve piston 8 (lower half in FIG. 1), the ring web 27 closes the pressure-relieved tank connection 12. In the open position (upper half in FIG. 1), the tank connection 12 is only partially closed by the ring web 27. When the valve piston 8 moves back from the open position into the closed position, the hydraulic medium is displaced freely via the pressure-relieved tank connection 12 until the valve piston 8 has almost completely reached its end position (lower half in FIG. 1). Only then is the pressure-relieved tank connection 12 separated from the annular groove 21 by the ring web 27, while the pressure-loaded one Tank connection 13 is connected via the annular groove 21 to the working connection 11.

Since the hydraulic medium is displaced freely when returning via the pressure-relieved tank connection 12, the valve piston 8 can be reliably moved back into its closed position by the compression spring 18, in which it separates the pressure connection 10 from the working connection 11 with its annular web 19.

For damping during the switching process, the valve piston 8 has an axially penetrating end bore 28, which acts as a throttle point and is designed as a nozzle. It opens into the central axial bore 23. The throttle point 28 can of course be of any other suitable design, for example formed by reducing the diameter of the bore 23.

The two ring webs 19 and 27 of the valve piston 8 form control edges 33, 34 and 35 which interact with corresponding control edges 33a to 35a of the housing 7. These control edges 33a to 35a are provided on the working connection 11 and on the pressure-relieved tank connection 12. The control edges 33 to 35 and 33a to 35a are designed with respect to one another in such a way that the overlap is very slight and is therefore referred to as a zero cut.

If the valve piston 8 is in its closed position (lower half in FIG. 1), then the working connection 11 is connected to the pressure-loaded tank connection 13 via the annular groove 21. The pressure relief valve 15 ensures that the entire system even in this non-switched state of the actuating unit has corresponding residual pressure. This prevents the system from running dry in the closed position of the valve piston 8.

When the valve piston 8 moves back from the open position (upper half in FIG. 1) to the closed position (lower half in FIG. 1), the hydraulic medium is discharged to the tank via the pressure-relieved tank connection 12, while the pressure-loaded tank connection 13 remains closed as a result of the pressure relief valve 15 . Shortly before the valve piston 8 reaches its closed position, the pressure-relieved tank connection 12 is closed. The pressurized hydraulic medium is then discharged at the end of the displacement of the valve piston 8 via the pressure-loaded tank connection 13, as long as the pressure of the hydraulic medium is greater than the pressure determined by the pressure relief valve 15.

If the valve piston 8 is pushed back into its open position by the tappet 16, the annular web 27 releases the pressure-relieved tank connection 12 after the shortest displacement path, so that the hydraulic medium can be discharged to the tank immediately via this tank connection 12. In the end position, the ring web 19 then separates the working connection 11 from the tank connection 12.

In the embodiment according to FIG. 3, the actuation unit is designed as a cartridge valve. The electromagnet 26 is firmly connected to the housing 7 and is used as a unit in a corresponding component 36. The actuating unit also has the pressure connection 10, the working connection 11, the pressure-relieved working connection 12, the pressure-loaded tank connection 13 in which the pressure relief valve 15 is seated, and the Throttle point 14. The valve piston 8 is moved by the plunger 16 of the electromagnet 26 from its closed position (right half in FIG. 3) against the force of the compression spring 18 into the open position, which is shown in FIG. 3 in the left half. In this open position of the valve piston 8, the pressure connection 10 is connected via the annular groove 20 to the working connection 11, which is separated from the two tank connections 12, 13 by the annular webs 19, 27 of the valve piston 8.

In contrast to the previous exemplary embodiment, the pressure-loaded tank connection 13 lies in the axial direction of the valve piston 8 and of the electromagnet 26. However, this does not change the mode of operation of the actuating unit. Otherwise, this embodiment works the same as the embodiment of FIG. 1.

If the electromagnet 26 is switched off and the plunger 16 is retracted, the valve piston 8 is pushed back into its closed position under the force of the compression spring 18. The ring land 27 of the valve piston 8 does not initially close the pressure-relieved tank connection 12 when the valve piston 8 is pushed back, so that the displaced hydraulic medium can be rapidly discharged to the tank via this tank connection 12. Only shortly before the valve piston 8 reaches its closed position (right half in Fig. 3), the pressure-relieved tank connection 12 is closed by the ring web 27. As in the previous embodiment, the pressure relief valve 15 ensures that the system has a corresponding residual pressure even when the electromagnet 26 is not energized, so that the system is prevented from running dry.

In Fig. 3, an embodiment is shown with dashed lines, in which the throttle point between the pressure port 10 and the working port 11 is not provided in the housing 7, but in the component 36.

Claims (7)

Actuating unit for an adjusting device, preferably for a valve stroke adjusting device of motor vehicles, with at least one coupling element with which a fixed and a movable component of the adjusting device can be coupled and which is hydraulically adjustable via at least one valve piston of the actuating unit, with which in a closed position at least one working connection from is separable from a pressure connection,
characterized in that the actuating unit has a pressure-relieved tank connection (12) and a pressure-loaded tank connection (13) provided with a pressure-limiting valve (15), that the pressure-relieved tank connection (12) when the valve piston (8) is moved until shortly before reaching the respective end position the work connection (11) is connected, and that in the end position the work connection (11) is connected to the pressure-loaded tank connection (13). Actuating unit according to claim 1,
characterized in that the valve piston (8) has an annular web (27) which is in the closed position of the valve piston (8) separates the pressure-relieved tank connection (12) from the working connection (11). Actuating unit according to claim 1 or 2,
characterized in that the valve piston (8) has a further ring web (19) which, in the closed position of the valve piston (8), separates the pressure connection (10) from the working connection (11). Actuating unit according to one of claims 1 to 3,
characterized in that the pressure connection (10) is connected to the working connection (11) via a throttle point (14). Actuating unit according to claim 4,
characterized in that the throttle point (14) is provided in a housing (7) of the actuating unit. Actuating unit according to claim 4,
characterized in that the throttle point (14) is provided in a component (36) receiving the housing (7) of the actuating unit. Actuating unit according to one of claims 1 to 6,
characterized in that the valve piston (8) has at least one throttle point (28) which connects a hydraulic chamber (24) in front of the valve piston (8) to an axial bore (23) of the valve piston (8).

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