WO2014094809A1 - Electromechanical drive arrangement and solenoid valve - Google Patents

Abstract

The invention relates to an electromechanical drive arrangement, more particularly for moving a valve member (49; 69; 79; 89), with at least one hollow-wound solenoid coil (2; 22; 42) and a ring yoke (3; 23) comprising a first ring section (4; 24) and a second ring section (5; 25), wherein the solenoid coil (2; 22; 42) surrounds the first ring section (4; 24) in places, and wherein the second ring section (5; 25) is arranged in such a manner that it can swivel towards the first ring section (4; 24). The invention proposes that the first ring section (4; 24) and the second ring section (5; 25) are designed such that a first air gap (9) formed between the first ring section (4; 24) and the second ring section (5; 25) is arranged completely in a volume of space surrounded by the solenoid coil (2; 22; 42), more particularly in a middle third of such volume of space.

Description

 Electromechanical drive device and solenoid valve

The invention relates to an electromechanical drive device, in particular for moving a valve member, comprising at least one hollow wound magnet coil and a ring ^¬ yoke, which comprises a first ring portion and a second ring ^¬ section, wherein the at least one magnetic coil surrounds the first ring portion partially and wherein the second ring portion is pivotally mounted to the first ring portion. Furthermore, the invention relates to a solenoid valve with such an electromechanical drive device.

From the German patent DE 536 909 A, a switching magnet for DC and AC is known in which a fes ^¬ ter magnetic core is provided with a magnetic coil and a movable armature is attached to a cantilever of the magnetic core. In this case, a movable connection between the armature and the arm of the magnetic core is produced by means of a pin hinge.

DE 1 972 126 U discloses a hinged armature magnet, in which a magnetic coil is mounted on a central leg of an E-shaped yoke and a pivotable armature is provided, which can perform a pivoting movement in response to energization of Mag ^¬ net coil. The pivoting ^¬ bare armature is arranged on the side of the yoke, rectangular frame-shaped cover plates by means of a riveted joint pivotally mounted, wherein the contact of armature ensured to the cover plates, that regardless of the Schwenkstel- Development of the armature always the same magnetic resistance zwi ^¬ rule anchor and yoke in the rivet connection is present.

The object of the invention is to provide an electromechanical drive device and a solenoid valve, which have an improved switching behavior.

This object is achieved according to a first aspect of the invention for an electromechanical drive device of the type mentioned above with the features of claim 1. It is provided that the first ring portion and the second ring portion are formed such that the first air gap ^¬ completely in a space surrounded by the magnetic coil volume, in particular in a middle third of this volume space, is arranged. Preferably, the first air gap is arranged in a central region of the volume surrounded by the magnetic coil, in particular in a middle third of this volume, to ensure a low-loss coupling of the magnetic field generated by the magnetic coil in both ring sections. It is advantageous if the air gap is always completely absorbed, regardless of the functional position of the electromechanical drive device, in the volume of space surrounded by the magnet coil, since this is dependent on the size of the air gap

Variations for the coupling of the magnetic field from the magnetic coil can be kept low in the yoke. Ins ^¬ particular scattering losses for the magnetic field to be coupled can be kept low by this arrangement of the air gap.

Advantageous developments of the invention are the subject of the dependent claims.

It is expedient if at least a first portion between the first ring and the second ring portion, and a two ^¬ ter each size variable air gap are formed. In this case, ring sections are preferably arranged such that the two air gaps in a pivoting movement of the second ring section with respect to the first ring section depending ^¬ one, preferably in the same direction, change in size experience. Depending on the design of the two ring sections, a proportional or non-proportional change in size of the two air gaps can be provided for this purpose. Preferably, a pivot axis for the second ring portion is disposed at an end portion of the second ring portion. It can thus be achieved that the second air gap is always smaller than the first air gap.

In a development of the invention, it is provided that a magnetic resistance between the first and the second ring section in the region of the second air gap is at least almost exclusively, in particular exclusively, dependent on the size of the second air gap and / or that the second ring section is in the region of the second Air gap always rests at least with a line contact on the first ring section. In this embodiment of the electromechanical drive device, a particularly simple structure for the Ringj och can be realized, since no measures must be taken to ensure an air gap with a constant size.

Additionally or alternatively, it can be provided that between the first and the second ring portion irrespective of the pivotal position of the second ring portion relative to the first ring portion is a line contact between the first and the second ring portion. Thus, it is always ensured that the magnetic resistance between the two ring sections in the region of the second air gap does not exceed a predetermined level, wherein the maximum magnetic resistance by the line contact between the first and second ring section at maximum size of the Air gap is determined and reduced with decreasing size of the air gap.

