DD154385A5 - HYDRAULIC CONTROL DEVICE, ESPECIALLY STEERING DEVICE - Google Patents

Abstract

The invention relates to a hydraulic control device, in particular steering device, with a control valve device and a valve slide. The aim of the invention is a functional improvement of the control device. The object is to achieve that an adjustment of the Handbetaetigungsorgans immediately leads to an adjustment of the piston-cylinder arrangement, so no dead zone in the region of the neutral position is present. According to the invention, the piston-cylinder arrangement has a differential piston, the first working connection leading to the pressure chamber of smaller effective area is permanently connected to the first control pressure space and separated from the tank connection. Two throttles, which are adjustable in opposite directions by the valve slide, are provided, of which one connects the second control pressure chamber to the second working connection and the other connects the second working connection to the tank connection. To form both throttles connected to the second working port annular groove in the housing of the control valve device cooperates with a collar on the valve spool, which has a smaller axial length than the annular groove.

Description

Hydraulic control device, in particular steering device

Field of application , the invention

The invention relates to a hydraulic control device, in particular steering device, with a control valve device which is connected via a first and a second working port, each with a pressure chamber of a piston-cylinder assembly and a tank connection to a tank and having a valve spool which Neutral position springs and the front side is loaded by the pressure in two control pressure chambers, which are each connected to a terminal of a controllable by a manual actuator control pump and a check valve assembly with a main pump.

Characteristic of the known technical solutions

In a known control device of this type (FR-PS 14 65 422, Fig. 4), the valve spool has two collars, which close the two working ports in the neutral position and at a shift in each case one working port with a control pressure chamber and the other working port to the tank port connect. The main pump is connected via a check valve directly to both control pressure chambers and in the neutral position via a short circuit path to the tank connection. In an adjustment of the manual actuator, the pressure in the two control pressure chambers is changed, so that the valve slide is displaced from its neutral position. It then flows pressure medium from the main

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Pump via a check valve, the control pump and a control pressure chamber in the one pressure chamber of the piston-cylinder assembly, while the other pressure chamber is connected to the tank. Both pressure chambers of the piston-cylinder arrangement have the same effective area. It is disadvantageous that the manual actuator must first cover a certain Totweg before the piston-cylinder assembly can be moved, because first the valve spool must be moved to a certain extent before the one working port can be supplied with hydraulic fluid.

Object of the invention

The aim of the invention is to enable a functional improvement of the hydraulic control device.

presentation; the essence of the invention

The invention has for its object to provide a hydraulic control device of the type described above, in which an adjustment of the manual actuator immediately leads to an adjustment of the piston-cylinder assembly ', so no dead zone in the region of the neutral position is present.

This object is achieved in that the piston-cylinder assembly has a differential piston, that the pressure chamber for smaller effective area leading first working port is permanently connected to the first control pressure chamber and separated from the tank port and

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that are provided by the valve spool in opposite directions adjustable throttles, of which one throttle connects the second Steu.erdru.ckratun with the second working port and the other throttle connects the second working port with the tank port.

In this construction, the two oppositely adjustable throttles form a pressure divider. The pressure taken off between the two throttles generates a force in the pressure chamber of greater effective area of the piston-cylinder arrangement which is compared with a force which is generated by the unreduced pressure in the pressure chamber of smaller effective area. With the aid of the adjustable by the manual control valve control pressure differences in the two control pressure chambers, due to which shifts the valve spool. This displacement leads immediately to a pressure change between the two throttles and thus to a displacement of the piston in one or the other direction. Another advantage is that external forces acting on the piston, lead to an adjustment of the valve spool so that the external force is compensated by hydraulic forces. In addition, the occurrence of this external force on the control pump on Handbetatigungsorgan is noticeable, so that it can be countered by hand.

In a particularly simple embodiment, it is ensured that the formation of both reactors connected to the second working port annular groove in the housing of the control valve device cooperates with a collar on the valve spool, which has a smaller axial length than the annular groove. It is therefore sufficient a very simple trained valve spool in a very simple design housing to achieve the desired goal.

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It is recommended to use a pressure-controlled main pump. This ensures that it is always assumed that the same pressure level, which facilitates the design of the two throttles compared to the effective surfaces of the two pressure chambers of the piston-cylinder assembly.

