DE3918926A1 - Constant pressure flow control valve - has tubular valve spool sliding over fixed sleeve with high pressure sealing surfaces of equal dia. - Google Patents

Abstract

Good sealing surfaces are produced between the valve spool and the fixed part of the valve. Fitting into the stepped bore (2) of the valve housing is a fixed sleeve (14) which is sealed at each end (33). In the annular space between the sleeve and housing is the tubular spool (3) which slides over the sleeve and seals in the two regions (17) and (18) over a distance (L). The coil spring (7) loads the spool to the left with a force that is adjustable. Ports (6, 24) in the spool and sleeve overlap to create a shutter opening (B) which throttles and finally shuts off the supply of pressurised oil to the outlet passage (28) as the spool moves to the right. The movement of the spool and hence the amount of throttling is determined by the difference between the supply pressure forcing the spool to the right and the downstream pressure forcing the spool to the left. USE/ADVANTAGE - Free oil passage through the valve. Sealing surfaces can easily be produced. Well defined valve characteristic.

Description

The invention relates to a flow control valve in the Preamble of claim 1 specified type and one with the flow control valve as a supply controller equipped directional spool.

A flow control valve known from DE-OS 32 40 038 has the tubular closing element in the Housing bore of a directional spool valve, the Inner bore of the closing element at the same time Pump channel forms. The outer circumference of the closing element is at axially spaced sealing zones in the Housing bore and the inside diameter one in the Housing bore inserted sleeve guided. This means that in the shut-off position of the Flow control valve which then occur extraordinarily high pressure difference (200 bar or more) these sealing zones must be sufficiently tight. This but brings with it manufacturing problems themselves because the sealing zones are either on different Diameters or between a total of three different and coordinated Components are available. The closing element like this to fit that it is sensitive and smooth is adjustable and still the required Ensures tightness at high pressure differentials, is technically difficult and leads easily again to leaks or to a jamming of the Closing element. The reject rate due to Manufacturing tolerances are inappropriately large. A clean one  Characteristic curve can only be achieved with an extraordinarily high one Achieve manufacturing expense.

The principle of a tubular closing element in one Arrange the housing bore to be displaceable depending on the pressure. optionally with a side connection channel is connectable, is known from DE-PS 25 56 708. The basic advantage of this design is a compact Construction because the closing element takes up little space and with its inner bore one for other purposes usable flow channel, e.g. the pump channel in a directional control slide. However, there are also with this known valve the problem of different diameters in the housing bore lying sealing zones between the closing element and the Housing bore.

It has also been proposed (P 39 08 721) Front ends of the tubular closing element Pressure compensator through one in the inner bore of the Closing element gripping ring opposite the interior to seal the housing bore. However, also arise here manufacturing problems for the sealing zones between the three components: locking element, the two rings and the housing bore.

The invention is based on the object To create a flow control valve of the type mentioned at the outset, while maintaining the advantage of compact dimensions even for large pressure differences between the Housing bore and the connection channel easy to manufacture and is particularly reliable. This task contains the demand for a reduction in the reject rate due to the tightness and / or smoothness more restrictive in the regulation Manufacturing tolerances.  

The object is achieved by the im characterizing part of claim 1 specified Features solved.

With this design, it is in the housing bore stationary sleeve in interaction with the locking element for sealing and smooth guidance of the Closing element responsible. The sleeve can be used fixed sealing areas simply into the housing bore fit in. The sealing zones between the Sealing guide section and the inner bore of the Closing element on which the large pressure differences are easy to manufacture master because the inner bore of the closing element like the outer circumference of the sealing guide section with the sealing zones lying on the same diameter exactly are adaptable to each other. Where the closing element is the housing bore wall is sealed, only occurs a small pressure difference so that the tight fit can be relatively undemanding there and easy to manufacture. The Advantage of the compact design of the flow control valve remains because of the internal bore of the stationary Sleeve serves as a flow channel. Since between the Closing element and the sleeve with reasonable Manufacturing effort even with inevitable Manufacturing tolerances a clean fit on the same Diameter can be achieved that the smoothness and the necessary tightness ensures a good one Control characteristic of the flow control valve reached. The The reject rate can be reduced considerably. Self if the fit between the sleeve and the Closing element is unsatisfactory, is - if at all - only the sleeve or the closing element Committee. Such errors can be caused by reworking  be rectified later. In no case it is expensive housing.

Manufacturing and assembly technology is also the Embodiment according to claim 2 advantageous in which the housing bore for the closing element Stepped bore with at least one diameter step. No special care is required to be directed that the housing bore clean with the inner bore of the sleeve or the outer circumference of the Closing element is aligned because of the smooth operation and sealing the fit between the Closing element and the sleeve is responsible.