Preferably, a second air gap formed between the second annular section and the first annular section is arranged completely in a volume of space surrounded by a second magnetic coil, in particular in a middle third of this volume. As a result, a low-loss coupling of the magnetic field in the Ringj och is at least largely independent of the relative position of the two ring sections guaranteed to each other for the second air gap.

In a further development of the invention, the first ring portion and the second ring portion are hinged together and a hinge connection between the first ring portion and the second ring portion is formed for a motion-independent, constant magnetic resistance between the first ring portion and the second ring portion. As a result, the magnetic resistance in Ringj och at least largely determined by the size of the first air gap, while the magnetic resistance in the region of the hinge connection is at least largely independent of the position of the two ring sections to each other.

For this purpose, for example, be provided to guide the second ring portion between laterally attached to the first ring portion cover plates, said cover plates are in magnetic coupling with the first ring portion, thus thus in the region of the hinge joint independent of the pivotal position of the ring sections magnetic resistance between the yoke and the anchor is guaranteed.

Preferably, the first ring portion is U-shaped, in particular with a first U-leg, which is longer than a second U-leg. This will ox at a ^¬ pose a compact construction of a central Ringj Arrangement of the solenoid and the first air gap ensured. In a further embodiment of the ring yoke, both the first and the second ring section may be U-shaped. It can preferably be provided that the U-legs of the respective ring sections are each the same length.

It is advantageous if the first ring portion are assigned two, in particular parallel to each other and spaced from each other, magnetic coils. As a result, a significant increase in performance can be achieved without a significant increase in the overall volume of the electromechanical drive device, which is advantageous, for example, for carrying out rapid switching operations.

In a further embodiment of the invention, it is provided that the second ring portion between the first ring portion and a, in particular cutting-like design, bearing means and / or a, in particular elastically formed, pressure means is arranged, for an alignment of the second ring portion and / or for a force is formed on the second and first ring portion. In this case, the bearing means serves to ensure a respectively definable position of the second ring portion relative to the first ring portion in all pivot positions, which can occupy the second ring portion. The bearing means may in particular be a blade-like geometry whose cutting edge is aligned parallel to the pivot axis of the second ring section. Additionally or alternatively, a pressure means may be provided, which exerts a pressure force on the second ring portion in the direction of the first ring portion, thereby ensuring a reliable positioning of the second ring portion relative to the first ring portion. Preferably, the pressure means is at least partially made of an elastic material. In an advantageous embodiment of the invention is seen ^¬ before that in a first magnetic circuit formed by the first and the first magnetic circuit, a permanent magnet is arranged, which is assigned ^¬ assigned to the first or second ring portion and / or that the Ringj och a third ring portion is assigned , which forms at least one, in particular size-variable, air gap with the first or the second ring portion and forms a second magnetic circuit with the first and / or the second ring portion. With the aid of the permanent magnet, a magnetic bias in the Ringj och can be caused, which can be used, for example, that the second ring portion opposite the first ring portion without a power supply to the solenoid assumes a predetermined preferred position. If, in addition, a third ring section is provided, an additional magnetic circuit is thereby formed, which is preferably arranged such that the second ring section remains in at least one switching position, preferably in two different switching positions, without the need for an additional energy input into the solenoid coil is required. Typically, the second ring portion associated with a spring device which is operatively connected to the first ring portion and determines a preferred position for the second ring portion relative to the first ring portion, when no energization of the solenoid is provided. Depending on the design of the forces of Federein ^¬ direction and the magnetic field of the permanent magnet hereby a bistable drive device can be provided, in which the second ring portion remains in two different switching positions without energy input to the magnetic coil.

It is preferably provided that the second ring section has at least one curved surface in the region of the first air gap and / or that the ring sections consist of several Metal sheet layers are constructed and / or that at least one of the ring sections has a rectangular, in particular square, cross-section. The at least one ge ^¬ curved surface may, in particular concentrically to the

Be aligned pivot axis of the second ring portion and / or have a radius corresponding to a distance between the pivot axis of the second ring portion and the surface. In this way, an advantageous utilization of the volume of space surrounded by the magnetic coil can be ensured by the second annular section, whereby a magnetic efficiency for the electromechanical drive device can be optimized. By constructing the ring sections from a plurality of, in particular against each other iso ^¬ lated, metal sheet layers eddy currents, as they can occur in a high-frequency switching operation for the electromechanical Antriebseirichtung due to the rapidly changing magnetic field, suppressed or completely avoided.

