DE1945064C3 - Directional control valve - Google Patents

Description

The invention relates to a directional valve with a piston valve that can be moved longitudinally in the housing, which protrudes with both ends into pressure chambers of the housing provided with control connections and by alternately pressurizing its end faces and one in one of the pressure chambers the piston slide end cooperating annular piston in one of two end positions or one Middle position can be held, including the annular piston relative to the housing and the piston valve axially movable on one of the outer diameter of the slide via one as a stop for the annular piston Serving stage remote cylinder attachment is placed and for which purpose the annular piston and the opposite The end of the piston valve is assigned a stop fixed to the housing and in which the seldom des The end face located on the annular piston is smaller than the opposite end face, which in turn is smaller is the sum of the areas of the annular piston and the associated face of the cylinder attachment of the Piston valve.

In a known directional control valve of this type (DT-Gbm 19 51 773) is a cylinder attachment Control spool an annular piston arranged To center the control spool in a central position, both ends of the control spool together with the annular piston must be under pressure. Except this one Negative control, the directional control valve cannot be used for another type of control, so this Directional valve is only usable to a limited extent

The object of the invention is to design a directional control valve of the specified type so that it is more versatile becomes usable.

This is achieved according to the invention in that the cylinder attachment has a second slide-side Has stop for the annular piston that in the pressure chamber receiving the annular piston, a second Fixed stop is arranged that the diameter of the piston valve on the cylinder base a second pressure chamber is assigned which is connected to a third control connection, and that the effective area of the annular piston is greater than that of the step on the cylinder base.

In this way, the directional control valve is not only suitable for a negative control, but also for a positive control and can daTier versatile can be used.

Particularly useful refinements of the subject matter of the invention result from the subclaims, which particularly favor a simple design of the directional control valve.

An embodiment of the invention is shown in the drawing, namely shows

F i g. 1 a 5/3-way valve for positive control in the middle position,

F i g. 2 there? same valve in his right and

F i g. 3 in its left end position,

F i g. 4 the same 5/3-way valve for negative control in middle position,

Fig. 5 shows the valve in the control according to Fig. 4 in his right and

F i g. 6 in its left end position.

A 5/3-Wegcventil has a cuboid housing 1, which is a continuous, cylindrical Has hole 2. In this bore 2 a slide sleeve 3 is used, which on its cylindrical surface carries six O-rings 4. Between the O-rings 4 is the Provide the outer surface of the slide sleeve 3 with five ring recesses 5. The ring recesses 5 are on each one in Figs. 1 to 6 each lower point via radial, through the wall of the sleeve 3 and the Housing 1 leading openings 6 connected to an inner longitudinal bore 7 of the slide sleeve 3. the Slider sleeve 3 is held in place in the housing by means of two equally long spacer sleeves 8 and 9, which are connected to their Support the outer ends with a sealing plate 10 in between on two covers 11. The two covers 11 close the hole 2 to the outside.

In the bore 7, a piston valve 12 is inserted longitudinally movable, the outer surface of which has two Has annular grooves 13, the edges of which act as control edges and thereby with the in the wall of the Longitudinal bore 7 lying mouths of the openings 6 cooperate. The piston valve 12 is longer than the slide sleeve 3. Beyond this greater length, it still has one on each side

Cylinder attachment 14,15, with which he the spacer necks 8 or 9 can penetrate completely and strike the sealing plates 10. The right approach 14 is smooth cylindrical, the left extension 15, however, has a narrow annular groove 16 into which a snap ring 17 is inserted This snap ring 17 is used, as will be explained later is, as a left stop for an annular piston 18, which is placed on the approach 15 and between the Snap ring 17 and a step 19 at the transition from the extension 15 to the lateral surface of the slide 12 is longitudinally movable. The annular piston 18 has an annular recess 18 ', the outer diameter of which is larger is than that of the piston valve 12, and is inside and outside by a sealing ring 20 and 21 opposite the The outer surface of the projection 15 and the inner surface of the spacer sleeve 9 are sealed. In this inner surface is still a snap ring 22 is let in, which also serves as a stop for the annular piston 18.

The spacer sleeves 8 and 9 each have an O-ring 23 on their cylindrical outer surface. The outer diameter of the spacer sleeves 8 and 9 is reduced on both sides of these O-rings, so that two annular spaces 24, 24 'and 25, 25' are created. The inner (24, 24 ') of these annular spaces is connected to pressure spaces 28 and 29 via radial openings 26 and 27 in the spacer sleeves 8 and 9. The left pressure chamber 29 is separated by the annular piston 18 from a pressure chamber 30 which is connected to a radial housing bore 32 via a recess 31 in the sealing plate 10. In addition to this bore 32, four radial bores 33, 34, 35 and 36 are provided in the housing I.

The bore 33 opens into the annular space 24 and the bore 35 into the annular space 24 '; the hole 34 in the middle of the annular recesses 5, and the bore 36 leads over the annular space 25 'and the recess 31 in the pressure chamber 28. A cover plate 37 is placed on the housing 1, which covers the bores 32 and 36 closes off, but connects the bores 33 and 34 to one another through a channel 37 '.

On the underside of the housing 1 two lateral bores 38 and 39 are provided, which in the outer Annular spaces 25, 25 'and lead from there into the pressure spaces 28 and 30. Five housing connections 40 to 44 serve in a known manner as inlet (40), consumer connections (41 and 42) and return connections (43 and 44). The named bores and connections are all through a sealing plate 45 passed through, on which the housing 1 is placed. It should also be noted that the cross-sections of the Approach 15, the piston valve 12 and the annular piston 18 to each other an increasing area ratio exhibit. In the exemplary embodiment, the ratio 1: 2: 3 was chosen. But it can also be a other increasing ratio can be used.

