DE2439271A1 - Solenoid valve with main and auxiliary valve plug - opposing pole of latter slides in plug guide - Google Patents

Abstract

Previous designs of similar arrangements worked on the principle that the magnitude of the lift of the main valve plug was dependent on the lift of the armature and/or the auxiliary plug. Instead, a movable arrangement sliding inside the plug guide acts as the opposing pole, or alternately the main valve plug serves as an opposing pole for the armature, which is spring loaded and can slide against the main valve plug. The opposing pole can be an integral part of the main valve plug or arranged separately. A distancing pin can be arranged between the main valve plug and the opposing pole.

Description

7439271

PATENTANWÄLTE __ ^fcig * ^{; l} · '·'

DIPL .-! NG. LEO FLFUCHAUS

DP.-ING. HANS LEYH DIPL-ING ERNST RATHMANN

Munich 71,

Melchiorstrasse 42

Our reference: A 12 893

HERION-WERKE KG 7012 Fellbach Stuttgarter Str.

Passage solenoid valve 1

The invention relates to a straight-way solenoid valve with a main valve seat and a cooperating with this in a piston guide guided main valve piston, a magnet armature forming an auxiliary valve piston, which is connected to a Main valve piston designed auxiliary valve seat interacts / and a counter pole for the armature.

A valve of the aforementioned type is known from German patent specification 1 16 8 725. This valve has the main valve piston Cup-shaped, while the magnet armature, which forms the auxiliary valve piston, is in the cavity of the main valve piston is arranged and displaceable in this. When the magnet is excited, both valve pistons hit a stationary one Opposite pole at. The disadvantage here is that the stroke of both the main valve piston and the auxiliary valve piston is the same , i.e. in other words, the stroke of the main valve piston depends on that of the auxiliary valve piston,

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i.e. the armature. This leads to problems with valves with higher pressure ratings and larger nominal sizes, since the stroke the armature and thus the auxiliary valve piston should be kept as small as possible because of the magnetic force during in particular For valves with higher pressure levels and larger nominal sizes, a correspondingly larger stroke of the main valve piston is required.

The invention seeks to avoid these disadvantages, which is why it is based on the object of a through valve of the initially mentioned type in such a way that the stroke of the main valve piston is independent of that of the armature, i.e. the Auxiliary valve piston is.

According to the invention, this is achieved in that the opposite pole is designed to be movable and can be displaced in the piston guide is led.

Advantageously, the main valve piston itself can Form the opposite pole for the armature, which in turn is resiliently supported in the axial direction against the main valve piston.

Preferably, however, the magnet armature can also be located between the main valve piston and the opposite pole, wherein the opposite pole is either fixedly connected to the main valve piston or else can be formed separately from the main valve piston. The magnet armature can expediently be axially elastic support against the opposite pole.

In the case of the opposite pole, which is independent of the main valve piston, the latter is expediently on its opposite pole facing away from the magnet armature Side resiliently supported in the axial direction, expediently between the main valve piston and the opposite pole a spacer bolt can be arranged, the length of which is greater

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than the length of the armature through which the spacer bolt preferably extends.

Exemplary embodiments of the invention are provided below explained in detail with reference to the drawing, in the

Fig. 1 in section a valve according to the invention in current-closing Design and shows in the open position.

Fig. 2 shows in section the valve according to FIG. 1 in the closed position.

Fig. 3 shows in section a further embodiment of the invention in current-opening design and in closed position.

Fig. 4 shows the valve of FIG. 3 in section in an open Position.

Fig. 5 shows a modification of the valve of Fig. 3, i. current-opening design, in the closed position.

Fig. 6 shows in section the valve according to FIG. 5 in the open position.