The object of the invention is achieved according to a second aspect by a solenoid valve according to claim 11. The solenoid valve comprises a valve housing which has at least one inlet connection for a fluid supply and at least one outlet connection for a fluid removal and in which a valve member is movably received, which for a sealing abutment at one of the inlet connection or the outlet connection associated valve seat for influencing ei ^¬ nes fluid flow between the at least one ^{Eingangsan ¬} circuit and the at least one output terminal is formed through the valve housing, with an electromechanical drive device according to any one of the preceding claims. With the integration of the electromechanical drive device according to the invention in the solenoid valve, a fast-switching valve with low volume and high energy efficiency can be created. In an advantageous development of the solenoid valve is provided that the valve member is formed as a sealing means on a side facing away from the first ring portion surface of the second ring ^¬ section or by a movement-coupled with the second ring portion actuator actuated ^¬ bar.

Advantageous embodiments of the invention are illustrated in the drawing. Showing:

Figure 1 is a schematic sectional view of a first

Embodiment of an electromechanical drive ^{¬ device} ,

Figure 2 is a schematic sectional view of a second

 Embodiment of an electromechanical drive device,

3 shows a solenoid valve with an electromechanical drive device and at ^¬ a first Ventilausfüh ^¬ tion,

FIG. 4 shows a second valve embodiment for the solenoid valve according to FIG. 3

Figure 5 shows a third valve embodiment for the solenoid valve according to Figure 3 and

FIG. 6 shows a fourth valve embodiment for the solenoid valve according to FIG. 3.

A shown in Figure 1 electromechanical drive device 1 comprises a hollow wound magnetic coil 2, which is made of a conductive magnetic fields for Mate ^¬ rial, in particular from a ferromagnetic material, associated with a ring yoke. 3 The Ringj och 3 is an example of a first ring portion 4 and a second ring portion 5 on ^¬ built, which are pivotally mounted to each other, wherein a pivot axis 6 is aligned perpendicular to the plane of representation of Figure 1 and is indicated by an axis symbol. By way of example, the magnet coil 2 is assigned to the first ring section 4, in particular fixed to the first ring section 4, so that the second ring section 5 is designed to be movable relative to the magnet coil 2.

In order to ensure a preferred position for the second ring portion 5 ge ^¬ genüber the first ring portion 4 without a current to the solenoid coil 2, a spring device 7 is provided by way of example that engages projections on the ring portions 4 and 5 and this forcing apart. In order to ensure a defined position of the second ring section 5 against ^¬ over the first ring section 4, an example of an elastic hose 8 formed of an elastic material pressure means is provided, which is supported on a housing, not shown, for the electromechanical drive device 1. The hose 8 is received between the housing, not shown, and the second ring section 5 such that the hose 8 can press the second ring section 5 against the first ring section 4. By the force exerted by the hose 8 pressing force is ge ^¬ ensures that the second ring portion 5 always rests at least in a line contact with the first ring section 4.

In the illustrated open position, in which a magnetic circuit formed by the two ring sections 4, 5 is opened, a first air gap 9 and a second air gap 10 are formed between the ring sections 4 and 5. Since the pivot axis 6 extends exemplarily along a contact line between the first and the second ring section 4, 5, a ratio between the size of the first air gap 9 and the size of the second air gap 10 during a pivoting movement from the open position shown in one Closed position in which the two air gaps 9, 10 at least almost completely disappear, at least almost constant. The pivoting movement of the second ring section 5 relative to the first ring section 4 about the pivot axis 6 and against the spring force applied by the spring device 7 is effected by energizing the magnetic coil 2. As a result of this current flow, a magnetic flux is formed which is coupled into the ring yoke 3 and which causes magnetic attraction forces between the ring sections 4, 5 in the regions of the air gaps 9 and 10. Because of these attractive forces, the restoring force of the spring device 7 is overcome, so that the two ring sections 4, 5 can approach each other. By way of example, this approach movement is ended only by a two-dimensional abutment of the second annular section 5 on the first ring section 4. In this situ ^¬ ation the air gaps 9 and 10 are vanishingly.

Due to the configuration of the two ring sections 4, 5 and the arrangement of the magnetic coil 2, the first air gap is located in a space surrounded by the example hollow magnetic coil 2 space volume, whereby an advantageous coupling of the magnetic flux is ensured in the yoke 3. Upon termination of the energy input into the magnetic coil 2, the second ring section 5 is moved back into the rest position according to FIG. 1 due to the restoring force of the spring device 7.