The directional control valve described works as follows:

In the so-called positive control according to FIGS. 1 to 3, the slide is in each case through Postponed pressure increase. In the middle position according to FIG. 1, the inlet connection 40 is under pressure. the Inlet pressure then also prevails in the middle ring recess 5, in the bore 34 and over the Channel 37 'in the bore 33. From there it passes through the annular space 24 and the radial opening 27 in the Pressure chamber 29. The annular piston 18 is shifted to the left until it strikes the stop 22. the Piston slide 12 is pressed to the right by the action of pressure on step! 9, until stop 17 hits

the annular piston 18 strikes

Because the annular surface of the annular piston 18 is three times larger than the annular surface of the step 19, remains the piston valve 12 are in the center position shown, it is positive there due to the pressure medium locked In this middle position, the inlet 40 of the piston valve 12 is different from the ones at 41 and 42 connected consumers separately, and the return flow ports 43 and 44 are closed.

The F i g. 2 shows the piston valve 12 in its right end position, which it reaches when pressure medium flows into the bore 39. The inlet connection 40 can also receive pressure medium (see arrow). From the bore 39 the pressure medium reaches the left pressure chamber 30. It acts there on the end surface of the projection 15 and on the annular piston 18. The predominant force on the parts 15 and 18 located in the chamber 30 due to the area ratio pushes the slide 12 into its right end position. In space 30 , an area is acted upon which is twice as large as the area which acts in the opposite direction in space 29 and which results from the annular surface of the annular piston 18 minus the annular surface of the step 19. The end face of the projection 15 is equal to the annular surface of the step 19. In this position of the valve, the inlet 40 is connected to the one consumer via the connection 42 and the other consumer connected at 41 to the return connection 43.

In FIG. 3 the piston valve assumes its left end position. It reaches this when the bore 38 and the pressure chamber 28 to the right of the slide 12 receives pressure. In addition, inlet 40 is also back vacuum. Since the entire slide surface (i.e. approach 14 plus stage 19) is acted upon in space 28 and in the Space 29 in the opposite direction is the annular surface of the stage 19, which is a quarter of the total slide surface including that of the annular piston is effective, the piston slide is in the specified position pressed. The inlet 40 is then connected via the connection 41 to one consumer and the other at 42 connected consumers with the return connection 44 connected.

Figures 4 to 6 show the same valve as that Figs. 1, 2 and 3, only in circuit caused by a pressure drop.

Has the valve been shown in FIG. 1 to 3 are only switched by increasing the pressure (positive control) Valve in FIGS. 4 to 6 back and forth due to pressure drop moved forward (negative control) and locked in the middle position with pressure. Here, however, becomes a different one Plate placed on the valve housing. This plate 47 has a through hole 48 which communicates with the hole 32 aligned, a through hole 49 and a through hole 50, which with the bores 33 and 36 correspond. A line branching into two line strands 51 and 52 is attached to the bore 34 connected. The lines 51 and 52 each lead via a normally open solenoid valve 53 and 54, respectively the bores 48 and 50. A sealing plate 55 under the housing 1 closes the bores 38 and 39, but leaves the inlet 40 and the connections 41 to 44 open.

Ii. In this circuit, the directional control valve works as follows:

Via the connection 40, the bore 34, the two line strands 51 and 52, the open solenoid valves 53 and 54, the bores 48 and 50 as well as 32 and 36, the two ends of the piston valve 12 are under pressure. The Riiigkoiben iS go to the right until it is on the left

Front face of the slide sleeve 3 strikes. This sets (F i g. 5) or left (F i g. 6) end position is above one <

the annular piston 18 adjoins the step 19. Since the on the two solenoid valves 53 or 54 of the left (30) or <

entire slide face (approach 14 plus step 19) right space (28) relieved. The slider will a

force acting to the left is greater than that to the right by relieving pressure on one side at a time

Directed force on the extension 15, the slide 12 is moved in the .., and this type of control becomes Negal

Center position (Fig. 4) locked. called control.
To reverse the piston valve 12 to the right

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Directional control valve with a piston valve which is longitudinally displaceable in a housing and which with its protrudes at both ends into pressure chambers of the housing provided with control connections and through alternating pressurization of its end faces and one in one of the pressure chambers with the Piston slide end cooperating annular piston in one of two end positions or one Middle position can be held, including the annular piston relative to the housing and the piston valve axially movable on one of the slide outer diameter via a stop for the Ring piston serving step is attached to the remote cylinder attachment and for which purpose the ring piston and The opposite end of the piston valve is assigned a stop fixed to the housing and at where the end face located on the seldom of the annular piston is smaller than the opposite End face, which in turn is smaller than the sum of the areas of the annular piston and associated End face of the cylinder attachment of the piston valve, characterized in that the cylinder attachment (15) has a second stop (17) on the slide side for the annular piston (18), that in the pressure chamber (30) receiving the annular piston (18) there is a second stop fixed to the housing (22) is arranged that the diameter step (19) of the piston valve (12) on the cylinder attachment (15) a second pressure chamber (29) is assigned which is connected to a third control connection (33) has, and that the effective area of the annular piston (18) is greater than that of the step (19) on Cylinder attachment (15). 2. Directional valve according to claim 1, characterized in that in the end region d <; s cylinder attachment (15) a snap ring (17) is arranged as a two-way stop on the slide side. 3. Directional control valve with a slide sleeve receiving the cylinder slide and two slide sleeves Spacer sleeves centering in the housing according to claim 1 or 2, characterized in that as second stop fixed to the housing a into the spacer sleeve (9) receiving the annular piston (18) inserted snap ring (22) is used.