DE3730381A1 - Bistable solenoid valve with permanent-magnetic holding force - Google Patents

Abstract

A valve of this type contains an armature axially movable in an elongated inner space between two working positions and having outer fluid paths in order to alternately close and open fluid passages, the armature being moved into its working positions by electromagnetic force and being held there by means of permanent magnetic force. In order to be able to operate a valve of this type with a higher fluid pressure at enlarged cross-sections of flow, the two end positions of the armature are formed by end cores with central fluid passages, the base-side end core of the valve being surrounded by a ferromagnetic sleeve which on the other side is connected to the yoke circuit. The electric coils are arranged in such a way that, in the working position of the armature, they in each case surround both the relevant end core and the associated armature section. Provided axially between the electric coils are magnetic-flux means which are connected to the yoke circuit via outer permanent-magnet means in order to contribute to an increased magnetic holding force for the armature.

Description

The invention relates to a bistable solenoid valve with permanent magnetic holding force, in which in an elongated, zen central interior between two working positions as Valve body acting armature with fluid paths axially movable is at each end of the anchor one of its working positions determining body associated with central fluid passage is in which the armature is radially opposite and its Permanent magnetic stabilizers and mag Netflußmittel are provided, which abge on the anchor side with a yoke circle, and at axially next to the permanent magnet means and the magnetic flux means an electrical coil is provided, respectively the coil in question the armature against the power supply corresponding body moves.

Such a solenoid valve is open in DE-OS 22 08 218 beard. In this valve, the two axial working positions gene of the armature acting as a valve body in each case by a Plastic part from a pipe section and from a radial Flange set, in the transition area between the Pipe section and the flange a ring open to the anchor is provided, in which the respective end ring collar  engages the anchor. The anchor is directly from a ring shaped permanent magnet, which is essentially over extends the entire length of the anchor and its end sides are covered by the two flanges. On the back of the Flanges then close the two electrical coils on, which thus surround the pipe sections mentioned circumferentially.

This known solenoid valve can only be used proportionally low fluid outputs can be controlled because the plastics NEN pipe sections may only have a relatively small axial Have fluid passage and the pressure of the fluid to be controlled ides must not exceed a relatively low value, if the force of the permanent magnet the respective, by electricity Flow of the coil in question occupies the working position the anchor should fix securely. This is essentially due to it attributed to the fact that the anchor ends in the respective work position despite the mentioned ring groove not against the yoke circle come to the system because this is due to the remaining wall thickness of the Flanges in this transition area is prevented. Thus ver there remains a considerable air gap in every working position between the armature end and yoke circle, which is the magnetic flux and thus weakens the permanent magnetic holding force relatively strong.

The task of the invention is to improve one bistable solenoid valves of the type mentioned in the introduction in that the valve is compact with a higher fluid pressure than previously can be operated and at the same time tig a larger nominal size of the flow-determining fluid has passages in its electrical control part.  

The solution to the problem starts from the introductory one Solenoid valve off and characterized by the fact that in a known tubular coil carrier with the central interior for the anchor, with a ferromagneti schem, axially opposite the anchor at one end the one with a fluid passage with the yoke circle in contact end core and with the one electrical, partially around the anchor and the end core in the axial direction giving coil is provided, the armature with two end permanent, spring-loaded sealing elements and provided with at least one fluid path on its outside is that both sealing elements are axially movable in the armature are stored that the bobbin axially extended forms and with the second electrical coil and with the magnetic flux arranged axially between the two coils means on the outside of the permanent magnet means point, it is provided that another, the other central Fluid passage and at least one on its outer circumference axial fluid path, ferromagnetic end core and a ferromagnetic sleeve surrounding this end core, which both is in contact with this end core as well as with the yoke circle, are provided that the further end core and the sleeve in the central interior of the bobbin, the other end of the Armature opposite, protrude axially, and that the second Coil the armature and the sleeve with the other end core in partially surrounds the axial direction.

