DE3732445A1 - Pressure control valve - Google Patents

Abstract

In a pressure control valve in which the piston spool controlling the pressure-medium paths between the control-pressure passage, a pressure-medium source and a tank can be adjusted by a proportional magnet, the actuating force of the proportional magnet is reduced by a hydraulic auxiliary force so that such pressure control valves can be used for high pressure ranges and large volumes of flow. The measures for producing the auxiliary force are based on the differential-piston principle. All embodiments have a low production cost.

Description

The invention relates to a pressure control valve with the The preamble of claim 1 features mentioned.

Pressure control valves for larger flow rates and / or higher Pressures are usually carried out in a pilot-controlled manner. Since the Proportional magnet for regulating the system pressure only on the pilot valve works, small magnets Ver find application. The adjustment speed is great, but tax oil is consumed on the one hand and is on the other the construction effort for a pilot operated pressure control valve relatively large.

In the case of pressure control valves without pilot control, the high flow forces a relatively large magnet to be built in.

Basically, it is known the size of magnets to reduce (FR-PS 14 00 801) that hydrau generated additional forces for the valve member. This is also realized in a known pressure relief valve light (DE-PS 33 15 222). It is a Seat valve, its closing body from the plunger of the magnet anchors pressed onto the valve seat by means of a preload spring is, the biasing spring chamber connected to the tank is and the closing body against the magnetic force from System pressure is applied. To generate the hydrauli additional force, it is necessary to guide between the armature space and the preload spring room with a seal.

According to an older proposal (P 37 12 168) is also used for  a pressure control valve with three ways the magnetic force of the Proportional magnets through a hydraulic pressure force that is proportional to the control pressure. By means of a Differential area between the spool of the pressure rule valve and a plunger actuating the piston slide becomes the hydraulic Zu supporting the magnetic force generated force, the plunger also sealing is led.

Based on a well-known pressure rule on the market valve is the object of the invention, the Fer To reduce the effort required for such valves and possible large flow rates and high pressure ranges to control the smallest possible proportional magnets.

The stated object is according to the invention in characterizing part of claim 1 Features solved.

According to the hydraulic additional force Support the magnetic force by means of a difference area generated without the be for the spool operating plunger of the magnetic armature a special seal tion is required. There are different designs possible, where there are additional advantages. The Differential area can result from the difference in through knife of the spool and an additional den Result slide valve piston acting additional piston. The diameter of the additional piston can be larger or be smaller than that of the spool. The hydraulic Additional force results from the pressure Actuation of the two end faces of the slide piston and the additional piston. In another embodiment the additional piston on the slide piston abge reverse side of the anchor. This one too  Embodiment can be a corresponding differential area achieve.

Embodiments according to the invention are also distinguished due to a compact design, especially a ratio moderately small axial length and use at high Pressure values.

Several embodiments of the invention are below explained in more detail with reference to the drawing. Show it:

Fig. 1 is a schematic representation of a three-way pressure control valve with a propor on which the tionalmagneten end facing away from the spool disposed auxiliary piston,

Fig. 2 is a pressure control valve similar to FIG. 1 with abge ändertem piston slide,

Fig. 3 is a pressure control valve similar to FIG. 1, in which the armature space of the magnet is pressure-relieved,

Fig. 4 is a schematic representation of a pressure control valve with an additional piston and the piston spool facing away

Fig. 5 shows a pressure control valve similar to Fig. 4 in a modified version.

The schematic illustration of FIG. 1 shows a spool 10 with two collars 11 and 12 which enclose between them an annular groove. 13 The spool 10 is slidable in a bore 14 of a housing. Via the control edges 15 , 16 , a control pressure channel 18 opening into the annular groove 13 can optionally be connected to a channel 19 connected to a pressure medium source P or a channel 21 connected to a tank T.

On one side of the spool 10 , a Pro portionalmagnet 24 is provided, the movable armature 26 in an armature space 25 carries a plunger 27 which bears on the piston slide 10 . The two-sided spaces of the armature 26 are connected to one another in a manner not shown. The armature chamber 25 is also connected to the control pressure channel 18 via a channel 29 .

On the side of the spool 10 facing away from the armature 26 , an additional spool 30 is provided, which is pressed against the spool 10 by a spring 31 . The spring chamber 32 is connected via a channel 33 to the control pressure channel 18 . The space 34 between the additional piston 30 and the piston slide is always connected to the channel 21 leading to the tank T via a bore 36 in the piston slide. The space 34 is thus relieved of pressure.

The diameter D _{ZK of} the additional piston 30 is larger than the diameter D _{K of} the piston slide 10 . Defined by the diameter of the auxiliary piston 30 surface that faces the space 32, and defined by the diameter of the piston slide surface which faces the armature space 25 are respectively acted upon by the regulating pressure A. The difference between the two areas is calculated from (D _ZK ² - D _K ²). It is therefore only necessary to apply the force corresponding to this differential area from the proportional magnet 24 . It can be seen that the magnetic force and the control pressure in the space 25 on the piston slide 10 act in the same direction, while the additional piston 30 acting control pressure and the spring 31 act against sensible.