In a preferred embodiment it is ensured that the check valve assembly consists of a single check valve 36 and that the main pump 38 via this check valve to the second control pressure chamber 20 'and via the series circuit of check valve and control pump 31 with the first control pressure chamber. 19 is connected. This results in a simpler structure than in the usual use of two check valves, but does not affect the operation.

In addition, the check valve may be spring loaded. This ensures that not even slight vibrations in the pressure center column or vibrations, as they occur in a vehicle, lead to malfunction.

Preferably, both control pressure chambers 1 9, 20 are each connected to the tank 18 via a check valve 41, 41 'opening towards them. This allows an emergency operation alone with the help of the control pump in case of failure of the main pump.

For emergency operation, it is also advantageous if the tank connection of the control valve 9 is connected to the tank 18 via a spring-loaded check valve 42 which opens towards the control valve.

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embodiment

The invention will be explained in more detail with reference to a preferred embodiment shown in the drawing. The drawing shows a hydraulic control device according to the invention in a circuit diagram.

A piston-cylinder arrangement 1 v / eist a cylinder 2 and a one-sided connected to a piston rod 3 differential piston 4, which pivots on a linkage 5 a wheel 6 to be steered. The cylinder results in a first pressure chamber 7 smaller active area F1 and a second pressure chamber 8 larger effective area F2.

A control valve device 9 has a housing 10 with a bore 11 and a valve slide 12. In the housing 10 there is a first annular groove 13, which communicates with a first working port 14, which leads to the pressure chamber 7. A second annular groove 15 communicates with a second working port 16, which leads to the pressure chamber 8. Further, there is a tank connector 17 leading to the tank 18. At the ends of two control pressure chambers 19 and 20 are provided. In the control pressure chamber 19 is a neutral position spring 21, which acts on a perforated disc 22. The latter is supported either on a step 23 of the housing 10 or on an end face of the valve slide 12. In the control pressure chamber 20 is a Neutraiste11ungsfeder 24, which is based on a perforated disc 25. The latter rests either on a step 26 of the housing 10 or on the other end face of the valve spool 12. A first collar 27 on the valve spool 12 separates the control pressure chamber 19 from the space connected to the tank connection 17. With the annular groove

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forms a second collar 28, which has a smaller axial length than the annular groove 15, two throttles 29 and 30 which changes in opposite directions at a displacement of the valve spool 12.

A control pump 31 is adjustable via a hand actuator 32 ver. The two sides of the control pump 31 are connected to connecting lines 33 and 34, which lead to the control pressure chambers 19 and 20, respectively. The connecting line 34 is also connected via a spring-loaded check valve 36 to the pressure side 37 of a main pump 38, which has a pressure control device 39 for keeping the output pressure constant. The connection lines 33 »34 are connected via the check valves 41, 41 * via the line 40 to the tank 18. The tank connection 17 is associated with a check valve 42 which is so heavily loaded by a spring that in emergency operation, the valve spool 12 can be moved by means of the pressure generated by the control pump 31 to the left without the check valve 42 opens.

With this control device, the following modes of operation result:

In the illustrated neutral position, the main pump 38 generates a pressure Pq. The pressure P in the "control pressure chamber 19 and the pressure P ₂ in the control pressure chamber 20 is approximately equal

Pq. The pressure P. prevails in the pressure chamber 7 · In the pressure chamber 8, however, there is a pressure P ^, because the check valve 36 and the two throttles 29 and 30 continuously a small pressure medium flow flows, which leads to a pressure division at the working output 16. The ratio of the throttle resistances in the neutral position is chosen so that in the neutral position P ₁ χ F = P ~ χ F ₂ . As a result of this power

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equilibrium, the piston 4 stops.

Upon rotation of the actuator 32 to the left, P ^ increases slightly. Accordingly, the valve spool 12 shifts to the right. The resistance of the throttle 29 increases while that of the throttle 30 decreases. As a result, the reduced pressure P- decreases. Therefore, the piston 4 moves to the right.

Pressure fluid is supplied from the main pump 38 via the check valve 36, the control pump 31 and the control pressure chamber 19 in the Druckrauin 7, while at the same time pressure fluid from the pressure chamber 8 via the throttle 30 to the tank 18 can flow.

