DE3815248A1 - Solenoid for a solenoid valve - Google Patents

Abstract

The invention relates to a solenoid for a solenoid valve for gaseous or liquid media, having a coil core (11) fixed to the frame and a movable armature (13) which is acted upon by a return spring (14), the opposing pole faces (24) of which can be brought into contact, counter to the return force of the return spring (14), when the solenoid coil (10) is excited. Provided in the coil core (11) is a return passage (12) that emerges at the pole face (24) of the coil core (11). When the solenoid coil (10) is not excited, this return passage is connected to the clearance space between the pole faces in a manner which allows flow, and, when the solenoid coil (10) is excited, can be closed by a valve arrangement (23, 26). This valve arrangement consists of a valve seat (26) and a valve element (23), one of these parts being of flexible design and the spacing between them being smaller in this state than the spacing between the pole faces. According to the invention, the valve seat (26) and the valve element (23) are designed as rigid components. The valve element (23) is supported against a valve spring (19) and its freedom of motion is limited in the direction of pressure of the valve spring (19) by a stop (20) which determines the distance between its valve-sealing surface and the valve seat (26) in the unexcited state of the solenoid coil (10). <IMAGE>

Description

The invention relates to a solenoid for a solenoid valve for gaseous or liquid media with a fixed frame Coil core and a movable one, with a return spring acted on anchor, the opposite Pole surfaces when the solenoid coil is energized against the Return force of the return spring in mutual contact can be brought, one provided in the coil core and in the Pole surface of the coil core opening backflow channel, which at non-energized solenoid coil with the clearance between the pole faces are in flow communication, one that Mouth of the return flow channel when the solenoid coil is energized occluding valve arrangement with in one of the pole faces arranged valve seat and one in the opposite Valve body arranged with a pole face when excited Solenoid coil sealingly engages with the valve seat bringable valve sealing surface, either the valve seat or the valve body is flexible and the Distance between valve seat and valve sealing surface at not excited solenoid coil is smaller than the distance between the pole faces in this state.

If the solenoid is energized by Switch off the voltage in the de-energized state offset, it is the job of the return spring to drop the anchor in its basic position at a distance from the coil core attributed.

As a result of a certain residual in the coil core, the anchor sticks immediately after switching off the voltage on Coil core, and it may happen that the Return spring only after a certain delay time succeeds in separating the armature from the coil core. The increase the spring force of the return spring are among others constructive reasons that the magnetic force even in the greatest distance of the Anchor when switching on the magnet still be able  must, the spring force for pulling out the anchor too overcome. In addition, the pull-out work should be as possible be kept low.

Modern electronic control circuits, such as those used today Control of pneumatic and hydraulic circuits are used to place the solenoid valves in the general one of the most important links between the electrical and the hydraulic / pneumatic part of a Represent control, increased requirements.

So has through electronic control circuits on the one hand, the possible switching speed is greatly increased, so that electromagnets for valves are also desirable, where the armature when the coil is transferred to the de-energized state responded as soon as possible and not waiting for the remanence to subside until the armature return spring is able to to separate the armature from the coil core.

Another special feature of electronic control circuits is that they also use semiconductors as switches use. While in previous relay controls one Galvanic isolation between the spreader circuit and the circuit was given by the relay and on a solenoid valve coil in the de-energized state there is actually no tension more system, there is a galvanic isolation of the Circuits in purely electronic control circuits are not more instead, so that there is a possibility that at a Solenoid valve coil one more even when de-energized certain residual voltage is present, which constantly a certain magnetic flux generated in the coil core. This can in particular be the case if in certain Logic circuits also have the logic state "0" certain positive voltage level is assigned.  

So the solenoids of solenoid valves are not only the requirement that they not only when de-energizing overcome a certain remanence faster, but also against permanent idling magnetism let it separate easily.

An increased effort is only for that immediate separation of the pole faces from each other required. First assign one, if still so close to each other, the power of the Return spring to continue the Anchor return process. The use of return springs with progressive spring characteristics could help here. There the travel is generally very small and especially the initial separation path, which is anchor bonding should be overcome, is extremely short, one can progressive spring characteristic, if at all, only with the force-displacement ratio is relatively expensive of a solenoid valve solenoid.

Solenoid valves are known and are widely used used in the coil core of the magnet return flow or pressure relief duct leading to the outside located when the solenoid valve is open, i.e. H. at tightened anchor by a provided in the pole faces Valve arrangement is closed. This valve arrangement generally has an elastically compliant part, which when the pole faces approach each other the magnetic attraction yields elastically, on the one hand to allow the pole faces to lie against one another and on the other hand, the valve arrangement under a certain To maintain closing pressure. In support of Flexibility of the valve arrangement are already here Anchors arranged and arranged in springs been used.  

This elastic version of known valve arrangements however, only has elastic links with proportion low spring force as its sole purpose is to Sealing valve arrangement when the armature is energized close.

