DE2845301A1 - Noise reduction for servo steering valve - has stepped insert pistons and transverse compensating bores and uses connecting tube with through bore - Google Patents

Abstract

The slide control valve for a hydraulic steering servo has control ducts fitted with stepped insert pistons with central bores. The pistons are displaced by the pressure in the servo and allow a flow of oil in transverse ducts between the inlet and outlet ducts of the valve. The transverse flow is controlled and serves to reduce the pressure peaks on the return line and hence the noise associated with servo control valves. For this purpose transverse bores provided may throttle the pressure oil flow.

Description

Rotary slide valve for power steering.

The invention relates to a rotary slide valve for power steering of motor vehicles, with a rotary valve and one enclosing the rotary valve Valve sleeve, with a distribution of the pressure medium to a servomotor 'The between Rotary slide valve and valve sleeve arranged inlet control edges and return control edges between rotary valve and valve sleeve, with connecting bores from the return control edges lead to a return connection.

In rotary slide steering valves this Bauert it is known that from At a certain pressure level, clearly audible flow noises in the form of unpleasant ones Hissing noises occur, which arise on the control edges of the rotary disc valves. These noises depend on the pressure ratio of the pressures in front of and behind the control edges. The greater the pressure drop, the more uncomfortable they become Hissing noises.

For this reason azn has so far thawed the return oil by thawing Pressure ratios at the control edges changed accordingly. Through this backflow is an elimination or at least at least considerable damping of the flow noise achieved. The disadvantage here, however, is that the backlog when it is not actuated Steering valve poses problems. Among other things, there is a deterioration of the vehicle return. In addition, there is unnecessary heating of the Hydraulic fluid and a waste of energy.

The present invention is therefore based on the object of a throttle valve create for power steering of motor vehicles of the kind mentioned singangs, in which the desired backflow pressure is generated when the steering valve is actuated is, while on the other hand, when the steering valve is not actuated, the steering function is not adversely affected.

This object is achieved in that in at least a connecting hole one with a through hole for the blrücklau4, when the steering valve is not actuated, it is essentially located in the connecting bore and when the steering valve is actuated, pistons protruding into the return groove are arranged which has a differential pressure surface directed towards the return flow direction, whereby the differential pressure area is connected to the respective inlet groove via cross bores Servomotor and connected to the respective drainage groove from the servomotor ISti and where Throttle points are arranged between the transverse bores.

The inventive management of the hydraulic fluid provides if the steering valve is not actuated, there is no back pressure.

In the hydraulic system, there is more essential everywhere.

the return pressure. The differential pressure area is ineffective and the The piston lies in the connecting bore. If the steering is now operated, so builds a pressure builds up in the respective inlet groove. The Differential pressure surface is acted upon by a differential pressure which is opposite to that in the Return groove prevailing return pressure acts. This will move the piston towards of the return groove bottom moved until its hole through the groove bottom of the return groove is so narrowed that the return oil builds up. The amount of back pressure is proportional to the pressure of the servo motor and can be controlled by the choice of the area ratio on the differential pressure area vary.

While so far according to the state of the art, the return pressure in the return groove prevailed, so that at the return control edge the entire pressure difference with corresponding Zlschgeräuschen aD was built, is now due to the additional throttle point an intermediate pressure in the return groove before the extended piston, creating hissing noises be avoided. According to the invention, there is a gradual reduction in pressure.

According to the invention, in order to keep bleeding losses low, between the transverse bores Throttle points provided.

If the return connection goes from the interior of the rotary valve, then the connecting bores with the piston are generally radial in the rotary valve arranged. In the same way, however, a reverse construction is also possible; d. H. the connecting bores are directed radially outward in the valve sleeve and the connection to the return connection runs in the valve sleeve.

In general, as many pistons will be used as there are return grooves or connecting holes are available.

However, if the oil throughput is so high that the or the Cross-sections of the connecting holes are too small to allow the entire bl could absorb so it may be sufficient if only one Part of the WerbindungsbohrunOen are provided with the piston according to the invention.

In the remaining free connecting bores then arises due to the excessive amount of oil also creates a dynamic pressure.

The advantage is that with the back pressure built up according to the invention no seals are applied in the low-pressure part.

In an embodiment of the piston according to the invention it is provided that the piston is designed as a stepped piston and the differential pressure area of the Stage is formed.

The step or the shoulder directed towards the return groove thus represents represents the differential pressure area in a simple way.

A simple measure to reduce the leakage current between the high pressure side To keep the servomotor and the low-pressure side low, according to the invention in that the transverse bores are designed as throttle bores.

Another measure to keep the leakage current low is to that between the transverse bores and the differential pressure area there is an annular throttle area is arranged by the piston and one surrounding the piston Wall part is formed.

An annular throttle surface can be produced more easily than throttle bores with their small diameters.

It is advantageous if the piston is in a return groove on its own protruding end face is convex.

By: de measure a better flow is achieved.

There is no sharp edge and the through hole is in the fully extended state of the piston more tightly sealed.

The following is an exemplary embodiment of FIG Invention described in more detail.

The figures show: FIG. 1 a cross section through a rotary slide steering valve, FIG. 2 Section II - II according to FIG. 1 through the piston according to the invention (enlarged shown).

The throttle slide valve is basically of a known construction. It has a "six, groove" system, the connections being in the drawing the pump, the return tank and the servomotor are only shown schematically are.