The embodiment according to claim is also expedient 3, because the longitudinal through bore as large cross-sectional flow channel can be used in the pressure medium that does not flow to the connecting duct to other consumers.

Another useful embodiment in which the Closing element a collar with an outside Has sealing surface which on an axial side of the Seals connection channel on the housing bore wall and circular application areas of the Closing element separates from each other can be acted upon in the opposite way with control pressures, emerges from claim 4. In the sealing zones on both sides of the passage in the guide section with a technically justifiable effort perfect sealing with simultaneous smooth movement of the closing element reached. Even high pressure differences are here reliably sealed.  

A particularly important thought is also in claim 5 contain. Limiting the sealing zones, preferably to the same degree, leads to a constant Resistance to movement for the closing element, what the Achieving a clean control characteristic is important.

Works in the embodiments of claims 6 and 7 the pressure compensator as an inlet regulator from the higher one pressure-bearing housing bore to the side Connecting channel. The spring determines the pressure difference between the control pressures for the adjustment movement of the closing element.

In terms of construction, the embodiment of Claim 8 useful because a long spring can be used is.

Another important thought is in claim 9 contain. By replacing the intermediate layer change the spring preload.

With regard to a perfect securing of the position Sleeve in the housing bore is the embodiment of Claim 10 useful.

The flawless control behavior and the Manufacturing advantages of the flow control valve come in particular with a directional spool Wear it with the pressure compensator arranged in the housing as a feed regulator to one in a slide hole adjustable, pressurizing a Equipped with consumer-controlling spool is, furthermore with one between opposite Continuous housing sides, serving as a pump channel Housing bore that runs across a transverse  Connection channel is connectable to the slide bore and the pressure compensator with the tubular, movable Closing element contains that from the pressure in the connection channel in one direction and from the load pressure of the consumer and a spring in the other direction is. The pressure compensator claims in this training very little installation space in the housing of the Directional spool. The stationary sleeve of the Housing bore, which even at high pressure differentials Sealing problems eliminated and manufacturing technology Provides advantages, also serves as a pump channel through the pressure medium is led to other consumers. If the directional spool valve does not have an inflow controller used, then only the closing element needs to be removed. Is one without an inlet regulator working directional control valve of this type retrospectively then only need the locking element used and the sleeve to be sealed again.

An embodiment of the Subject of the invention, i.e. one in one Directional control valve integrated pressure compensator, explained. It shows:

Fig. 1 shows a cross section of the directional control slide in the axis of the pump channel.

In a directional control valve S of the usual type, which for Control pressurization of at least one Consumer V from a pump channel P is used, is a supply controller for load-independent current control a pressure compensator DW is provided, one for Working pressure control adjustable spool K in Flow direction is upstream.  

In a block-shaped housing 1 extends between opposite housing sides 1 a and 1 b, a housing bore 2 , which is designed as a stepped bore with three sections 2 a, 2 b and 2 c in this order of decreasing diameter. Diameter steps 22 and 11 are provided between the sections. In the housing bore 2 , a tubular closing element 3 is displaceably guided in a pressure-dependent manner and bears with an outer collar 4 and a cylindrical sealing surface 5 on the wall of section 2 b of the housing bore 2 . Lateral openings 6 penetrate the closing element on one side of the collar 4 . A control spring 7 supported between the collar 4 and the diameter step 11 acts on the closing element in FIG. 1 to the left. The spring 7 is arranged in an annular chamber 8 , which is connected via a connection 9 to a control pressure line 31 . The spring 7 is supported on the diameter step 11 by means of a sleeve-shaped intermediate layer 10 , which, due to its axial thickness, determines the preload of the spring and can be exchanged in order to be able to change the preload of the spring 7 .

In the inner bore of the closing element 3 , designated by 13 , a step 12 is provided, to which a region of larger diameter adjoins, which extends to the right end of the closing element 3 .

In the housing bore 2 , a sleeve 14 is stationary, which has a cylindrical sealing guide section 15 , which is longer than the closing element 3 and the inner bore 13 passes therethrough. Between the 16 specified, the cylindrical outer circumference of the sealing guide portion 15 and the inner bore 13 of the closing element 3, two sealing zones 17, 18 are formed, each same axial sealing length L have. The sealing zone 18 is axially limited by the gradation 12 in the inner bore 13 of the closing element 3 . The sealing zone 17 , however, is limited by gradations 16 a in its axial length.

The sleeve 14 is equipped at one end with a collar 20 which seals with a seal 33 on the wall of section 2 b. A circumferential stop 21 on the collar 20 is placed against the diameter step 22 so that the sleeve 14 is secured in position in the housing bore 2 . The other, designated 19 end of the sleeve 14 is sealed by a seal 33 on the wall of section 2 c.

