EP1628019A2 - Vane actuator with a pressure reducing valve - Google Patents

Abstract

The oscillating motor comprises a cylinder (3) with ribs extending axially on the inside diameter, and a motor shaft (7) with vanes with the same axial extent as the ribs, whereby the vanes and ribs together with the cylinder, the end caps (11,13) and the shaft from individual chambers. Between at least two working chambers which are connected to different pressure medium connections (33,35) at least one pressure limiting valve is installed inside the oscillating motor.

Description

The invention relates to a swivel motor according to the preamble of patent claim 1.

DE 196 13 769 C2 describes a dual-circuit pressure medium system for active chassis control using a slewing motor. The swivel motor is known for example from DE 44 42 223 C2 and consists of a cylinder and extending in the axial direction ribs. Inside the cylinder, a motor shaft with wings is rotatably mounted parallel to the ribs. End cover closes the pivot motor, so that the motor shaft forms working chambers together with the cylinder, each adjacent working chambers is connected to a respective other of the existing pressure medium connections. A composite system within the swing motor serves to supply pressure medium between the respective working chambers.

As a result of a pressure supply of the swing motor exerts on the split stabilizer in the chassis a twisting movement, which ensures that the vehicle body performs only a limited roll motion. Peak pressures of about 180 bar occur. These peak pressures can be exceeded even if, with the swing motor activated, a jounce movement of the wheel takes place.

In DE 196 13 769 C2, a pressure limiting valve is used within the pressure medium system, which is functionally arranged between the pressure supply and a switching valve. Thus, a further pressure medium line within the vehicle is necessary, which can represent a potential leakage point.

Object of the present invention is to further develop such a pivot motor, which can absorb the said peak pressures permanently.

According to the invention the object is achieved in that at least one pressure relief valve is disposed within the swing motor between at least two working chambers which are connected to different pressure medium connections.

Regardless of the functional design of the pressure supply system of the swivel motor this can also withstand peak pressures, which is due to the short connection a very fast reaction time of the pressure relief valve.

In a first embodiment, the pressure limiting valve is arranged in a flow connection between adjacent working chambers. To implement the principle, several options are conceivable.

Thus, the flow connection can be carried out in a foot region of a rib or a wing. This solution requires no changes to the disc seals.

Alternatively, the flow connection may intersect a groove for a disc seal within a rib or wing. The advantage is that a flow connection below the wing, especially in a large motor shaft diameter in conjunction with a small wing height is difficult to manufacture, however, the access for a tool in the wing is already significantly low.

For this purpose, the window seal is designed with a cross connection. The manufacturing cost of the disc seal with a cross connection is practically free.

In a further advantageous embodiment, a valve body of the pressure relief valve comes in the closed position on the window seal to the plant. The advantage is that the disc seal consists of an elastic material and thus with little effort an ideal seating surface for the valve body is available.

In a further embodiment, the pressure limiting valve controls a flow connection between the pressure medium composite systems of the working chambers. The great advantage is that at the same time all working chambers are connected to each other via a single pressure relief valve.

A constructive possibility is that the pressure medium composite system is formed by at least two transverse bores within the motor shaft and between these transverse bores, the at least one flow connection is executed. A flow connection can be carried out particularly advantageously in the central axis of the motor shaft.

Furthermore, there is the possibility that the two pressure medium composite systems, a third pressure medium composite system is connected in parallel and this pressure medium composite system is in operative connection with the pressure relief valve.

The third pressure medium composite system is formed by an annular groove between the cylinder and the lid. This form of pressure fluid composite system and the flow connection between the pressure medium composite system can be made very easily.

Furthermore, there is the possibility that at least one working chamber is connected via the pressure limiting valve to the pressure medium composite system of an adjacent working chamber. This variant is particularly easy to produce because you simply make a radial bore between two wings in the direction of a transverse bore.

Alternatively, it can be provided that the flow connection for the pressure relief valve runs within the groove for the disk seal.

In a further constructive embodiment, a check valve is disposed within the groove side wall of the groove for the window seal. By a simple broaching the necessary space for the check valve can be created.

Furthermore, it is provided that the check valve is biased by a strip spring in a groove side wall.

One solution is that between the motor shaft and the lids each one of the pressure of a first working chamber biased shaft seal is disposed in an annular space, said annular space is connected via the pressure relief valve with a second working chamber, wherein the two working chambers are coupled to different pressure medium connections. At least part of the flow connection is taken over by the annulus. The particularly heavily loaded area of the motor shaft is not weakened.

