DE3338111C2 - magnetic valve - Google Patents

Abstract

The invention relates to a valve with a valve chamber arranged in a valve housing with inlet and outlet openings, a valve seat arranged around the inlet opening, a valve body movable in the valve chamber between a blocking position and a flow position and a closing device for the valve body, wherein the valve body has a permanent magnetic element and a permanent magnetic closing magnet is provided on the valve seat and/or on the side of the movement path of the valve body facing away from it. The closing magnet is arranged in such a way that it permanently forces the valve body into its blocking position by the action of magnetic force.

Description

The invention relates to a solenoid valve with a valve housing, a valve chamber arranged therein with an inlet opening and an outlet opening, a valve seat arranged in the valve chamber around the inlet opening, a permanent magnetic closure piece arranged in the valve chamber and axially displaceable between a closed position and an open position lifted off the valve seat, and a permanent magnetic closing magnet arranged coaxially in the valve chamber on the side of the closure piece facing away from the valve seat and urging the latter into its closed position by magnetic poles of the same name facing one another.

In the solenoid valve of this type known from US-PS 26 67 895, the permanent magnetic closure piece and the closing magnet are each directly wetted by the flow medium flowing through the valve chamber, which leads to rapid corrosion and failure of the valve when aggressive liquids are conveyed. In addition, there is a risk that the closure piece will collide hard with the closing magnet when the valve is opened, which quickly reduces the permanent magnetization of both parts.

From DE-AS 10 51 589 a valve is also known for installation in the closure plug of a container, which has a closure piece which can be moved axially in a valve housing and has a magnet embedded in plastic, which is urged into its closed position against a valve seat at the outlet opening by closing magnets embedded in the valve housing, whereby a spherical element holds the closure piece in its open position by its gravitational effect as long as the container is not tilted by a predetermined angle. This known design requires very large housing cross-sections and uses closing magnets arranged laterally next to the movement path of the closure piece, so that the interacting pole faces of the magnets are not coaxially opposite one another and only relatively small closing forces are achieved.

Finally, DE-OS 30 14 690 discloses a magnetically operated shut-off valve which has a spherical shut-off element with a central flow bore which is rotatably mounted in a flow channel and which is rotated via a rotatable actuating shaft with rare earth/cobalt magnets arranged thereon by rotating a carrier with rare earth/cobalt magnets which surrounds it. However, this valve is complicated and bulky and, moreover, cannot be used for automatic opening by a predetermined pressure of the flow medium.

The object of the invention is therefore to provide a solenoid valve of the type mentioned at the outset which, despite its simple construction, operates reliably over the long term even with highly corrosive flow media.

To achieve this object, the solenoid valve of the type mentioned at the outset is equipped according to the invention with the features listed in the characterizing part of claim 1.

Since all valve parts that come into contact with the flow medium can be coated with corrosion-resistant material, such as polytetrafluoroethylene, without significantly weakening the spring effect of the permanent magnets, the valve's possible applications are only limited by the resistance of this coating material. By selecting the permanent magnetic rare earth materials and their spacing from one another, the closing force of the valve can be selected within a wide range.

An advantageous embodiment of the solenoid valve is described in subclaim 2.

In the following, preferred embodiments of the solenoid valve are further explained with reference to the accompanying drawings.

It shows

Fig. 1 a solenoid valve according to the invention and

Fig. 2 a modified solenoid valve.

The valve housing 1 of the solenoid valve shown in Fig. 1 consists of a main part 1a containing a valve chamber 2 and an outlet part 1ab with a sealing ring 1d inserted between them and connected to the main part 1a by a connecting ring 1c . The valve chamber 2 has an inlet opening 3 and an outlet opening 4. In the valve chamber 2 , a valve seat 5 is arranged around the inlet opening 3 , which is enclosed on the outside of the valve by a sealing ring 5a for the sealing connection of a supply line (not shown). A closure piece 6 is arranged in the valve chamber 2 , which is movable between a closed position resting against the valve seat 5 and an open position raised therefrom and is urged by a closing device 7 in the direction of the valve seat 5 , against which it rests in the closed position in such a way that a sealing ring 6a arranged on the side of the closure piece 6 facing the valve seat 5 is pressed sealingly against the valve seat 5 .