In a preferred embodiment of the invention Solenoid valve exist between the radially on the coil carrier the armature and the permanent magnet means arranged Mag net flux from lamellae assembled into a package  discs and the ferromagnetic sleeve extends essentially Lichen over the entire length of the further end core. To the Simply assemble another end core and fix it securely can, he is abge by axially acting on his the anchor turned the end attacking spring means against the surrounding him fixed the ferromagnetic sleeve, which for example as a plate shaped disc spring trained spring means together with the End core and the ferromagnetic sleeve partially in a non-mag netischen receiving part are stored, the latter preferably detachable with the yoke circle and / or with the housing for the Solenoid valve is connected.

The bistable solenoid valve according to the invention can be considerable increased fluid pressure are operated than the aforementioned known solenoid valve. It is a noticeable increase in the Fluid pressure possible, which results in the main advantage tiert that the solenoid valve can also be used there, where relatively strong vibrations occur, the valve anchor even in the event of pressure loads in its respective work position is held. Furthermore, the axial fluid passages through the end cores larger in diameter be designed so that correspondingly larger flow rates can be controlled per unit of time. Instead of so far 0.8 mm can now with almost the same size and the same Operating pressure diameter up to about 2.0 mm can be applied which means an increase in cross-sectional area of over 600%. With the help of the receiving part for the further end core is one easy assembly and a secure position fixation of this end kernes reached, the receiving part also such can be further developed to the control part of the solenoid valve angularly relative to the base part of the valve if desired to be able to align.  

In EP 01 01 527 there is a pulse controlled Solenoid valve described that a tubular coil support has an axially in its central interior movable anchor acting as a valve body and on its Outside carries an electrical coil. The anchor owns outer fluid paths and two end-sided, cushioned against each other te sealing elements, one of which is an end core with a axially opposite central fluid passage, while the other, even immovable sealing element a main flow path directly opens and closes which function of a permanent magnetic force is supported.

This known valve is a monostable solenoid valve, in which, however, the permanent magnetic force to be held by a additional, space-consuming spring force is supported. In addition, no larger nominal can be used with this valve wide for the central fluid passage in the end core be used, as is also not possible, this valve operate at a higher fluid pressure.

The invention is based on one in the concerns the drawings shown embodiment closer explained. Show it:

Fig. 1 is an axial section, for example through the execution,

Fig. 2 is a cross section along line AB in Fig. 1,

Fig. 3 is a cross section along the line CD in FIG. 1,

Fig. 4 is a partially shown axial section of the embodiment in a modified form.

Referring to FIG. 1 explained the bistable solenoid valve including an electrical control portion 1, and a thus preferably releasably connected to the base part 2 with the fluid ports 3 and 4. The control part 1 consists mainly of a yoke 5 with two axially opposite end cores 6 and 7 , each having a central and axially extending fluid passage 8 and 9 , from an axially movable between the end cores and their fluid passages alternately closing armature 10th , From a coil carrier 11 , which is supported with its corresponding end sections partially on the end cores, has a central interior 12 for the armature 10 and also three outer, axially adjacent chambers 13 , 14 and 15 , from two electrical coils 16 and 17 , which are each arranged in the end chambers 13 and 15 , from magnetic flux means 18 , which are arranged in the middle chamber 14 , and from permanent magnet means 19 , the two sides with surface contact on the one hand on the magnetic flux means 18 and on the other on the yoke circle 5th issue. The control part 1 , which is surrounded by a preferably manufactured according to the injection molding technology housing 20 , has a preferably by means of snap connections 21 with the yoke 5 and / or with the housing 20 connected, non-magnetic receiving part 22 , which on the other hand in a recess 23 of the Base part 2 engages and is fastened therein, for example by pins 24 or the like.