The invention is based on the object of a solenoid of the type mentioned for a solenoid valve, which has a valve arrangement in the pole faces, such train that the anchor even in the presence of Can separate residual magnetism.

According to the invention the object is achieved in that the Valve seat and the valve body as rigid components are executed, and that the valve body against a Valve spring supported and its movement in Direction of pressure of the valve spring limited by a stop which is the distance of its valve sealing surface from Valve seat when solenoid coil is not energized certainly.

In a preferred embodiment, the valve body arranged in the region of the pole face of the armature, during the Valve seat is a surface formed in the coil core.

The valve body has a greater hardness than that Valve seat.

The restoring force of the valve spring is in the excited state the solenoid coil at least half as large, preferably 0.6 ... 1.5 or 0.8 ... 1.2 times as large as that Return force of the return spring of the armature.

The valve body has a curved, conical or Flat surface as a valve sealing surface.  

A ball can preferably be used as the valve body because these are in a technically simple way and Can be inserted and fastened in its holder, especially in constructive designs in such a way small orders of magnitude.

The device according to the invention ensures a safe operation and quickly switching off the solenoid valve, even if it is still there is a residual voltage on the coil or a remanent one There is magnetism in the coil core.

In the excited state of the solenoid both the force act the return spring as well as the force of the valve spring together against the magnetic attraction. At De-energizing the solenoid will therefore be the sum of both Spring forces act to pull the armature away from the spool core separate. The force of the valve spring, however, only works in this way long until the valve body against its stop in the anchor comes to the concern. This can be done after a travel 0.1 mm, a way, but its brevity sufficient to separate the armature from the coil core. Then only the return spring takes over the rest Movement of the anchor to its rest position.

The arrangement according to the invention ensures that an elevated one only for the first disconnection of the anchor Spring force is available during the short distance The rest of the armature movement is taken over by the return spring that is only sufficiently strong for this task needs to be interpreted.

The invention is to be described in more detail using an exemplary embodiment are explained. The attached drawings show in

Fig. 1 shows a longitudinal section through a solenoid valve and

Fig. 2 shows the enlarged sectional view of the valve arrangement on the pole faces.

Fig. 1 shows in section a solenoid valve which comprises a valve body 1. This has a vertical flow channel 2 . Another flow channel 3 also runs in the vertical direction adjacent to this flow channel 2 , but in the present example case it merges into the horizontal. At the upper end of the vertical part of the flow channel 3 there is a channel opening 4 . A solenoid is arranged on the valve body and has a housing 5 , which is arranged at its lower end by means of a sealing ring 6 on the valve body 1 in an airtight and liquid-tight manner and is closed with a housing cover 7 . An electrical connection 9 for applying a voltage, for example a standard control voltage of 24 volts, opens into the housing 5 containing the yoke 8 . Of course, the present invention is also suitable for solenoid valves which are designed for a different excitation voltage.

A solenoid coil 10 corresponding to the electrical connection conditions is also arranged in the housing 5 . This encloses a coil core 11 which is fixedly connected to the solenoid coil 10 , so that it sits immovably in the upper part of the housing 5 . The coil core 11 contains a return flow channel 12 .

Furthermore, the solenoid coil 10 encloses a movable armature 13 , which is movable in the vertical direction away from the coil core 11 or towards the coil core 11 . The movable armature 13 is pressed by a return spring 14 in the rest position of the solenoid valve away from the coil core 11 against the valve seat 4 of the flow channel 3 in the base body 1 . For this purpose, the return spring 14 is supported in the interior of the housing 5 and a collar 15 arranged at the lower end of the armature 13 .

In the interior of the movable armature 13 , a bore provided with several shoulders is provided in the vertical direction, which contains a sealing element 16 at its lower broad end, which serves to close the flow channel 3 . This sealing element 16 can be displaced upwards in the vertical direction, but is pressed downward against a stop in the vertical direction by means of a valve spring 17 which is under prestress. The valve spring 17 is supported on a bore shoulder, or, as in the present example, on a snap ring 18 . A valve spring 19 is in turn arranged above the snap ring 18 , which is supported on the one hand on the snap ring 18 and on the other hand on a stop pin 20 . This stop pin 20 is also arranged in the vertical bore of the armature so as to be displaceable in the vertical direction. A valve body 23 is introduced into the upper surface of the stop bolt 20 . This valve body 23 can have a curved, conical or flat surface. In the present example, the valve body 23 has a spherical shape.

This spherical shape is preferred because it is suitable for such Orders of magnitude in a simple production engineering way and Can be inserted and fastened in the valve seat.

A pole face 24 is arranged on the end face of the coil core 11 . Together with the mouth of the return flow channel 12, this forms a valve seat surface 25 in the form of a chamfer which is adapted to the shape of the valve body. This valve seat 26 lies opposite the valve body 23 , so that the pole face 24 of the coil core 11 lies opposite the pole face 22 of the armature 13 . Further details can be clearly seen in the enlarged detail from FIG. 1 in FIG. 2.

