DE9116498U1 - Magnet with stable anchor positions, especially for use in a sanitary fitting - Google Patents

Description

105 EN 27

Description

Magnet with stable anchor positions, especially for use in a sanitary fitting

The invention relates to a magnet with stable armature positions, in particular for use in a sanitary fitting, with a spring-loaded armature and a winding.

A contactless sanitary fitting that is to be operated from a battery or accumulator, possibly supported by solar cells, must only have a minimal energy requirement so that the off-grid power supply can be maintained for as long as possible and without disruption.

DE-PS 38 18 342 describes a contactless sanitary fitting for continuously changing the amount of water flowing through, which uses an electric DC motor and a device that converts the rotary movement of the DC motor into a linear movement of a tappet to control the position of the diaphragm. This well-known sanitary fitting is convenient, but too expensive to manufacture due to its complex design.

The invention is based on the object of providing a solenoid valve

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with stable anchor positions, which is easy and inexpensive to manufacture and has minimal energy requirements so that it can be operated over a longer period of time with a battery or accumulator.

According to the invention, the object is achieved by the features listed in claim 1.

The invention has the advantage over the known that the armature of the solenoid valve can assume two stable end positions and the magnet therefore only needs current pulses to operate. For this reason, the magnet requires very little energy. Accordingly, the magnet can be operated in battery or accumulator mode without problems over a longer period of time. The solenoid valve is constructed using elements that are known per se and can therefore be manufactured inexpensively.

Further advantageous embodiments of the invention emerge from the subclaims and the following description.

The invention is explained using exemplary embodiments based on drawings.

Fig. 1 a longitudinal section through the magnet according to the invention with the valve body indicated as an application,

Fig. 2 is a plan view of the magnet along a line II-II in Fig. 1, but without the winding body of the magnet,

Fig. 3 is a partial longitudinal section through the magnet according to Fig. 1, but with a spring arranged concentrically on the armature,

Fig. 4 shows a cross section through an embodiment of an anchor provided with lateral longitudinal slots,

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Fig. 5 a cross-section through an armature guide tube with longitudinal lateral slots in which the armature of the magnet runs,

Fig. 6 is a plan view of the magnet, similar to the illustration in Fig. 2, but with a ring-shaped permanent magnet and a ring-shaped yoke.

An armature 2 (Fig. 1) of the magnet 1, which is designed as a wet armature magnet, particularly when used on a sanitary fitting, can assume two stable end positions. The magnetic circuit of the magnet 1 is formed by a magnetic series connection consisting of the armature 2, a pole core 3, an iron bracket 4 (Fig. 1, 2), two permanent magnets 5, 6 and a yoke 7 of the magnet 1. Instead of the two permanent magnets 5, 6, one permanent magnet would also be sufficient. In the exemplary embodiment, the armature 2 is designed as a tappet, on the end of which protrudes from the magnet 1 a closing body 14 for closing a valve seat 15 in a valve body 16 of a valve 9, for example as part of a sanitary fitting, is attached in a manner known per se.

The winding 11 of the magnet 1 is supplied with direct current. To achieve one position of the armature 2, the direct current must flow in one direction through the winding 11, to achieve the other position of the armature 2, the direct current must flow in the opposite direction through the winding 11. In each of the two end positions of the armature 2, it remains stable in the respective end position.

functionality

If the armature is extended (not shown in the drawing), it is supported by an axially mounted

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Compression spring 8 (Fig. 1), which is supported on the pole core 3 of the magnet 1, is held in this position, with its closing body 14 striking a stop, for example on the valve seat 15 of the valve body 16. A magnetic circuit, described in detail below, is interrupted due to an air gap between the armature 2 and the pole core 3 of the magnet 1.

If the armature 2 is to be drawn into the winding 11 of the magnet 1, direct current is passed through the winding 11 of the magnet 1. The direction of the direct current must be such that the direction of the magnetic flux in the iron bracket 4 on the one hand and in the yoke 7 on the other hand is the same as the direction of the magnetic flux in the permanent magnets 5, 6. To draw the armature 2 into the magnet 1, it is sufficient to apply direct current to the winding 11 for a short time, i.e. in a pulsed manner. The magnetic flux in the iron bracket 4 on the one hand and in the yoke 7 on the other hand amplifies the magnetic flux of the permanent magnets 5, 6 and thus in the entire magnetic circuit, so that the armature 2 is drawn into the magnet 1. If the armature 2 is drawn into the magnet 1 as shown in Fig. 1 - even after the direct current through the winding 11 of the magnet 1 has ended, the permanent magnets 5, 6 maintain a magnetic flux in the magnetic circuit (permanent magnets, yoke, armature, pole core, iron bracket) that is so large that the armature 2 continues to rest against the pole core 3 when the compression spring 8 is compressed or remains in the attracted state. The compression spring 8 lies in a hole in the armature 2, rests on the armature 2 on the one hand and on the pole core 3 on the other.