In Fig. 2, a modified embodiment is shown, in which the piston slide 210 is slidably disposed in a bore 211 of a housing 200 and has a collar 212 , each with a control edge 215 and 216 and ring grooves 213 and 214 adjoining it. When moving the spool valve 210 of connected to a pressure medium source P channel 219 is connected to the control pressure passage 218 via the control edge 215, during the passage from the control pressure channel 218 to the annular groove 213 and controlled thereby a connected with a tank T channel 221 of the control edge 216 is . The piston slide 210 has a collar 208 and 209 at both ends.

Compared to the representation in Fig. 1, the connections to the pressure medium source and the tank are thus interchanged and the passage to the control pressure channel 218 from the collar 212 is determined.

As shown in Fig. 1, a proportional magnet 24 is seen with an armature 26 and a plunger 27 attached to the armature. The armature is displaceable in an armature space 25 , which is connected to the control pressure channel 218 via a channel 29 .

On the other hand, the control pressure reaches the consumer A via a line 33 and the spring chamber 32 for the additional piston 30 . This corresponds to the illustration in FIG. 1. The space 34 between the additional piston 30 and the piston slide 210 is also connected via a bore 236 to the channel 221 leading to the tank. The bore 236 in the piston slide 210 extends between the space 34 and opens into the annular groove 213 . This eliminates the long bore in the piston slide required in FIG. 1.

Otherwise, the mode of operation and the manner in which the additional hydraulic force is generated fully correspond to the relationships described with reference to FIG. 1.

A modification is shown in Fig. 3. Components that are the same as the components explained in FIG. 1 are identified by the same reference numerals. In this embodiment, the additional piston 330 has a diameter D _ZK that is smaller than the diameter D _{K of} the piston slide 10 . The collar 11 of the spool 10 has an extension 334 , which is arranged in a chamber 335 . The spring space 332 of the chamber 335 is connected to the space 338 on the other side of the extension 334 , for example by an annular gap or other means. The control pressure thus acts on the additional piston 330 as well as on both sides of the extension 334 and on the differential area, which results as follows (D _K ²- D _ZK ²). The space 340 formed in the collar 11 , that is to say the space between the piston slide 10 and the additional piston 330, is connected via a bore 336 to the channel 21 leading to the tank T. The purpose of the extension 334 is that the diameter of the additional piston 330 is only slightly smaller than that of the piston slide. Here too, the area difference between the piston slide valve and the additional piston results as the weighing surface for the additional hydraulic force. The armature space 25 on both sides of the magnet 26 is in this embodiment ver connected to the tank, so that the end face of the spool 10 facing the armature is relieved of pressure. This embodiment also has a relatively low manufacturing cost and also the advantage that the pressure control valve is suitable for high pressure values, since the magnet is only connected to the tank pressure.

In FIG. 4, a further embodiment is shown in which a spool valve is provided with a through hole 411,410 which connects the spaces 412 and 413 on both sides of the piston slide. The piston slide 410 carries the armature 426 of the proportional magnet 24 . The slide piston is designed on the side facing the space 413 as an additional piston 430 , the diameter D _{ZK of which is} greater than the diameter D _{K of} the piston slide. The spring 431 is also arranged in the space 413 .

As a result of the two spaces 412 and 413 via the annular groove 13 and the bore 411 acting control pressure and the differential area between the spool and the additional piston results in Fig. 4 a resul ting force. Therefore, the magnetic force must work to the right. The additional hydraulic force acts on the spool 410 in space 412 . The armature space 425 on both sides of the armature 426 is connected to the tank T.

Fig. 5 shows a similar embodiment, in which the piston slide 510 has at its end facing away from the armature 526 a projection 530 , which has a smaller diameter d _k than the diameter D _{K of} the piston slide 510 . The additional piston is thus formed by the extension 530 . The diameter D _{K of} the spool 510 on both sides of the armature 526 is the same. The resulting force thus results from the area difference determined from the diameter D _K to the diameter d _k . Both spaces 512 and 513 are connected to the annular groove 13 and thus to the control pressure via a bore 511 located in the piston slide.

A cap 540 is pushed onto the extension 530 and is arranged in a chamber 541 connected to the tank T. The cap 540 is supported on the left side of the housing. Since the outer space 541 is relieved towards the tank, there is also a leftward pressure force due to the area difference between the diameter of the spool and the projection 530 , which is compared with the rightward magnetic force.

The advantage imparted with the embodiments according to FIGS. 4 and 5 lies above all in the compact design.

