DE29722208U1 - Distribution valve - Google Patents

Description

The present invention relates to a distribution valve according to the preamble of claim 1.

Distribution valves are used to control the flow of fluid between two fluid paths. Distribution valves are commonly used, for example, in central heating systems to selectively supply hot water from a boiler to either the house's hot water system or the heating system.

Such distribution valves are usually provided directly in the boiler, especially in a combined boiler. This means that such a distribution valve has to meet special requirements in terms of price, power consumption and response time.

The manifold valves currently in use normally operate with a return spring. In such a design, the valve actuator must both overcome the force of the return spring to close a first port and apply the required closing pressure to the first port. If the actuator is not activated, the return spring pulls the valve back towards the second port and applies the required closing pressure to the second port. In many designs of the valve equipped with a return spring, power must be provided continuously if the valve must be held in the position to close the first port against the force of the return spring.

It is therefore an object of the present invention to provide a distribution valve which overcomes the problems of known valves.

According to the present invention, a distributor valve is provided with a valve component that can be displaced to close a selected one of two connections, and a magnetically lockable, bistable actuating device that is designed to displace the valve component between the two connections, the actuating device being designed to lock in each of the two end positions with the aid of magnetic force, and the valve component closes one of the two connections in each of the two end positions.

In one embodiment of the distributor valve according to the invention, the actuating device is designed to magnetically lock in each of its two end positions. This means that the closing force for each connection is caused by magnetic forces, so that the actuating device does not need to be supplied with energy to hold it in one of its two end positions. Since the actuating device is designed to

is designed to move the valve component between the two connections, there is no need to provide a return spring.

In a preferred embodiment, the actuating device contains a solenoid that can be locked by means of magnetic force and is designed to displace an elongated drive rod along its length in each of the two opposite directions, wherein a displacement of the drive rod causes a displacement of the valve component.

The actuator rod can, for example, be connected directly to the valve component. Alternatively, the actuator rod can be coupled to a valve component holder.

In a preferred embodiment, the two valve ports are in mutual alignment with each other, and the valve member support includes an elongated support rod that supports the valve member and that extends through each of the two valve ports. By displacing the support rod along its length, the valve member is displaced between the two ports.

In a preferred embodiment, the solenoid has two coils between which an annular permanent magnet is provided. In addition, a piston made of a magnetic material extends axially relative to the two coils and to the permanent magnet, so that energizing one or both coils with direct current causes displacement of the piston. The displacement of the piston causes a force to be applied to the elongated drive rod.

In one embodiment, the coils are connected to

separately from each other with direct current of the same polarity. In another embodiment, the coils are connected to be fed simultaneously, but the

Polarity of the supplied direct current can be selected depending on the desired position of the valve component.

Some embodiments of the present invention are described below with reference to the accompanying drawings, in which:

Figure 1 shows a distribution valve of the present invention, wherein

the valve body is shown in cross section,
10

Figure 2 shows an actuating device of the valve of Figure 1, and

Figures 3a and 3b show various electrical circuits for supplying the actuating device from Figure 2.

Figure 1 shows a distributor valve 10 for controlling fluid flow between two different fluid paths. The first fluid path leads from an inlet 2 to a common outlet 4 and the other fluid path leads from an inlet 6 to the common outlet 4. It will be understood that the distributor valve 10 may alternatively be used with a common port 4 serving as an input port, whereby fluid flow may be selectively directed to the outlet port 2 or to the outlet port 6. The path of fluid flow through the valve 10 is determined by the position of a valve member 8. As can be seen in Figure 1, the valve member 8 is supported on an elongated support rod 12 and is displaceable to selectively close a first valve seat 14 or a second valve seat 16. The support rod 12 extends out of the valve housing through suitable sealing means, generally indicated at 20.

At its upper end, the support rod 12 is coupled to an actuating device 24 by means of a coupling 22. In the embodiment shown, the actuating device 24 is

held on a support arm 26 which is attached to the housing of the distributor valve 10. As described below, the actuating device 24 is designed to move the support rod 12 up or down along its length, whereby the valve component 8 is selectively brought into sealing engagement with one of the two valve seats 14 or 16.