The straight-way solenoid valve 10 according to FIG. 1 comprises a housing 12, a magnet 11, an inlet 22 and an outlet 24. In the housing 12, a magnetic closure sleeve surrounded by the magnet 11 is arranged, which here also has the function a piston guide 14 has. In the piston guide 14, the main valve piston 16 is axially guided with radial play. The main valve piston has a closure piece 18 which cooperates with a main valve seat 20. On his the breech block

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opposite end face is the main valve piston 16 with an auxiliary valve seat 26 from which a e.g. through-hole 28 extending along its central axis through the entire valve piston 16. Above the valve piston 16, a magnet armature 30 is arranged in FIG. 1, which is also guided axially in the piston guide 14 with radial play is. The magnet armature 30, which forms an auxiliary valve piston, has a closure piece 32, which can for example be a soft seal and the one with the auxiliary valve seat 26 at the rear End of the main valve piston 16 cooperates. The closure piece 32 is through a bore, not shown in detail of the armature 30 arranged compression spring 34 is elastically supported in the axial direction. In another also not designated A compression spring 36 is arranged in the bore of the magnet armature 30 and loads a spacer pin 38 in the axial direction. which holds the armature 30 at an axial distance from the main valve piston 16, so that there is a gap between this and the armature 52 (when the magnet is not excited) is formed.

The armature 30 strikes axially on a nose 40

Transverse wall 51 of the piston guide 14, which in turn is held in the housing by a nut 15. The holes which accommodate the springs 34 and 36, are relieved of pressure through suitable transverse bores, which are not designated.

As FIG. 2 shows, the main valve piston 16 is provided with a collar 42 which abuts against a shoulder 44 of the piston guide 14 can, thereby defining the stroke of the main valve piston and is limited. An axial bore 46 runs through the collar 42, through which the pressure medium enters an annular gap 48 flow in between the piston guide 14 and the main valve piston 16 or the magnet armature 30 and into a space 50 above the Magnet armature can occur.

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243927

In the embodiment of FIG. 3, the main valve piston is 16 is provided with an elongated tubular collar 60, with its end 61 a magnetic counter pole 62 for the magnet armature 30 is firmly connected in a suitable manner. In the embodiment shown in FIG. 3, the opposite pole 62 has a shoulder 63, which rests against the front end 61 of the collar 60. The section 65 of the counter pole has essentially the same diameter like the outer diameter of the collar 60, while the section 67 protruding into the collar 60 has a diameter, which corresponds essentially to the inner diameter of the collar 60.

Between the main valve piston 16 and the opposite pole 62 is in Inside the collar 60 of the armature 30 is arranged to be axially movable with radial play.

An axial through-hole 68 extends through the opposite pole 62 and has an enlargement in which a compression spring 66 is arranged, which acts on the end face of a short pipe socket 64 which is held in the magnet armature 30. The magnet armature 30 is pressed off by the spring 66 from the opposite pole 62 (when the magnet is not energized), so that, as shown in FIG shows, between the opposite pole and the armature, a gap 74 is formed. The bore 68 is above the bore 69 of the pipe socket 64, one with this aligned bore 71 in the armature 30 and a transverse bore 70 with an axial extending channel 72 and a space 76 between the armature and the main valve piston in connection. The opposite pole is provided with a nose 82 which, as FIG. 4 shows, can strike the transverse wall of the piston guide 14. Part of the tubular collar 60 of main valve piston 16 consists of a magnetic locking ring 80 because of the magnetic flux.

In Fig. 5, which is a modification of the embodiment of Fig.

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shows, the opposite pole 62 is spatially separated and independent of the Main valve piston 16 is formed. Here, as in the embodiment According to FIGS. 3 and 4, however, the opposite pole 62 is arranged within the piston guide 14 with radial play and guided. The magnet armature 30 is in turn supported resiliently ;; a compression spring 90 and a spacer pin 92 on the opposite pole 62, so that the gap 74 is formed (when the magnet is not excited) will. The opposite pole 62 is supported by a compression spring 100 and a spacer pin 94, both with radial play in a blind hole 96 of the opposing pole are arranged elastically against the Jase 40 in the axial direction. The blind hole 96 is through a small cross hole 98 relieved of pressure.