The sleeve 14 is provided with a smooth through bore 23 which defines the pump channel P. Lateral passages 24 lead from the inner bore 23 to the inner bore 13 of the closing element 13 . The passages 24 cooperate with the openings 6 in the manner of an orifice B, the passage width of which changes as a result of the adjustment movement of the closing element 3 , namely between a completely closed shut-off position and passage positions in which a more or less severe throttling takes place.

The passages 24 are delimited by webs 25 , which produce the one-piece construction of the sleeve 14 despite the passages 24 .

Between the sealing surface 5 and the sealing surfaces 17 , 18 , the closing element 3 has annular pressurizing surfaces A, at which control pressures for the pressure-dependent adjustment of the closing element can be brought to bear in order to give this flow control valve a pressure compensator function, which acts as a load pressure-independent inlet regulator for the slide piston K required so that the speed of consumption selected by the setting of the spool K is kept constant regardless of the load pressure.

From section 2 b of the housing bore 2 , a connecting duct 28 branches off laterally to a slide bore 29 , more precisely, to an annular recess 30 in the slide bore 29 . Starting from the recess 30 , the slide piston K distributes the pressure medium to the consumer as a function of the selected setting. Therefore, the slide piston K is symbolically indicated in Fig. 1 as an adjustable throttle K '. The pressure prevailing in the connection channel 28 as a function of the opening size of the diaphragm is a control pressure which loads the closing element 3 on the loading surface A to the right. The pressure downstream of the spool K is applied via the control pressure line 31 of the chamber 8 , so that it loads the closing element 3 on the loading surface A in the direction to the left. At the same time acts in this direction, the spring 7 , which determines the response pressure difference between the two control pressures. Consumer connections 32 are finally indicated by dashed lines in the housing 1 . A return channel system also runs in the housing. For the sake of clarity, this is not shown.

If the consumer is not controlled, then the annular chamber 8 is depressurized. The pressure from the pump channel P to the right, which acts on the application area A via the diaphragm B, shifts the closing element 3 to the right until the diaphragm is closed and there is a positive overlap between the left edge of each opening 6 in FIG. 1 and the right edge of each passage 24 is present. The then possibly high pressure difference is sealed in this area (corresponding to the sealing zone 18 ) and also in the other sealing zone 17 between the inner bore 13 of the closing element 3 and the outer circumference 16 of the sealing guide section 15 . The pressure difference between the chamber 8 and the connection channel 28 is low; the seal between the sealing surface 5 and the wall of section 2 b does not have to meet any special requirements.

As soon as the slide piston K is adjusted and pressure is applied to the consumer, the pressure in the control pressure line 31 and thus in the chamber 8 also increases . The closing element 3 is then moved to the left until it reaches the position shown, in which the aperture B is most open. Practically the full pressure in the pump channel P is also present in the connection channel 28 and thus on the spool K. If only a lower consumer pressure is required and the slide piston K is adjusted only slightly, then the pressure in the chamber 8 is also low. The closing element 3 is immediately shifted to the right again until the diaphragm reduces its passage width accordingly and controls only a pressure in the connecting channel 28 which is determined by the force of the spring 7 . The seal between the high pressure in the pump channel and the low pressure in the connection channel 28 is properly sealed via the two sealing zones 17 and 18 between the closing element and the sealing guide section 15 . The pressure difference between the chamber 8 and the connection channel 28 is still low, so that the sealing effect of the sealing surface 5 plays a subordinate role. In the event of changes in the pressure downstream of the spool K, the closing element carries out play movements, on the basis of which the pressure difference across the spool K remains constant.

The inner bore 13 of the closing element 3 , like the outer circumference 16 of the sealing guide area, could be smooth and continuous. The high pressure differences between these surfaces are easily sealed. The machining of the closing element 3 can be precisely matched to the outer peripheral surface 16 . The design of the housing bore 2 requires little manufacturing outlay due to the static seals, ie manufacturing tolerances that lead to inaccurate alignment of the individual sections of the housing bore 2 with respect to the peripheral surface 16 and the inner bore 13 do not affect the control behavior.

In this design, the flow control valve with the pressure compensator function could also be used in a separate housing and connected to a control slide via the connection channel 28 . If several control slides or flow control valves are placed next to one another in a battery-like manner, then there is the advantage of a continuous pump channel via the inner bores 23 of the sleeves 14 . For sealing between the housing sides 1 a and 1 b in such a battery-like arrangement 14 sealing elements are used on the front ends of the sleeve.