If the actuator is rotated to the right, the valve spool 12 moves to the left. As a result, the intermediate pressure P ~ between the throttles 29 and 30 increases. The piston 4 is pushed to the left. Here, pressure fluid flows from the main pump 38 via the check valve 36 and the control pressure chamber 20 to the pressure chamber 8. The simultaneously displaced from the pressure chamber 7 hydraulic fluid passes via the control pump 31 also in the pressure chamber

If the main pump 38 fails, an emergency operation can be maintained by means of the control pump 31. If the piston 4 is to be displaced to the left, the additionally required pressure fluid via the suction line 40 ', the check valve 41' and the control pump 31 'to the pressure chamber 8 can be promoted. With a desired displacement of the piston 4 to the right, the required pressure fluid can be conveyed via the suction line 40, the check valve 41 and the control pump 31 to the pressure chamber 7, wherein the liquid discharged from the pressure chamber 8 via the

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Check valve 42 to the tank 18 can flow.

When an external force in the direction of the arrow X acts on the piston 4 while the actuator 32 is held, the piston 4 shifts slightly to the left, as a result, the pressure increase in the control pressure chamber of the valve spool 12 is moved to the right. This increases the resistance of the throttle 29, which leads to a reduction of the pressure P ~. This corresponds to a compensation of the external force. At the same time, the pressure increase of P. by a corresponding pulse on the control pump 31 makes noticeable, so that the user experiences a slight impact on the actuator 32 and can counteract. Acts the force against the direction of the arrow X, so that similar conditions arise, but with the proviso that the valve spool shifts to the left and thereby increases the pressure P ^ and in this way the external force is compensated.

If the actuator 32 is not held in the occurrence of the external force, it rotates in accordance with the displacement of the piston 4. It is also possible to brake the displacement of the piston by applying a braking torque to the actuator 32 upon the occurrence of external force.

If the external force is not very large, there are also no concerns to support the adjustment of the piston triggered thereby by an equally effective adjustment of the actuator.

The line 37 can also be connected directly to the stop via a non-return valve similar to the check valve 36.

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connection line 33 are connected. Further, in this case, the check valves 41, 41 'can also be combined to form a single, only the main pump · 38 bridging check valve when in emergency control, the forces necessary to open the check valve 36 and the like further check valve forces can be accepted.

Claims (7)

1. A hydraulic control device, in particular steering device, with a control valve device which is connected via a first and a second working port, each with a pressure chamber of a piston-cylinder assembly and a tank connection to a tank, which further comprises a valve spool, which by neutral position springs and end face is loaded by the pressure in two control pressure chambers, which are each connected to a terminal of an adjustable by a manual control valve • pump and a check valve assembly with a main pump, characterized in that Piston-cylinder assembly (1) has a differential piston, that the pressure chamber (7) smaller effective surface leading first working port (14) permanently connected to the first control pressure chamber (19) and separated from the tank connection (17) and that two by the valve spool (12) oppositely adjustable throttles (29, 30) are provided, of which one throttle (29) the second control pressure chamber (20) with the second working port (16) and the other throttle (30) the second working port (16) with the Tank connection (17) connects. Control device according to item 1, characterized in that, to form both throttles (29, 30), an annular groove (15) connected to the second working connection (16) in the housing (10) of the control valve device (9) is provided with a collar (28) on the valve slide (10). 12) cooperates, which has a smaller axial length than the annular groove. 2 5 2 14 - 2c 2 2 52 1Λ- ó- 3. 2. 1981 58 333/16 Claim 3 # Control device according to item 1 or 2, characterized in that a pressure-controlled main pump (38) is used. 3. 2. 1981 58 333/16 4 ·. Control device according to one of the items 1 to 3> characterized in that the check valve arrangement consists of a single check valve (36) and that the main pump (38) via this check valve to the second control pressure chamber (20) and via the series circuit of check valve and control pump (31 ) is connected to the first control pressure space (19). 5. Control device according to one of the items 1 to 4, characterized in that the check valve (36) spring- , is charged. 6. Control device according to one of the items 1 to 5, characterized in that both control pressure chambers (19, 20) via a respective opening to them check valve _t 41 ') _{m with} the tank (18) are connected. 7. Control device according to one of the items 1 to 6, characterized in that the tank connection of the control valve (9) via a spring-loaded, the control valve to open the check valve (42) is connected to the tank (18). For this 1 page drawings