When the solenoid valve is at rest, there is a gap 27 between the pole faces 22 and 24 of the coil core 11 and the armature 13 , which has the width b . In the present example, the width b is approximately 0.5 mm. The opposing sealing surfaces 25 of the valve body 23 and the valve seat 26 form a distance a which is approximately 2/3 to 4/5 of the width of the gap 27 . The width b of approximately 0.5 mm corresponds to the path of the armature 13 to be covered . The armature 13 travels this way when an electrical voltage is applied to the solenoid coil 10 . The force of the magnetic field that builds up overcomes the spring force of the return spring 14 and pulls the armature 13 against the coil core 11 , so that the two pole faces 22 and 24 meet and rest against one another without a gap. Before the pole faces 22 and 24 meet, however, the two valve seat faces 25 of the valve body 23 and the valve seat 26 touch at the mouth of the return flow channel 12 . Now only the difference between a and b, namely about 0.1 mm, is covered until the two pole faces 22 and 24 meet. As a result, the stop pin containing the valve body 23 is displaced vertically downward by the differential path of approximately 0.1 mm against the resistance of the force of the valve spring 19 .

In the example case, the valve spring 19 has a restoring force that is equal to or greater than the restoring force of the restoring spring 14 . Since the valve spring 19 was already under prestress and was further tensioned by pushing back the valve body 23 and the stop bolt 20, it still presses the valve body 23 against the sealing surfaces 25 . Due to the great force of the inner compression spring 19 on the valve body 23 against the opening of the return flow channel 25 , the two pole faces of the coil core 11 and the armature 13 are abruptly separated from each other and thus the remanence of the solenoid coil 10 is overcome, for which purpose the return spring 14 is not alone in the Location would have been. The sealing element 16 is pressed again onto the valve seat 4 of the flow channel 3 while the return flow channel 12 is opened. The abrupt separation of the two pole faces of the coil core 11 and the armature 13 ensures a quick and secure closure of the flow channel 3 and the opening of the return flow channel 12 .

By the present solenoid design according to the invention will switch off the Solenoid valve reached because the remanence of the magnet or the residual voltage of the solenoid when the Solenoid valve is overcome.

Claims (8)

1.Solenoid for a solenoid valve for gaseous or liquid media with a frame-fixed coil core and a movable armature loaded with a return spring, the opposite pole faces of which can be brought into mutual contact against the restoring force of the return spring when the solenoid coil is excited, one provided in the coil core and in the pole face of the coil core opening return flow channel, which is in flow connection with the non-energized solenoid coil with the spacing between the pole faces, a valve arrangement closing the mouth of the return flow channel with energized solenoid coil with a valve seat arranged in one of the pole faces and a valve body arranged in the opposite pole face with a excited solenoid coil with the valve seat sealingly engageable valve sealing surface, wherein either the valve seat or the valve body is flexible and the distance between the valve seat and the valve sealing surface when the solenoid coil is not energized, it is smaller than the distance between the pole faces in this state, characterized in that the valve seat ( 26 ) and valve body ( 23 ) are designed as rigid components, and in that the valve body ( 23 ) is supported against a valve spring ( 19 ) and its movement in the pressure direction of the valve spring ( 19 ) is limited by a stop ( 20 ) which determines the distance of its valve sealing surface from the valve seat ( 26 ) when the solenoid coil ( 10 ) is not energized. 2. Solenoid according to claim 1, characterized in that the valve body ( 23 ) is arranged in the region of the pole face of the armature ( 13 ). 3. Solenoid according to claim 2, characterized in that the valve seat ( 26 ) is a surface formed in the coil core ( 11 ). 4. Solenoid according to at least one of claims 1-3, characterized in that the valve body ( 23 ) is of greater hardness than the valve seat ( 26 ). 5. Solenoid according to one or more of claims 1-4, characterized in that the valve body ( 23 ) has a curved, conical or flat surface as a valve sealing surface. 6. Solenoid according to at least one of claims 1-5, characterized in that the restoring force of the valve spring ( 19 ) in the excited state of the solenoid coil ( 10 ) is at least half as large as the restoring force of the restoring spring ( 14 ) of the armature ( 13 ). 7. Solenoid according to claim 6, characterized in that the restoring force of the valve spring ( 19 ) in the excited state of the solenoid coil ( 10 ) about 0.6 ... 1.5 times the restoring force of the restoring spring ( 14 ) of the armature ( 13th ) is. 8. Solenoid according to claims 6 and 7, characterized in that the restoring force of the valve spring ( 19 ) in the excited state of the solenoid coil ( 10 ) about 0.8 ... 1.2 times the restoring force of the restoring spring ( 14 ) of Anchor ( 13 ) is.