The closure piece 6 contains a permanent magnet rare earth magnet element 8 which is completely enclosed by a casing made of material which is corrosion-resistant to the flow medium. Between the closure piece 6 and the outlet opening 4 there is a closing device 7 in the form of a closing magnet 9 made of rare earth material which is also completely enclosed by a casing made of corrosion-resistant material, so that the mutually facing magnetic poles of the magnet element 8 of the closure piece 6 and the closing magnet 9 have the same name. The closing magnet 9 therefore repels the magnet element 8 and forces the closure piece 6 into its closed position resting on the valve seat 5 .

If the pressure of the flow medium acting on the closure piece 6 via the inlet opening 3 becomes greater than the sum of the repulsive force of the closing magnet 9 holding the closure piece 6 in its closed position and the force of any back pressure from the flow medium contained in the valve chamber 2 , the closure piece 6 lifts off the valve seat 5 and thus allows the flow of flow medium through the inlet opening 3 into the valve chamber 2 and past the closing device 7 through the outlet opening 4. The closure piece 6 and the closing device 7 are dimensioned such that sufficiently large flow openings for the flow medium remain between their outer peripheral surfaces and the inner wall of the valve chamber 2. The outer peripheral edges of the closing device 7 and the closure piece 6 are slightly rounded in order to prevent tilting in the valve chamber 2 , which is also helped by the small distance between them, which prevents a greater inclination against the longitudinal axis of the valve. By using permanent magnetic rare earth materials, particularly high magnetic forces are achieved. The repulsion force between the closure piece 6 and the locking device 7 , which increases with increasing proximity, is selected so that under normal operating conditions, even if the solenoid valve is suddenly opened, the closure piece 6 does not come into contact with the locking device 7. This protects the permanent magnetization of the magnets and prevents any impact damage to the parts.

Fig. 2 shows a modified solenoid valve in which additional closing magnets 9' are arranged in the area of the valve seat 5 , which are directed with opposite magnetic poles towards the poles of the magnetic element 8 facing them and thus pull the closure piece 6 into its closed position. All closing magnets 9 push the closure piece 6 towards the valve seat 5. With a suitable choice of closing magnets 9 and 9', the attractive force of the closing magnets 9' arranged near the valve seat 5 increases as the repulsive force of the closing magnet 9 decreases, so that the magnetic force acting on the closure piece 6 remains largely the same over almost its entire path of movement. Only when the repulsive closing magnet 9 is approached closely does the repulsive force increase so much that a stop of the closure piece 6 against the closing magnet 9 is prevented. The solenoid valve shown in Fig. 2 has a higher closing force compared to the one shown in Fig. 1.

Claims (2)

1. Solenoid valve with a valve housing ( 1 ), a valve chamber ( 2 ) arranged therein with an inlet opening ( 3 ) and an outlet opening ( 4 ), a valve seat ( 5 ) arranged in the valve chamber ( 2 ) around the inlet opening ( 3 ), a permanent magnetic closure piece ( 6 ) arranged in the valve chamber ( 2 ) and axially displaceable between a closed position and an open position raised from the valve seat ( 5 ) and surrounded by the flow medium, and a permanent magnetic closing magnet ( 9 ) arranged coaxially in the valve chamber ( 2 ) on the side of the closure piece ( 6 ) facing away from the valve seat ( 5 ) and urging the latter into its closed position by magnetic poles of the same name facing one another, characterized in that
a) the closure piece ( 6 ) consists of at least one rare earth magnetic element ( 8 ) which is protected by a casing made of material resistant to the flow medium and completely enclosing the magnetic element ( 8 ), b) the closing magnet ( 9 ) also consists of a rare earth material, which is also protected by a casing made of material resistant to the flow medium and surrounded by the flow medium, and c) the mutually repelling permanent magnetic forces of the closing magnet ( 9 ) and the magnetic element ( 8 ) of the closure piece ( 6 ) are such that the closure piece ( 6 ) does not strike the closing magnet ( 9 ) even if the valve is suddenly opened.
2. Solenoid valve according to claim 1, characterized in that the valve seat ( 5 ) is formed on a part facing the magnetic element ( 8 ) of the closure piece ( 6 ) with opposite magnetic poles of at least one further closing magnet ( 9 ) completely embedded in corrosion-resistant material.