A portion of the actuator 24 is shown in Figure 2. As can be seen, the actuator 24 is a bidirectional solenoid having a first coil 30 and a second coil 32, each disposed on either side of an annular permanent magnet 34. A piston 36 made of a magnetic material extends axially relative to the permanent magnet 34 and to the two coils 30 and 32. The piston 36 is connected to a drive rod 38 which is connected to the valve support rod 12 by means of a coupling 22. The solenoid coils 30 and 32 are disposed in a magnetic housing 40 and an associated stop 42 is provided at each end. The stops 42 are also made of a magnetic material and form part of the magnetic path represented by the magnetic field lines in Figure 2.

In operation, the coils 30 and 32 are energized to magnetize the piston 36, whereby the piston 36 is either attracted to or repelled by the permanent magnet 34. The stops 42 determine the end positions of the piston 36. It is obvious that the displacement of the piston 36, the drive rod 38 and the support rod 12 also moves the valve component 8. In each of the end positions of the piston 36, the valve component 8 is arranged to close one of the respective valve seats 14, 16.

The type of solenoid control can be selected depending on the respective requirement. Figures 3a and 3b show two possible control types. As shown in Figure 3a-

, the two coils 30 and 32 are energized separately and independently of each other in operation. When the piston 36 is to be displaced to its left-hand position, that is to say to the position shown in Figure 2, a positive DC pulse is applied to the coil 30 for a period of time T. This DC current is large enough to displace the piston 36 to its left-hand stop 4 2 so that the piston 36 is locked in this end position by means of magnetic force. The supply of DC current is then interrupted and the piston 36 is held in the position shown by means of magnetic force. When it is then desired to displace the valve member 8 to the other port, a similar DC pulse of the same power and duration is applied to the coil 32 to overcome the magnetic holding forces, move the piston 36 to the other end stop and lock it in this position by means of magnetic force.

Another embodiment is shown in Figure 3b. In this case, the two coils 30 and 32 are fed simultaneously. However, the coils are wound in opposite directions. This means that the DC pulse fed simultaneously to the two coils causes one of the coils to attract the piston 36 while the other coil repels the piston 36. However, this also means that a displacement of the piston 36 in the opposite direction requires a DC pulse of opposite polarity, as shown in Figure 3b.

Claims (8)

Expectations 1. Distributor valve (10) with a valve component (8) that is displaceable to close a selected connection of two connections, and a magnetically lockable, bistable actuating device (24) which is designed to displace the valve component (8) between the two connections, wherein the actuating device (24) is designed to lock in each of the two end positions with the aid of magnetic force, and wherein the valve component (8) closes one of the two connections in each of the two end positions. 2. Distributor valve (10) according to claim 1, wherein the actuating device (24) is designed to lock in each of its end positions by means of magnetic force. 3. Distributor valve (10) according to claim 1 or claim 2, wherein the actuating device (8) comprises a magnetically lockable solenoid which is designed to displace an elongated drive rod (38) along its length in each of the two opposite directions, wherein a displacement of the drive rod (38) causes a displacement of the valve component (8). 4. Distributor valve (10) according to claim 3, wherein the drive rod (38) is connected to the valve component (8). 5. Distributor valve (10) according to one of the preceding claims, in which the two valve ports are in mutual alignment with one another, and in which the valve component (8) has an elongated support rod (12) which supports the valve component (8) and extends through each of the two valve ports, so that by displacement of the support rod (12) along its length a Displacement of the valve component (8) between the two connections. 6. Distributor valve (10) according to one of the preceding claims, in which the actuating device (24) comprises a solenoid which contains two coils (30, 32) between which an annular permanent magnet (34) is provided, and a piston (36) made of a magnetic material which extends in the axial direction relative to the two coils (30, 32) and the permanent magnet (34), so that the supply of one or both coils with a direct current causes a displacement of the piston (36). 7. Distributor valve (10) according to claim 6, wherein the two coils (30, 32) are connected to be separately supplied with direct current of the same polarity. 8. Distributor valve (10) according to claim 6, wherein the two coils (30, 32) are connected to be fed simultaneously, but the polarity of the supplied direct current can be selected depending on the desired position of the valve component (8).