In the embodiment described here, the magnet armature 30 is also axially between the opposite pole 62 and the main valve piston 16 arranged and movable in the axial direction. With a section 106 that has a reduced diameter has, the armature 30 engages into the interior of the tubular collar 60 with radial play so that between the Outer diameter of the section 106 and the inner diameter of the collar 60, an annular gap 102 is formed.

In the axial direction, an unspecified through-hole extends through the armature 30, in which there is play a spacer bolt 104 is arranged, the length of which is greater than the length of the armature 30 and which couples the opposite pole 62, as will be explained, with the main valve piston 16.

The valve according to the invention works as follows:

In the embodiment according to FIG. 1, the magnet 11 is not excited. The main valve piston 16 is controlled by the pressure of the medium

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pushed up from the inlet 22 and thus the main valve seat 20 open. The penetrating through the bore 46 and the gap 48 in the space 52 medium is through the open auxiliary valve 26 and the bore 28 led to the outlet 24. (In the bore 28 an unspecified tube can sit, which is something in the Drain 24 extends into it). The auxiliary valve seat 26 is open, since there is no force acting on the armature 30 when the magnet 11 is not energized, so that it is caused by the spring 36 and the spacer pin 38 is pressed off by the main valve piston 16. Its upper end in the drawing strikes against the nose 40. The hub of the main valve piston 16 is delimited by the shoulder 44 of the piston guide 14.

If the magnet 11 is now excited, the magnetic flux closes via the magnet bracket 13, the magnet armature 30 and the main valve piston 16. The armature 30 is thereby against the force of the spring 36 on the end face 54 of the main valve piston 16, the forms the opposite pole here, pulled, the spacer pin 18 being pushed back. Here, the locking piece 32 of the The magnet armature, as shown in FIG. 2, is pushed back against the force of the spring 34 and the auxiliary valve seat 26 is closed. That Medium flowing in via the gap 4 8 can no longer be discharged through the auxiliary valve, so that in the space 50 between the end wall 51 of the piston guide and the upper end of the magnet armature 30 in the drawing, the full pressure of the medium builds up, whereby the armature 30 and the main valve piston 16 are pressed down until the latter is on its valve seat 20 sits and closes the latter, as shown in FIG.

When the magnet is excited, the valve is closed (current-closing design) and when the The solenoid is opened again by the medium pressure, whereby the magnet armature is initially pressed off the main valve piston 16 and the

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Auxiliary valve is opened, whereupon the main valve piston 16 from Medium pressure is increased again.

In the embodiment of FIG. 3 (magnet not excited) the main valve piston 16 by the pressure of the medium flowing from the inlet through the gap 48 into the space 50 above the counter pole 62 flows, pressed against its valve seat 26 and thus the valve is closed. If the magnet is switched on, (Fig. 4) so the magnetic flux closes via the magnetic bracket 13, the opposite pole 62, the magnet armature 30 and the magnetic locking ring 80. As a result of the magnetic force, the magnet armature 30 is drawn against the force of the spring 66 onto the end face 54 of the counter pole 62 and the auxiliary valve 26 is opened. The medium in the space 50 can now through the axial bores 68, 69 and 71, the transverse bore 70 and the channel 72 to the space 76 and thus flow through the open auxiliary valve 26, whereupon the main valve piston 16 is raised by the pressure of the medium coming from the Zuluaf 22 acting on its end face and the main valve 20 is opened will.

In the embodiment according to FIGS. 3 and 4, the Valve opened by energizing the magnet (current-opening design). If the magnet is switched off again, the magnet armature becomes 30 is pressed off by the spring 66 from the opposite pole 62 and the auxiliary valve 26 is closed. Builds in room 50 above the opposite pole then again the full pressure of the medium flowing in through the gap 48, whereby the opposite pole together with the The main valve piston is pressed down onto the main valve seat 20 and the latter is closed.

The embodiment according to FIGS. 5 and 6 is a modification the embodiment of Figures 3 and 4, i.e. by excitation of the magnet, the main valve is opened (current-opening design).