The pressure limiting valve is arranged on a cover, which is much easier to machine compared to the motor shaft.

Regardless of the location of the check valve, this consists of a valve body in conjunction with a spring and a spring-supporting element, for. B. a screw-in. With a check valve in the lid, the spring of the pressure relief valve can be supported on a rib of the cylinder.

So that a defined outflow can take place in the working chamber, the rib is designed frontally with a groove for connection to a working chamber.

Fig. 1

Schwenkmotor im Längsschnitt

Fig. 2

Schwenkmotor nach Fig. 1 im Querschnitt

Fig. 3 -6

Schwenkmotor mit Druckbegrenzungsventil zwischen zwei benachbarten Arbeitskammern

Fig. 7

Druckbegrenzungsventil zwischen Verbundsystemen der Arbeitskammern

Fig. 8

Druckbegrenzungsventil zwischen einem Arbeitskammer und einem Verbundsystem einer benachbarten Arbeitskammer

Fig. 9 - 10

Druckbegrenzungsventil in einem dritten Druckmittelverbundsystem

Fig. 11 - 12

Druckbegrenzungsventil innerhalb einer Nut einer Scheibendichtung des Schwenkmotor

Fig. 13 - 14

Druckbegrenzungsventil zwischen einem Ringraum einer Wellendichtung und einem Arbeitskammer

The invention will be explained in more detail with reference to the following description of the figures. It shows:

Fig. 1

Swivel motor in longitudinal section

Fig. 2

Swivel motor according to Fig. 1 in cross section

Fig. 3 -6

Swivel motor with pressure relief valve between two adjacent working chambers

Fig. 7

Pressure relief valve between composite systems of the working chambers

Fig. 8

Pressure relief valve between a working chamber and a composite system of an adjacent working chamber

Fig. 9 - 10

Pressure relief valve in a third pressure medium composite system

Fig. 11 - 12

Pressure relief valve within a groove of a disk seal of the swing motor

Fig. 13 - 14

Pressure relief valve between an annulus of a shaft seal and a working chamber

1 shows, in conjunction with FIG. 2, a swivel motor 1 in longitudinal section whose basic construction is also assumed in the following figures. The swivel motor 1 comprises a cylinder 3, on whose inner diameter axially extending ribs 5 are executed. Inside the cylinder 3, a motor shaft 7 is rotatably mounted. On the motor shaft wings 9 are arranged, which extend parallel to the ribs 5. End is the cylinder 3 of lids 11; 13 closed. The motor shaft with its wings and the cylinder with its ribs together with the covers working chambers 15; 17, which are separated by disc seals 19 in the wings and ribs. Furthermore, in annular spaces 21; 23, the lid 11; 13 shaft seals 25; 27 chambered, the outlet of pressure medium from the working chambers 15; 17 prevent. Between the working chambers 15 and 17 there is a composite system of transverse bores 29; 31 in the motor shaft 7. A first pressure medium connection 33 supplies via the transverse bore 29, the working chambers 15 and a second pressure medium connection 35 fulfills this function via the transverse bore 31 for the working chambers 17. In the respectively interconnected working chambers prevails an equal pressure level. By inflow or outflow of pressure medium via the pressure medium connections 33; 35, the swivel motor exerts a torque that z. B. is used for adjusting a split stabilizer within a chassis for a motor vehicle.

FIG. 3 shows a swivel motor according to FIG. 2 in the embodiment with a pressure-limiting valve 36 between two adjacent working chambers 15; 17, with different pressure medium connections 33; 35 are connected. The Each pressure relief valve consists of a flow connection 37, which consists of a valve body 39, z. B. a ball or a cone in connection with a closing spring 41 is sealed. The closing spring 41 is supported on a sleeve 43. With a motor shaft with two blades, it makes sense in view of a large pivot angle of the motor shaft when the flow connection is parallel to the orientation of the wings 7 in a foot region of the rib or the wing. In this sectional plane, the pressure limiting valves for a peak pressure in the working chambers 15 are shown. Of course, also not shown pressure relief valves can release a flow connection of the working chambers 17 in the direction of the working chambers 15 in the reverse direction.