The second embodiment of an electromechanical drive device 21 shown in FIG. 2 comprises components having the same function as the electromechanical drive device 1, so that these components are designated by reference numerals increased by 20 and will not be explained again below. For reasons of clarity, FIG. 2 omits an illustration of the spring device and the pressure device. In contrast to the electromechanical drive device 1 is mounted in the electromechanical drive means 21 in the loading ^¬ reaching the second air gap 30 on the first ring portion 24, a permanent magnet 31st Preferably, the permanent magnet is magnetized such that the outgoing field lines extend along the longer leg 32 of the U-shaped annular portion 24, as indicated by the arrow in Figure 2. Furthermore, a third, exemplarily U-shaped trained annular portion 33 is provided, which is spaced and immovable relative to the ring yoke

23 is arranged and with the annular yoke 23 a third and possibly a fourth air gap 34, 35 is formed. In this case, the fourth air gap 35 is formed in particular variable in size due to the mobility of the second ring portion 25.

By way of example, it can be provided that the forces of attraction produced by the permanent magnet 31 between the first and second annular sections 24, 25 are insufficient to overcome the restoring force of the spring device, not shown, so that the second annular section without restoring the magnetic coil 22, the illustrated rest position occupies. In this case, the outgoing magnetic flux from the permanent magnet 31 flows through the third and fourth air gaps 34, 35 through the third ring portion 33, since the magnetic resistance of this second magnetic circuit is less than the magnetic resistance of the annular yoke 22 certain first magnetic circuit.

When the magnet coil 22 is energized, a magnetic flux is generated in the first magnetic circuit, that is, by the ring yoke 22, which leads to attractive forces between the ring sections

24 and 25 leads, which are greater than the restoring force of the spring device, not shown, so that a pivoting movement of the second ring portion about the pivot axis 26th takes place and the two air gaps 29, 30 at least almost disappear.

If the energization of the magnetic coil 22 is canceled at a time at which the second annular portion 25 is substantially flat against the first ring portion 24, there is a lower magnetic resistance in the first magnetic circuit than in the second magnetic circuit due to the vanishing air gaps 29, 30. Thus caused by the magnetic flux of the permanent magnet attraction forces between the ring portions 24 and 25 are caused, which are greater than the restoring force of the spring device, not shown, and thus ensure the assumed position of the second ring portion 25 relative to the first ring portion 24.

In a subsequent energization of the magnetic coil with a polarity, which leads to a magnetic flux in the yoke 23, the flow direction of the flow direction of the permanent magnet 31 is opposite, with sufficient flux density, the magnetic flux of the permanent magnet 31 is displaced, so that the attraction forces between the annular portions 24th , 25 are reduced and the restoring force of the spring device, not shown, leads to a pivoting movement of the second annular portion 25, in which the air gaps 29, 30 are increased. As a result, the second ring section 25 again reaches the rest position.

In the solenoid valves shown in Figures 3 to 6, the respective drive means is provided in accordance with the drive device 1 according to the figure 1 with a spring means, not shown, which is rich ^¬ tet, without a power supply to the respective magnetic coil a spacing of the respective second Ring section opposite the respective first ring section cause. Accordingly, the illustrations of Figures 3 to 6 are so to understand that the respective magnetic coil or the jewei ^¬ ligen solenoid coils are energized, so that the air gap or the air gaps between the respective first ring portion and the respective second ring portion is minimal or are.

In the case of the magnetic valve 40 shown in FIG. 3, an electromechanical drive device 41 is provided which, with the exception of a second magnet coil 42, corresponds to the electromechanical drive device 1, so that the same reference numerals as for the electromechanical drive device 1 are used here for functionally identical components. Further, the magnetic coils 2, 42 and the first ring portion 4 are surrounded by a drive housing 43, which is provided for electrical insulation and mechanical protection of these components.

The drive housing 43 is adjoined by a valve housing 44, on which an inlet connection 45 and an outlet connection 46 for a supply or removal of a fluid, in particular a gaseous or liquid medium, are formed. In the valve housing 44, a valve chamber 47 is formed between the input port 45 and the output port 46, which is traversed by the fluid. As an example, a valve seat 48 is formed in the valve chamber 47 at the output port 46, which serves as a contact surface for a sealing engagement of serving as a valve member 49 sealing element made of a rubber-elastic material. In this case, the valve member 49 is attached to an outer surface of the second ring portion 5. Thus, the valve member 49 from the second Ringab ^{¬ section} 5 between a rest position in which the valve member 49 sealingly abuts the valve seat 48 due to the action of a spring device, not shown, without energization of the magnetic coils 2, 42, and a functional position in which a free fluid flow between the input port 45 and the output terminal 46 is made possible by appropriate energization of the magnetic coils 2, 42 are moved.