The elongated armature 10 is provided in its interior with two end permanent, axially movable sealing elements 25 and 26 , which are pressed apart by a spring 27 , and on its outer circumference with at least one axial fluid path 28 . The further end core 7 also has at least one axial fluid path 29 on its outside and is surrounded by a ferromagnetic sleeve 30 with good surface contact, which preferably extends essentially over the entire length of the end core 7 . The sleeve 30 is connected on the one hand in good contact with the yoke 5 , for example by tight fit, and on the one hand projects centrally into the coil carrier 11 and on the other hand together with the end core 7 into the receiving part 22 . A very good magnetic flux in the further end core 7 is achieved by the ferromagnetic sleeve. The end coil chambers 13 and 15 and the electrical coils 16 and 17 provided therein are placed so that they surround both the end cores 7 and 8 and the corresponding end sections of the armature 10 , whereby a very good electromagnetic movement force is exerted on the armature when the corresponding coil is powered.

The arranged in the middle coil carrier chamber 14 magnetic flux 18 , which are directly opposite the central portion of the armature 10 , consist of a plurality of packet-like, annular laminated discs made of magnetizable metal and are on their outer side in surface contact with the permanent magnet means 19 , which in turn with good Surface contact on yoke circle 5 . The formation of the means 18 as lamellar disks nevertheless allows good surface contact with the permanent magnet means 19 with inexpensive manufacture of the disks, although they have a lower diameter accuracy compared to a one-piece magnetic flux, which should be manufactured more precisely.

The further end core 7 is, for example, axially acting spring means 31 , for example in the form of a plate-shaped disk benfeder, which engages on the end region of the core 7 facing away from the armature 10 , fixed relative to the ferromagnetic sleeve 30 surrounding it, the disc spring itself being part of the receptacle 22 is fixed. The disc spring is provided with holes 32 provide ver (Fig. 3), which are aligned with the fluid paths 29 on the periphery of the further Endkernes 7, and presses the end core 7 also under seal in an end seat 33 of the Fluidanschlus ses 3. As a result, the fluid passage 9 of the further end core is fluidly connected to the one fluid path 3 of the base part 2 , while the outer fluid paths 29 of this core 7 communicate with the other fluid path 4 of the base part, as clearly shown in FIGS . 1 and 4.

A further possibility of connecting the receiving part 22 and thus the control part 1 to the base part 2 is shown in FIG. 4, where a snap connection is shown, which is composed of arms 34 with outer beads 35 of the part 22 and a circumferential groove 36 of the base part 2 . This type of connection for parts 1 and 2 is preferably used because it enables the parts to be assembled and disassembled quickly.

Furthermore, it is possible to position the control part 1 relative to the base part 2 in different angular positions by means of positive-locking parts, for example by the receiving part 22 having knob-like projections 37 which engage in corresponding depressions 38 in the base part 2 ( FIG. 4). These positive locking means are provided several times and with the same Winkelab was arranged on a circle.

The valve described works in the following way.

Referring to FIG. 1, the short time current is acted upon by electric coil 17 has the effect that the armature 10 has come against the lower end core 7 to the plant, so that its central fluid passage 9 is closed. The armature now remains in this position, in which it is held by the force of the magnetic flux running through the parts 7 , 10 , 18 , 19 , 5 , 30 . A fluid flow can now take place along the fluid paths 4 , 23 , 32 , 29 , 28 and 8 . If, at a desired time, a brief current is applied to the other coil 16 , then said permanent magnetic flux is superimposed by the electromagnetic force of this coil and the armature 10 moves into its other end position on the end core 6 , so that its fluid passage 8 is closed The armature remains in this end position due to the permanent magnetic force flow then running mainly over the upper end core 6 . Thus, fluid communication between the fluid paths 3 , 9 , 29 , 32 , 23 and 4 is given.