4, a pressure relief valve 36 is shown within a wing 7, wherein the flow connection 37 crosses a groove for the disc seal 19. Fig. 5 shows a variant enlarged. Each disk seal comprises a sealing frame 45 in which patches 47 are arranged. In addition, side seal plates 49 are inserted in the groove. Overall, the disc seal 19 has a slight clearance to the groove side walls, so that pressure medium from a working chamber with high pressure can flow into the groove and thereby enters a gap between the filler pieces and a side seal. Via transverse openings 51 in the filler pieces, the operating pressure also acts radially on the sealing frame, the circumferential rests on the groove base and the inner wall of the cylinder and the inner sides of the lid. The higher pressure in a working chamber ensures that the window seal in the direction of the working chamber with lower pressure is shifted. If there is a pressure peak, which is above a defined opening point of the pressure relief valve, then the valve body lifts with the back in the direction of the working space with the lower pressure of a valve seat surface in the wing 7, so that a cross connection 53 is released in the window seal.

FIG. 6 shows a modification to FIG. 5, in which the valve body 39 comes to rest on the window seal 19, in particular the side sealing disks 49. In this variant, shape and position deviations, in particular to the valve body 39 and cross connection 53 can be easily compensated.

In Fig. 7, a pressure relief valve 36 is used, which can connect a working chamber 15 with the pressure medium composite system, transverse bore 31, an adjacent working chamber 17. The advantage of this embodiment is that the flow connection 37 utilizes the pressure medium composite system for the function of the pressure relief valve. It makes sense each of the work spaces 15; 17 with the corresponding transverse bores 29; 31 connect via a pressure relief valve 36.

The previous solutions describe a pressure relief valve between a working space and another working space or a pressure medium composite system. But one can also provide that the pressure relief valve is a flow connection between the pressure medium composite systems of the working chambers 15; 17 controls.

Fig. 8 shows a solution in which the pressure relief valve 36 is arranged with its flow connection 37 between the transverse bores 29, 31. Within the motor shaft 7, a stepped blind hole opening 55 is executed, the end of which forms the flow connection 37. The transverse bores 29; 31 intersect in the projection in the central axis of the motor shaft, so that there the flow connection 37 is made meaningful. A flow connection at this point of the slewing motor is only change, which exerts no influence on the mechanical strength of the motor shaft.

Figs. 9; 10 show a further variant, in which the pressure limiting valve 36, the flow connection 37 in conjunction with the pressure medium composite system 29; 31 controls. In addition, the swivel motor has a third pressure medium connection system that is hydraulically connected in parallel to one of the pressure medium compound systems. Within the lid 11, a circumferential annular groove 57 is executed, which is connected via the axialverlaufende flow connection 37 with the working chamber 17. At an excessive pressure, the valve body in the cover can lift against the spring force of the closing spring and release the flow path through the annular groove 57 in one of the working spaces 15.

In Figs. 11; 12, a pressure relief valve 36 is described, which is arranged in the ribs 5 of the cylinder 3. Fig. 11 shows a vertical section through the pivot motor parallel to the central axis of the cylinder. In addition, Fig. 12 is limited to a cross section through the rib 5. Der Aufbau der Disk seal 19 corresponds to the description of FIG. 5. A functional difference is that the flow connection for the pressure limiting valve runs within the groove for the disk seal 19. It has already been pointed out that the sealing frame 45 at the groove bottom of the groove and the surface of the motor shaft 7 and on the inner sides of the lid 11; 13 is present. However, if the pressure medium z. B. flows from the working chamber 15 into the groove for the disc seal, then the entire seal package is moved in the direction of the working chamber 17. The left side window seal 49 allows the pressure medium supply into the transverse openings 51, so that the sealing frame 45 is radially biased. In this case, the flow connection 36 opens, but prevents the side window seal 49 in the direction of the working space 17 a direct pressure medium crossing. However, if an allowable peak pressure is exceeded, then the pressure relief valve 36 opens within the groove of the disc seal, wherein the check valve is formed by a strip spring 59 in conjunction with a strip-shaped valve body 39 in a groove side wall 61. The open pressure relief valve allows a flow of pressure medium parallel to the longitudinal axis of the disk seal in the direction of the lid 11; 13, which exert no sealing function between the work spaces, so that this way a pressure equalization between the work spaces is possible.