For a reliable positioning and pivotal mounting of the second ring section 5, a bearing means 50 with a substantially triangular cross-section is exemplarily formed on the valve housing 44. The bearing means 50 extends with a uniform cross-section transverse to the plane of representation of Figure 3 and thereby forms a bearing blade 51. The bearing blade 51 is in a linear contact with the second ring section 5 and presses the second ring section 5 against the first ring section 4. Due to the interaction of the bearing blade 51 with the second ring section 5, this is held in a predeterminable position relative to the first ring section 4. In view of the small pivot angle range which is required for the movement of the second ring section 5 between the functional position shown in FIG. 3 and a rest position (not shown), this type of mounting is sufficient.

In the example shown in Figure 4 the valve housing 64, which can be grown in the same manner as the valve housing 44 to the Antriebsgehäu ^¬ se 43, the valve member 69 is formed as Memb ^¬ rane which the valve chamber 67 between the on input terminal 65 and the Output terminal 66 limited.

For this purpose, the membrane is sealed peripherally on the valve housing 64. On a second ring portion 5 supplied ^¬ facing surface area of the valve member 69 is a plunger 60, in particular integrally formed. This plunger 60 allows a central introduction of force from the second ring section 5 to the membrane, which can thus be pressed surface-sealingly onto the valve seat 68 in the functional position.

The valve housing 74 shown in FIG. 5 is an alternative development of the valve housing 64, wherein the valve member 79 is also formed as a membrane and peripherally circumferentially sealed in the valve housing 74 is added. An introduction of movement from the second ring section 5 to the valve member 79 takes place with a rocker 70 mounted pivotably in the valve housing 74.

This rocker 70 is supported by a spring element designed as spring ^¬ 71 and a cam 72 on the second ring section 5. Since the spring means 71 and the cam 72 are arranged on different sides of a pivot axis 73, with appropriate selection of the spring means 71, the rocker 70 and the valve member 79 is energized upon energization of the at least one, not shown, magnetic coil in the illustrated functional position in which a fluid flow from the input port 75 to the output port 76 is possible. As soon as a current supply to the magnetic coils is canceled 2 and 42, made on the basis of the stored spring force of the not Darge ^¬ set spring means comprises a directed in the Figure 5 downwards, introduction of force to the cam 72 so that it and the underlying area of the membrane in Direction of the valve seat 78 formed at the outlet port 76 are pressed and in the rest position of the valve member 79 ei ^¬ ne surface sealing engagement of the diaphragm of the valve member 79 is ensured on the valve seat 78. In this case, the spring ^¬ medium 71 is compressed and thus always ensures an investment of the cam 72 on the second ring section fifth

In one embodiment, not shown, the valve member and the rocker allow a mutual sealing of two gel-like arranged to the pivot axis of the rocker output terminals, so that in the rest position in the same manner as in the embodiment of Figure 5, a seal of the first output terminal results and when energized the two magnetic coils due to the restoring action of the spring means a pivoting movement of the rocker takes place. This seals the second output port. at Cancellation of the energization of the two magnetic coils, the release of the second output terminal and the re-closure of the first output terminal.

In an embodiment of the valve housing 84 shown in FIG. 6, the bearing means 90 is configured by way of example as a solid-body bearing between a bearing tongue 92 formed on the valve housing 84 and the second annular section 5. In this case, the bearing means 90 is made as a flexurally elastic plate, for example of a plastic or metal material and in each case with the valve housing 84 and the second ring portion 5, in particular cohesively connected.

In one embodiment of the bearing means, not shown, this is designed as a solid-body joint between the first and the second ring portion.

Furthermore, in the embodiment according to FIG. 6, the valve member 89 is designed as a diaphragm peripherally sealed and is movably coupled to the second ring section 5 by a slide 91 mounted so as to slide in the valve housing 84.

The bearing means and the valve members in accordance with the above-described embodiments may be combined in any manner with ^¬ each other, the combinations described and illustrated in the drawings are respectively an example.