Claims (9)

1. bistable solenoid valve with permanent magnetic holding force,

• in which an armature, acting as a valve body between two working positions and having fluid paths, is axially movable in an elongated central interior
• each body of the anchor is assigned a body with a central fluid passage that determines its working positions,
• in which permanent magnet means and magnetic flux means are provided which are radially opposite the armature and stabilize its working positions and which are in contact with a yoke circle on the side facing away from the armature,
• and in which an electrical coil is provided axially in addition to the permanent magnet means and the magnetic flux means, the coil in question moving the armature against the corresponding body in the case of power supply, characterized in that
• - That, in a manner known per se, a tubular coil carrier ( 11 ) with the central interior ( 12 ) for the armature ( 10 ), with a ferromagnetic, the armature at one end axially opposite, having a fluid passage ( 8 ), with the yoke circle ( 5 ) in contact end core ( 6 ) and with an elec trical, the armature and the end core in the axial direction partially surrounding coil ( 16 ) is provided, the armature ( 10 ) with two terminal, mutually sprung sealing elements ( 25 , 26 ) and is provided with at least one fluid path ( 28 ) on its outside,
• - That both sealing elements ( 25 , 26 ) in the armature ( 10 ) are axially movable,
• - That the coil carrier ( 11 ) is axially elongated and is provided with the second electrical coil ( 17 ) and with the magnetic flux means arranged axially between the two coils ( 18 ), which have the permanent magnet means ( 19 ) on their outside,
• - That another, the other central fluid passage ( 9 ) and on its outer circumference at least one axial fluid path ( 29 ) having ferromagnetic end core ( 7 ) and a ferromagnetic sleeve surrounding this end core ( 30 ), both with this end core and with that Yoke circle is in contact, are provided
• - That the further end core ( 7 ) and the sleeve ( 30 ) project axially into the central interior ( 12 ) of the coil support ( 11 ), the other end of the armature ( 10 ) opposite,
• - And that the second coil ( 17 ) partially surrounds the armature and the sleeve ( 30 ) with the further end core ( 7 ) in the axial direction.

2. Solenoid valve according to claim 1, characterized in that the on the coil carrier ( 11 ) radially between the armature ( 10 ) and the permanent magnet means ( 19 ) arranged magnetic flux means ( 18 ) consist of disks assembled into a package of discs. 3. Solenoid valve according to claim 1 or 2, characterized in that the ferromagnetic sleeve ( 30 ) extends substantially over the entire length of the further end core ( 7 ). 4. Solenoid valve according to one of claims 1 to 3, characterized in that the coil carrier ( 11 ) has three axially adjacent chambers ( 13 , 14 , 15 ) and that the middle chamber ( 14 ) receives the magnetic flux ( 18 ) while the electrical coils ( 16 , 17 ) are provided in the two outer chambers. 5. Solenoid valve according to at least one of claims 1 to 4, characterized in that the further end core ( 7 ) is fixed by axially acting, at its end facing away from the armature ( 10 ) spring means ( 31 ) relative to the ferromagnetic sleeve ( 30 ) surrounding it . 6. Solenoid valve according to claim 5, characterized in that the spring means ( 31 ) consist of a plate-shaped disc spring with holes ( 32 ), the latter to the fluid because ( 29 ) on the circumference of the further end core ( 7 ) are aligned. 7. Solenoid valve according to at least one of claims 1 to 6, characterized in that the further end core ( 7 ) and the ferromagnetic sleeve ( 30 ) surrounding it are mounted on their end portion facing the armature in a non-magnetic receiving part ( 22 ) and that the receiving part on the yoke circle ( 5 ) and / or on a yoke circle surrounding the housing ( 20 ) is preferably fastened by snap connection ( 21 ) and carries the further end core fixing spring means ( 31 ). 8. Solenoid valve according to claim 7, in which the electrical control part ( 1 ) with a two fluid paths base part ( 2 ) is connected, characterized in that the receiving part ( 22 ) on the other hand preferably by snap connection ( 35 , 36 ) on the base part ( 2 ) is fixed and that the central fluid passage ( 9 ) of the further end core ( 7 ) communicates with the one fluid path ( 3 ) of the base part ( 2 ) and the fluid paths ( 29 ) on the outer circumference of the end core ( 7 ) with the other Partly communicate the fluid path ( 4 ) of the base. 9. Solenoid valve according to claim 7 or 8, characterized in that the receiving part ( 22 ) and the base part ( 2 ) are provided with positive locking means ( 37 , 38 ) to the electrical control part ( 1 ) relative to the base part ( 2 ) in to position a desired angular position.