In the context of the description of the figures for Fig. 1 has already been noted that the shaft seals 27; 27 by the pressure in the work spaces 15; 17 are dynamically biased. In each case the greater pressure in the work spaces 15; 17 acts on the back of the shaft seals 25; 27. In this context will referenced DE 100 62 477 C1. Figs. 13; 14 show the pressure relief valve 36 with its flow connection 37 between the annular space 21 for the shaft seal 25 and a working space. The pressure relief valve 36 is disposed within the lid 13, wherein the closing spring 41 is supported on a rib 5 of the cylinder. As soon as the higher pressure from a working room, z. B. 17, flows into the annular space 21, the pressure continues through the flow connection 37 to the pressure relief valve 37 continues. After exceeding the peak pressure, the valve body 39 lifts from a valve seat surface in the lid 13 and releases an end-side groove 63 in the rib 5, so that the pressure medium in the working space, in this case 15, can flow, which with the other of the two pressure medium connections 33; 35 is coupled.

Claims (18)

A swing motor comprising a cylinder with axially inner diameter ribs closed at the ends by two lids, a motor shaft with vanes having the same axial extent as the ribs of the cylinder, the vanes of the engine shaft and the ribs of the cylinder together with the cylinder , the covers and the motor shaft forming individual working chambers, a first and a second pressure medium connection for two each separated by a rib working chambers; a composite system between the working chambers connecting at least a pair of working chambers, the arrangement of the connected working chambers being such that the working chambers associated with the first pressure medium port alternate with those associated with the second pressure medium port;
characterized,
in that at least one pressure-limiting valve (36) is arranged within the pivoting motor (1) between at least two working chambers (15; 17) which are connected to different pressure medium connections (33; 35). Swing motor according to claim 1,
characterized,
in that the pressure-limiting valve (36) is arranged in a flow connection (37) between adjacent working chambers (15; 17). Swing motor according to claim 2,
characterized,
in that the flow connection (37) is embodied in a foot region of a rib (5) or a wing (9). Swing motor according to claim 2,
characterized,
in that the flow connection (37) intersects a groove for a disk seal (19) within a rib (5) or a wing (9). Pivoting motor according to claim 4,
characterized,
that the window seal (19) is designed with a cross connection Pivoting motor according to claim 4,
characterized,
in that a valve body (39) of the pressure-limiting valve (36) comes to rest on the window seal (19) in the closed position. Swing motor according to claim 1,
characterized,
in that the pressure limiting valve (36) controls a flow connection (37) between the pressure medium composite systems (29; 31; 57) of the working chambers (15; 17). Swing motor according to claim 7,
characterized,
in that the pressure medium composite system (29; 31) is formed by at least two transverse bores within the motor shaft (7) and between which transverse bores (29; 31) the at least one flow connection (37) is made. Swing motor according to claim 1,
characterized,
in that at least one working chamber (15; 17) is connected via the pressure limiting valve (36) to the pressure medium composite system (29; 31) of an adjacent working chamber (15; 17). Swing motor according to claim 7,
characterized,
that the two pressure medium composite systems (29; 31) a third pressure medium composite system (57) is connected in parallel and this pressure medium composite system (57) is in operative connection with the pressure relief valve (36). Pivoting motor according to claim 10,
characterized,
that the third pressure medium composite system by an annular groove (57) between the cylinder (3) and the cover (11; 13) is formed. Swing motor according to claim 2,
characterized,
in that the flow connection (37) for the pressure limiting valve (36) runs inside the groove for the window seal (19). Swing motor according to claim 12,
characterized,
in that a check valve (36) is arranged within the groove side wall (61) of the groove for the window seal (19). Pivoting motor according to claim 13,
characterized,
that the non-return valve (36) is biased by a spring strip in the groove side wall (61). Swing motor according to claim 1,
characterized,
a shaft seal (25; 27) prestressed by the pressure of a first working chamber (15; 17) is arranged in an annular space (21; 23) between the motor shaft (7) and the covers (11; 13), this annular space (21 23) is connected via the pressure limiting valve (36) to a second working chamber (15; 17), the two working chambers (15; 17) being coupled to different pressure medium connections (31; 33). Swing motor according to claim 15,
characterized,
in that the pressure-limiting valve (36) is arranged in one of the covers (11, 13). Swing motor according to claim 16,
characterized,
in that a spring (41) of the pressure-limiting valve (36) is supported on a rib (5) of the cylinder (3). Pivoting motor according to claim 1 5,
characterized,
in that the rib (5) is provided at the end with a groove (63) for connection to a working chamber (15; 17).

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