Claims

claims

Electromechanical drive device, in particular for moving a valve member (49; 69; 79; 89), comprising at least one hollow-wound magnet coil (2; 22; 42) and a ring yoke (3; 23) having a first ring section (4; a second ring portion (5; 25), wherein the magnetic coil (2; 22; 42) surrounds the first ring portion (4; 24) in regions, and wherein the second ring portion (5; 25) is pivotally movable toward the first ring portion (4; ), characterized in that the first ring portion (4; 24) and the second ring portion (5; 25) are formed such that one formed between the first ring portion (4; 24) and the second ring portion (5; 25) the first air gap (9) is arranged completely in a space volume surrounded by the magnetic coil (2; 22; 42), in particular in a middle third of this volume volume.

2. Electromechanical drive device according to claim 1, characterized in that between the first ring portion (4; 24) and the second ring portion (5; 25) are formed Wenig ^¬ least a first and a second each size variable air gap (9, 10).

3. Electromechanical drive device according to claim 2, characterized in that a magnetic resistance between the first and the second ring section (4, 5, 24, 25) in the region of the second air gap (10) at least almost exclusively, in particular exclusively, of the size of the second Air gap (10) is dependent and / or that the second Ring section (5, 25) in the region of the second air gap (10) always at least with a line contact on the first Ringab ^{¬ section} (4, 24) abuts.

4. Electromechanical drive device according to claim 1 or 2, characterized in that between the second ring portion (5; 25) and the first ring portion (4; 24) formed second air gap (10) completely in one of a second magnetic coil (42) surrounded Room volume, especially in a middle third of this volume volume, is arranged.

5. Electromechanical drive device according to claim 1, characterized in that the first ring portion (4; 24) and the second ring portion (5; 25) are hinged together and a hinge connection between the first ring portion (4; 24) and the second ring portion ( 5; 25) for a motion-independent, constant magnetic ^resistance between the first ring section (4; 24) and the second ring section (5; 25).

6. Electromechanical drive device according to claim 1, 2 or 3, characterized in that the first ring section

(4; 24) is U-shaped, in particular with a first U-leg which is longer than a second U-leg.

7. Electromechanical drive device according to one of the preceding claims, characterized in that the first ring section (4; 24) two, in particular parallel to each other and spaced from each other, Magnetspu ^¬ len (2; 22; 42) are assigned.

8. Electromechanical drive device according to one of the preceding claims, characterized in that the second ring section (5; 25) between the first ring section section (4; 24) and a particular manner of cutting out ^¬ formed, bearing means (50; 70; 80; 90) and / or is arranged an, in particular elastically formed, pressing means (8) for alignment of the second ring portion (5 25) and / or for a force introduction to the second and first ring portion (4, 5, 24, 25) is formed.

9. Electromechanical drive device according to one of the preceding claims, characterized in that in a first of the first and second ring portion (24, 25) formed a magnetic permanent magnet (31) is arranged, which associated with the first or second ring portion (24, 25) is and / or that the ring yoke (23) is associated with a third ring portion (33) which forms at least one, in particular size-variable, air gap (34, 35) with the first or the second ring portion (24, 25) and with the first and / or the second ring portion (24, 25) forms a second magnetic circuit.

10. Electromechanical drive device according to one of the preceding claims, characterized in that the second ring section (5; 25) has at least one curved surface in the area of the first air gap (9) and / or that the ring sections (4, 5; 24, 25) are formed of several metal ^¬ sheet layers and / or that at least one of the ring sections (4, 5, 24, 25) has a rectangular, in particular ^¬ special square cross-section.

A solenoid valve comprising a valve housing (44; 64; 74; 84) including at least one fluid delivery inlet port (45; 65; 75; 85) and at least one fluid discharge outlet port (46; 66; 76; 86) and in which is movably received a valve member (49; 69; 79; 89) adapted for sealing engagement with at least one input port (45; 65; 75; 85) or at least one output port (46; 66; 76; 86) ) associated valve seat (48; 68; 78; 88) for influencing fluid flow between the input port (45; 65; 75; 85) and the output port (46; 66; 76; 86) through the valve housing (44; 64; 74; 84 ) is formed through, with an electromechanical drive device (1, 21) according to one of the preceding claims ^¬ .

12. Solenoid valve according to claim 11, characterized in that the valve member (49; 69; 79; 89) is designed as a sealing means on ei ^¬ ner the first ring portion (4; 24) facing away from the surface of the second ring portion (5; 25) or of a motion-coupled to the second ring portion (5; 25) actuator (70; 72; 91) is controllable.