In Fig. 5 (magnet not energized) the opposite pole 62 is through the

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Spring 100 pressed down in the drawing, the spring force and the movement of the counter pole can be transmitted via the spacer bolt 104 to the main valve piston 16, which is thereby is pressed onto its valve seat 20 so that the main valve is closed. The magnet armature 30 is in this case from the opposite pole 62 also pressed down via the spacer pin 92 and the spring 90, so that its closure piece on the auxiliary valve seat 26 sits up and the latter is also closed.

If the magnet is energized (Fig. 6), the magnetic flux via the magnetic bracket 13 is the opposite pole 62, the armature 30 and the tubular collar 60 of the main valve piston 16 closed. As a result, the magnet armature is counteracted by the force of the spring 90 is drawn to the end face 54 of the counter pole 62 and thus the auxiliary valve 26 is opened. The pressure in space 76, which is above the Gap 102 and gap 48 are connected to the inlet, can now be reduced via the opened auxiliary valve 26, since the medium from the chamber 76 through the bore 28 to the drain 24 can flow (the cross-section of the bore 28 is correspondingly larger than the inlet cross-section of the gap 48 or of the gap 102) whereupon the main valve piston; * 16 by the medium pressure acting on its end face from the inlet 22 from its valve seat 20 is lifted and the latter is opened. The movement of the main valve piston 16 is controlled by the spacer bolt 104 transferred to the opposite pole 62, which is pressed against the force of the springs 100 upwards until e-r, as FIG. 6 shows, abuts the nose 40. If the magnet is switched off again, the magnet armature 30 is activated by the spring 90 and the spacer bolt 92 pressed off again from the opposite pole 62 and the auxiliary valve 26 closed, whereupon the main valve piston by the spring 100 and pressed down again by the pressure of the medium in space 76, which is in communication with the inlet via gaps 48 and 102 and the main valve 20 is closed.

The invention makes it possible both with current-closing as well

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to make the stroke of the main valve piston independent of that of the magnet armature (ie the auxiliary valve piston) in the current-opening design, so that the main valve is at high pressure levels and on
large nominal diameters can be adapted and used for this, during the stroke of the magnet armature , to a strong magnetic force
to be maintained, is small or smaller than the stroke of the main valve piston.

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ORIGINAL INSPECTED

Claims (10)

2,3927 claims 1. Passage solenoid valve with a Hauptventil.sitz and a ^v - with this cooperating main valve piston guided in a piston guide, a magnet armature forming an auxiliary valve piston, which cooperates with an auxiliary valve seat formed on the main valve piston, and an opposite pole for the magnet armature, characterized in that the opposite pole (16, 62) is designed to be movable and is guided displaceably in the piston guide (14). 2. Valve according to claim 1, characterized in that that the main valve piston (16) forms the opposite pole (62) for the magnet armature (30). 3. Valve according to claim 1 or 2, characterized in that the magnet armature (30) in the axial direction is resiliently supported against the main valve piston (16). 4. Valve according to claim 1, characterized in that that the magnet armature (30) is arranged axially between the main valve piston (16) and the opposite pole (62). 5. Valve according to claim 4, characterized in that that the armature (30) is axially resiliently supported against the opposite pole (62). 6. Valve according to claim 4, characterized in that that the opposite pole (62) is firmly connected to the main valve piston (16). 7. Valve according to claim 4, characterized in that - 12 - ■ 6 09811/0 ^ 5 9 ORiGlNAL INSPECTED -IZ- n e t that the opposite pole (62) is separated from the main valve piston (16) is formed. 8. Valve according to claim 7, characterized in that that the opposite pole (62) is resiliently supported in the axial direction on its side facing away from the armature (30) is. 9. Valve according to claim 7, characterized in that between the main valve piston (16) and the Opposite pole (62) a spacer bolt (104) is arranged, the length of which is greater than the length of the magnet armature (30). 10. Valve according to claim 9, characterized in that that the spacer bolt (104) extends axially through a bore in the armature (30) and in this with Game is performed. 0 9 8 1Wf- * ' β 9 ORIGINAL INSPECTED