If the armature 2 is to be extended again, a direct current is again passed through the winding 11 of the magnet 1, but the direction of this current is the opposite of that which was used to attract the armature 2. The magnetic flux in the iron bracket 4

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on the one hand and in the yoke 7 on the other hand is opposite to that in the permanent magnets 5, 6, so that they allow no or at least only a small magnetic flux in the armature 2. For this too, a short-term, i.e. pulsed, direct current application to the winding 11 is sufficient. The compression spring 8 pushes the armature 2 away from the pole core 3, i.e. out of the magnet 1.

Instead of a single winding 11 (Fig. 1), in one embodiment two windings 17, 18 (Fig. 3) can be wound on top of one another, whereby the outer end of the inner winding 17 is expediently electrically connected to the inner end of the outer winding 18, so that a convenient possibility of reversing the polarity is provided for the purpose of operating the armature 2 of the magnet 1. For this purpose, the electrical connection between the two windings 17, 18, namely a center connection 29 - as well as the two free ends of the windings 17, 18 - is led out of the magnet 1.

Instead of the compression spring 8 (Fig. 1) mounted in the armature 2, according to another embodiment, a compression spring 10 (Fig. 3) can be provided, which is supported on the one hand on an abutment 19 fixed to the housing and on the other hand on the armature 2. In the embodiment, the compression spring 10 is arranged concentrically on the armature 2.

The armature of the magnet 1 is surrounded by the medium that passes through the valve 9, i.e. mainly water. If the armature pulls, the water slows it down in the space into which it wants to slide. This applies in particular to the space between the armature and the pole core 3.

Instead of an anchor 2 with a round cross-section (Fig. 2), according to one embodiment, an anchor 20 (Fig. 4) with slots 21, 22 running along the anchor 20 can be used.

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Water flows through these slots 21, 22 of the armature 20, particularly from the space between the armature 20 and the pole core 3, when the armature 20 is attracted. Due to the pressure equalization via the slots 21, 22, the movement of the armature 20 is only slowed down by the water to a negligible extent.

According to another embodiment, an armature 23 (Fig. 5) has a round cross-section, and an armature guide tube 24 is provided with slots 25, 26 running along the armature guide tube 24. When the armature 23 pulls, water flows out, in particular from the space between the armature 23 and the pole core 3, via the slots 25, 26 of the armature guide tube 24. Due to the pressure equalization via the slots 25, 26, the movement of the armature 23 is only slowed down by the water to a negligible extent.

Instead of rod-shaped permanent magnets 5, 6 (Fig. 1, 2, 3), according to a further embodiment, a ring-shaped permanent magnet can be provided as the permanent magnet 27 (Fig. 6). In this case, a ring-shaped yoke is used.

According to further embodiments, the permanent magnet required for the magnetic circuit can also be assigned to the pole core or the armature, i.e. connected to the pole core or the armature or be part of it.

The magnetic circuit, i.e. its mechanical dimensions and magnetic values, the permanent magnet or the permanent magnets, the winding(s) and the compression spring for the armature must be dimensioned or adjusted in such a way that the transition from one stable end position of the armature to the other takes place within less than 20 ms. If this condition is met, magnet 1 can be operated with pulse control with minimal energy consumption.

Claims (13)

105 EN 27 Claims 1. Magnet with stable armature positions, in particular for use in a sanitary fitting, with a spring-loaded armature and a winding, characterized in that the magnetic circuit of the magnet (1) is formed by magnetic series connection of the armature (2; 20; 23), a pole core (3), an iron bracket (4), permanent magnets (5, 6) and the yoke (7) of the magnet (1). 2. Magnet according to claim 1, characterized in that a compression spring (8) is supported between the armature (2; 20; 23) and the pole core (3). 3. Magnet according to claim 1, characterized in that a compression spring (10) is supported on the one hand on the housing and on the other hand on the armature (2; 20; 23). 4. Magnet according to one of claims 1 to 3, characterized in that the armature (20) is provided with slots (21, 22) running along the armature. 5. Magnet according to one of claims 1 to 3, characterized in that the armature (2; 23) runs in an armature guide tube (24) which is provided with slots (25, 26) running along the armature guide tube (24). 6. Magnet according to claim 3, characterized in that an abutment (19) is provided on the magnet (1) for supporting the compression spring (10), which engages laterally on the armature (2; 20; 23). 7. Magnet according to one of claims 1 to 6, characterized in that instead of one winding (11) two 105 EN 27 Windings (17, 18) lie one above the other. 8. Magnet according to claim 7, characterized in that the outer end of the inner winding (17) is electrically connected to the inner end of the outer winding (18). 9. Magnet according to claim 8, characterized in that the electrical connection, namely the center connection (29) of the two windings (17, 18) is led out of the magnet (1). 10. Magnet according to one of claims 1 to 9, characterized in that the permanent magnet (27) has an annular shape. 11. Magnet according to claim 10, characterized in that the yoke (28) is annular. 12. Magnet according to one of claims 1 to 11, characterized in that the permanent magnet is assigned to the pole core (3). 13. Magnet according to one of claims 1 to 11, characterized in that the permanent magnet is assigned to the armature (2; 20; 23).