Claims (11)

1. Flow control valve, in particular pressure compensator, with a tubular closing element ( 3 ) that has at least one annular action surface (A) and that is pressure-dependent in a housing bore ( 2 ) that cuts a lateral connection channel ( 28 ) between a shut-off position and passage positions in which there is a connection controls between the interior of the housing bore ( 2 ) and the connecting channel ( 28 ) in the manner of an aperture (B), is displaceable in a sealed manner, characterized in that a sleeve ( 14 ) is arranged in the housing bore ( 2 ) and the inner bore ( 13 ) of the closing element ( 3 ) with a sealing guide section ( 15 ) which is longer than the closing element ( 3 ), that the sleeve ( 14 ) is sealed in front of and behind the closing element ( 3 ) on the wall of the housing bore ( 2 ), and that in the guide section ( 15 ) at least one lateral passage ( 24 ) is provided, with which a lateral opening ung ( 6 ) of the closing element ( 3 ) forms the panel (B). 2. Flow control valve according to claim 1, wherein the housing bore ( 2 ) for the closing element ( 3 ) is a stepped bore with at least one diameter step ( 11 ), characterized in that the stationary sleeve ( 14 ) at one end of the sealing guide section ( 15 ) has a collar ( 20 ) has that the collar ( 20 ) in the large-diameter part ( 2 b) and the end opposite the collar ( 19 ) of the sealing guide section ( 15 ) in the small-diameter part ( 2 c) of the stepped bore is fixed. 3. Flow control valve according to claim 1, characterized in that the stationary sleeve ( 14 ) has a longitudinal through bore ( 23 ). 4. Flow control valve according to claims 1 to 3, wherein the closing element has a collar ( 4 ) with an outer sealing surface ( 5 ) which is displaceably displaceable on the housing bore wall on an axial side of the connecting channel ( 28 ) and separates annular action surfaces of the closing element from one another, which can be acted upon in opposite directions with control pressures, characterized in that the closing element ( 3 ) with its inner bore ( 13 ) is guided in an axially sealed manner on both sides of the passage ( 24 ) on the sealing guide section ( 15 ), and in that the lateral opening ( 6 ) of the closing element ( 3 ) with the connecting channel ( 28 ) is constantly connected. 5. Flow control valve according to claims 1 to 4, characterized in that the axial sealing zones ( 17 , 18 ) between the inner bore ( 13 ) of the closing element ( 3 ) and the guide section ( 15 ) of the sleeve ( 14 ) on both axial sides of the passage ( 24 ) are limited in their axial length independently of the position of the closing element ( 3 ), preferably to the same dimension (L). 6. Flow control valve according to claim 4, characterized in that a control pressure loads the closing element ( 3 ) via the loading surface (A) in the opening direction of the diaphragm (B). 7. Flow control valve according to claim 6, characterized in that the closing element ( 3 ) in the opening direction of the diaphragm (B) by a, preferably biased, spring ( 7 ) is loaded. 8. Flow control valve according to claims 1 to 7, characterized in that the spring ( 7 ) between the collar ( 4 ) and the diameter step ( 11 ) of the housing bore ( 2 ) is arranged. 9. Flow control valve according to claim 8, characterized in that the spring ( 7 ) on the diameter step ( 11 ) is supported by an interchangeable intermediate layer ( 10 ) which determines the spring preload with its axial thickness. 10. Flow control valve according to claim 1, characterized in that the sleeve ( 14 ) against a shoulder ( 22 ) of the housing bore ( 2 ) axially attachable stop ( 21 ). 11. Directional spool (S) with a pressure compensator (DW) arranged in the housing ( 1 ) as a feed regulator to a slide piston (K) adjustable in a slide bore ( 29 ) that controls the pressurization of a consumer (V), with a valve piston located between opposite sides of the housing ( 1 a, 1 b) continuous, as a pump channel (P) serving housing bore ( 2 ), which can be connected to the slide bore via a transverse connecting channel ( 28 ) and contains the pressure compensator with a tubular, displaceable closing element ( 3 ) which is at least depressurized in the connecting channel ( 28 ) in one direction and the load pressure of the consumer (V) and a spring ( 7 ) in the other direction, characterized in that a sleeve ( 14 ) is arranged stationary in the housing bore ( 2 ) the closing element (3) passes through the inner bore (13) with a seal guiding portion (15), which is longer than the closing element (3) that the H is sleeve (14) sealed to the wall of the housing bore (2) in front of and behind the closing element (3), that at least one lateral passage (24) is provided in the guide portion (15), with a lateral opening (6) of the closing element ( 3 ) forms the diaphragm (B), and which is approximately aligned with the connection channel ( 28 ), and that the sleeve ( 14 ) passes over the length of the housing bore ( 2 ) and with its inner bore ( 23 ) the pump channel ( 8 ) of the directional spool (S).