Claims (18)

1.Pressure control valve with a piston slide for controlling the pressure medium paths between a control pressure channel, a channel connected to a pressure medium source and a channel connected to a tank, with a proportional magnet, the armature of which acts via a tappet on the piston valve, the actuating force applied by the proportional magnet counteracting this the force of a spring and against the control pressure on the piston slide is effective, characterized in that the control pressure also acts in the same direction as the actuating force of the proportional magnet ( 24 ) on the piston slide ( 10 , 210 , 410 , 510 ) and that of the same and against meaningful control pressure is applied to a differential area, at which a resulting force acting against the magnetic force is generated. 2. Pressure control valve according to claim 1, characterized in that the difference area corresponds to the difference between the diameter of the spool ( 10 , 210 , 410 , 510 ) and the diameter of an additional piston ( 30 , 330 , 430 , 530 ) ( Fig. 1 to 5). 3. Pressure control valve according to claim 2, characterized in that the additional piston ( 30 ) is arranged on the end of the piston slide ( 10 , 210 ) remote from the proportional magnet ( 24 ), the additional piston has a larger diameter than the piston slide, the space ( 34 ) between the additional piston and the piston slide is connected to the tank and the additional piston and the end face of the piston slide facing the proportional magnet are acted upon by the control pressure (FIGS . 1, 2). 4. Pressure control valve according to claim 3, characterized in that the piston slide ( 10 ) has two collars ( 11 , 12 ), each with a control edge ( 15 , 16 ), via which one with the control pressure channel ( 18 ) connected annular groove ( 13 ) is ver bindable with the pressure medium source or the tank, with a to the space ( 34 ) between the piston slide and the additional piston open bore ( 36 ) in the piston slide valve opens into the tank channel ( 21 ) ( Fig. 1). 5. Pressure control valve according to claim 3, characterized in that the piston slide ( 210 ) has three collars ( 208 , 209 , 212 ), of which the central collar ( 212 ) each has a control edge ( 215 , 216 ) through which the control pressure channel ( 218 ) can be connected to an annular groove ( 213 , 214 ) which is connected to the pressure medium or to a tank and is connected to the tank, whereby a bore ( 236 ) in the space ( 34 ) between the piston slide and the additional piston ( 30 ) is open Piston slide opens into the annular groove ( 213 ) connected to the tank ( Fig. 2). 6. Pressure control valve according to one of claims 3 to 5, characterized in that the armature space ( 25 ) of the proportional magnet is connected to the control pressure channel ( 18 , 218 ), the armature ( 26 ) together with the tappet ( 27 ) being pressure balanced ( Fig. 1, 2). 7. Pressure control valve according to claim 2 or 3, characterized in that the additional piston ( 330 ) is arranged on the end remote from the proportional magnet of the piston spool ( 10 ), the additional piston has a smaller diameter than the spool, the space ( 340 ) between the Additional piston and the spool is connected to the tank, the additional piston and the end face of the spool surrounding the additional piston is acted upon by the control pressure and the end face of the spool facing the proportional magnet is relieved of pressure ( FIG. 3). 8. Pressure control valve according to claim 7, characterized in that the piston slide ( 10 ) has an extension ( 334 ) in which the additional piston ( 330 ) is arranged and the extension is arranged in a pressure-charged chamber ( 335 ). 9. Pressure control valve according to claim 7 or 8, characterized in that the armature space ( 25 ) of the proportional magnet is connected to the channel leading to the tank ( 21 ), the armature ( 26 ) together with the tappet ( 27 ) being pressure balanced ( Fig. 3). 10. Pressure control valve according to one of claims 1 to 9, characterized in that the spring ( 31 , 331 ) is arranged on the end remote from the proportional magnet of the piston valve. 11. Pressure control valve according to claim 1 or 2, characterized in that the additional piston ( 430 ) is arranged on the end facing away from the piston slide of the armature ( 426 ), has a larger diameter than the piston slide ( 410 ) and the end faces of the piston slide and of the additional piston with the control pressure are applied ( Fig. 4). 12. Pressure control valve according to claim 1 or 2, characterized in that the additional piston is arranged as a seat ( 530 ) at the end of the piston valve ( 510 ), the neck has a smaller diameter than the piston valve, on the neck a cap ( 540 ) is displaceably arranged and that the end faces of the extension ( 530 ) and the piston slide are acted upon by the control pressure, the end face of the piston slide having the control pressure acting on it has the same diameter as the piston slide ( Fig. 5). 13. Pressure control valve according to claim 11 or 12, characterized in that the piston slide ( 410 , 510 ) is integrally formed and carries the armature ( 426 , 526 ). 14. Pressure control valve according to one of claims 11 to 13, characterized in that pressurized spaces are seen on both sides of the armature ( 426 , 526 ). 15. Pressure control valve according to one of claims 11 to 14, characterized in that the piston slide has two collars ( 410 , 414 , 510 , 514 ) each with a control edge ( 15 , 16 ), via which one with the control pressure channel ( 18th ) connected annular groove ( 13 ) can be connected to the pressure medium source or the tank, the spaces adjoining the piston slide and the additional piston ( 412 , 413 ; 512 , 513 ) via a bore ( 411 , 511 ) in the piston slide and in the armature with one another are connected ( Fig. 4, 5). 16. Pressure control valve according to one of claims 11 to 15, characterized in that the armature space ( 425 , 525 ) is connected to the tank ( Fig. 4, 5). 17. Pressure control valve according to one of claims 11 to 16, characterized in that the spring ( 431 ) abuts the additional piston ( 430 ). 18. Pressure control valve according to one of claims 12 to 16, characterized in that the spring ( 531 ) abuts the end ( 30 ) of the spool which is opposite the extension ( 30 ) ( Fig. 5).