The steering valve consists of a rotary slide valve 1, which is supported by a valve sleeve 2 is surrounded. The steering valve is operated by a pump 4 via a line 5 with pressure medium provided. The pump 4 receives the pressure medium from a return tank 6. The line 5 opens into the valve housing 3 in an annular groove 7 from which transverse bores 8, 9 and 10 lead to grooves 11, 12 and 13 in the valve sleeve 2.

The grooves 11, 12 and 13 are each with in the control edges Rotary slide arranged grooves in connection.

The position of the valve shown represents the neutral position If the rotary valve 1 is rotated in the direction of the arrow, 14, 15 and 16 represent the inlet grooves and 17, 18 and 19 the return grooves.

From the inlet grooves 14, 15 and 1o lead - as shown by dashed lines - Boreholes in another annular channel, from which a servomotor 20 via a line 21 is supplied with pressure medium. In this way, the piston 22 of the moves Servomotor 20 in the drawing to the left.

The pressure medium return does not find its way into one via a line 23 shown annular groove instead. Go from this ring groove, as also dashed shown, cross bores to the return grooves 17, 18 and 19. The return grooves 17, 18 and 19 are connected to connecting bores 24, 25 and 26 via control edges, which open into the interior of the rotary valve, from where a return connection 27 goes off to the return tank 6. In the connecting bores 24, 25 and 26 are now pistons 28, 29 and 30 with through bores 31, 32 and 33 are arranged.

For the sake of clarity, more details are given below explained about the pistons and their mode of operation only with reference to the piston 28. the The mode of operation and the structure of the two other pistons 29 and 30 are the same.

Just as in the rotary valve return grooves 17, 18 and 19 are arranged are, there are in the valve sleeve 2 three with these grooves via return control edges cooperating return grooves 34, 35 and 36 arranged.

When the direction of rotation of the rotary valve is reversed, the inlet grooves are then 14, 15 and 16 with the return grooves 34> 35 35 and 36 cooperating Grooves.

The piston 28 is designed as a stepped piston and protrudes with his Upper part into the return groove 34. A step is formed by the stepped piston, which acts as a differential pressure surface 37. This differential pressure area 37 protrudes an annular gap, which is designed as an annular throttle surface 38, and two transverse bores 39 and 40 each with the inlet groove 14 and the return groove 17 of the valve slide 1 in connection. The piston 28 is on its end face protruding into the return groove 34 41 convex.

The piston 28 (as well as the pistons 29 and 30) act on the following Way: If the rotary slide valve 1 is turned in the direction of the arrow, as mentioned, then it is lying the working pressure in the inlet groove 14. As long as the control edge 42 is not complete is closed, there is a strong pressure gradient between the inlet groove 14 and the Return groove 34. However, through the bore 39 and the annular throttle surface 38 the differential pressure surface 37 is acted upon by a correspondingly “throttled” working pressure. As a result, the stepped piston 28 is pushed radially outward into the return groove 34. This leads to a throttling of the pressure medium in the return groove 34 and thus to build up an intermediate pressure in the return groove 34.

The level of the intermediate pressure is now dependent on the pressure in the Inlet groove 14, the throttling in the transverse bore 39 and the annular throttle surface 38 and the size of the office pressure area. Through these measures it is achieved that there is no excessive pressure reduction at the control edge 42, which would lead to the unpleasant Leads to hissing noises. The stepped piston 28 is in the neutral position by the pressure medium is automatically pushed back into the connecting bore 24.

The transverse bores 39 and 40 can be throttle bores or normal bores be. The same applies to the annular surface 38.

Claims (5)

Patent claims: 1) Rotary slide valve for power steering of motor vehicles, with a Drenschieber and a rotary valve enclosing Valve sleeve, with a distribution of the pressure medium to a servomotor via between Rotary slide valve and valve box arranged inlet control edges and return control edges between rotary valve and valve sleeve, with connecting bores from the return control edges lead to a return connection, which means that in at least one connecting bore (24, 25, 26) one with one Through hole (31, 32, 33) for the oil return provided, when not controlled Steering valve essentially lying in the connecting hole and when it is controlled Steering valve in a return groove (34, 35, 36) protruding piston (28, 29, 30) arranged which has a differential pressure surface (37) directed against the return flow direction having, wherein the differential pressure surface via transverse bores (39, 40) with the respective Feed groove (14) to the servomotor (20) and with a respective return groove (17) from Servomotor (20) is connected, and wherein between the transverse bores (39, 40) throttle points are arranged. 2) Throttle slide steering valve according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the piston is designed as a stepped piston (28, 29, 30) and the differential pressure surface (37) is formed by the step. 3) rotary slide steering valve according to claim 1 or 2, d a d u r c h g e k e n n n n e i c h n e t that the transverse bores (39, 40) are designed as throttle bores are. 4) rotary slide steering valve according to claim 1 or 2, d a d u r c h g e k e n n n n e i c h n e t that between the transverse bores (39, 40) and the differential pressure surface (37) an annular throttle surface (38) is arranged, which is from the piston (28, 29, 30) and a wall part surrounding the piston is formed. 5) rotary slide steering valve according to one of claims 1-4, d a d u r c h g e k e n n n z e i c h n e t that the piston (2b, 29, 30) on its in a Return groove (34) protruding end face (41) is convex.