WO2010025726A1

WO2010025726A1 - Solenoid valve/coil arrangement and solenoid valve

Info

Publication number: WO2010025726A1
Application number: PCT/DK2009/000196
Authority: WO
Inventors: Michael Birkelund
Original assignee: Danfoss A/S
Priority date: 2008-09-04
Filing date: 2009-09-03
Publication date: 2010-03-11
Also published as: DE102008045755A1

Abstract

A solenoid valve/coil arrangement (2) is provided, comprising a coil (8) which is disposed in a coil housing (7) having an opening (9) into which an element (3) of the solenoid valve (1) can be inserted. The invention is designed to prevent the loss of a seal without making installation more difficult. For this purpose, according to the invention a seal (10) is disposed in the region of the opening (9), said seal having an inside diameter that can be reduced.

Description

Main valve coil arrangement and solenoid valve

The invention relates to a solenoid valve Spulenan order with a coil which is arranged in a coil housing having an opening into which a member of the solenoid valve can be inserted.

A solenoid valve usually has a coil which is arranged in a coil housing to protect the coil from environmental influences, in particular from moisture, and to prevent unwanted electrical interaction between the coil and the environment. The coil interacts with an armature. The armature in turn actuates or moves a valve element. When power is applied to the coil, it shifts the armature. The armature is often arranged in an armature tube which is connected to a valve housing. The anchor tube is inserted through the opening in the coil housing. However, it is then necessary to provide a seal between the armature tube and the coil housing in order to prevent the penetration of moisture into the coil housing. The moisture could have a negative impact on the coil.

For the seal usually a round cord seal or O-ring is used. The O-ring is placed on the anchor tube before the coil is placed with its housing. The disadvantage of this solution is that the O-ring is usually not changed when the bobbin is changed. Accordingly, there is a risk of leakage, so that the replaced coil due to the ingress of moisture has a lower life expectancy and accordingly shorten the replacement intervals. Sometimes the o-ring will stick to the coil case and get lost. The invention has for its object to prevent the loss of a seal without complicating the assembly.

In the case of a solenoid valve coil arrangement of the type mentioned at the outset, this object is achieved by arranging a seal in the region of the opening which has a reducible inner diameter.

If you place the seal on the bobbin case, then you are sure that when you replace the coil with its housing both the old seal from the armature tube (or another part of the solenoid valve) is deducted as well as the new coil or the new coil housing with a Seal is placed on the anchor tube. The seal also ensures that the coil can not fall out of the coil housing during assembly, regardless of the mounting direction. However, this approach without additional measures has the disadvantage that the seal seals already when placed on the anchor tube and thus encloses the air located in the coil housing. If you then pushes the bobbin case on the anchor tube until it has arrived at its final position, ie the stop on the valve body, then the air trapped in the bobbin case is compressed, which on the one hand makes the forces necessary for mounting unnecessarily large and on the other hand, the risk of Leakage comes when the compressed air tries to escape. With the variability of the inner diameter, one can now handle this latter problem in an elegant way. It sets the coil housing on the element of the solenoid valve, when the seal has a larger inner diameter. In this case, there is a small gap between the element of the solenoid valve and the seal, through which air can escape from inside the coil housing, which is displaced by the element of the solenoid valve penetrating into the coil housing. The gap does not have to be big. As a rule, the fraction of a of one millimeter. As the bobbin case approaches the end position, the inner diameter of the seal may be reduced to close the opening of the bobbin case. This closure thus takes place on the last millimeters of the movement.

Preferably, the seal has an inner circumference, which is axially displaceable with respect to an outer circumference. If the inner circumference has been displaced from the outer circumference toward the valve housing before the assembly of the solenoid housing on the solenoid valve, then the inner circumference of the gasket is displaced in the direction of an axial area when the gasket contacts the valve housing Outside circumference is arranged. The previously "obliquely" arranged seal is then folded into a "straight" position. However, since their radial thickness does not change, this automatically leads to a reduction of the diameter. The seal is then brought into contact with the element of the solenoid valve and the opening in the coil housing is closed.

Preferably, the inner radius decreases with a displacement of the inner circumference in the range of 5 to 25% of the displacement movement. Thus, it achieves a relatively large gear ratio, so that even small axial displacements of the inner circumference relative to the outer circumference are sufficient to close the gap between the seal and the element of the solenoid valve.

Preferably, the inner circumference is displaced in the unloaded state 1 to 3 mm axially relative to the outer circumference. The "unloaded state" is the state in which the coil assembly is not yet assembled with the remainder of the solenoid valve. With a displacement in the order of magnitude of 1 to 3 mm, the inner radius of the seal is reduced by about 0.2 mm. This is sufficient to allow sufficient air during installation. to let occur, but close the opening of the bobbin case at the end of assembly.

Preferably, the seal is formed as a ring, the axial Erstre- ckung is smaller than its radial thickness. This facilitates the "pivoting movement" when the inner circumference is displaceable relative to the outer circumference.

Preferably, the seal is formed of a material having a predetermined stiffness. When the bobbin case is mounted to the valve body, the rigidity of the inner periphery remains displaced downward with respect to the outer circumference until the seal comes into abutment with the valve body at the inner circumference. A possible friction of the seal on the anchor tube is not enough for a deformation. Only a further displacement of the bobbin case on the valve housing then leads to the fact that the inner diameter of the seal is reduced. The seal is then deformed under the mounting pressure.

Herein, it is preferable that the material is selected from a group of materials containing liquid silicone rubber, vulcanized silicone rubber and / or EPDM rubber. Liquid silicone rubber (LSR), vulcanized silicone rubber and ethylene-propylene-diene monomer rubber have the desired properties.

Preferably, the seal is fixed by means of a fastening ring on the coil housing. This one is relatively free in the choice of materials for the seal and the coil housing. For mounting purposes, one only has to make sure that the fixing ring can be fastened both to the coil housing and to the seal in order to fix the position of the seal on the coil housing. It is preferred that the fastening ring and the seal have a form fit with each other. The attachment of the seal on the coil housing is thus also mechanical.

It is preferred that the fastening ring has a radially inwardly facing projection which projects into a recess of the seal. The projection may be just like the recess encircling. It is also possible to provide a plurality of projections which are spaced from one another in the circumferential direction and a corresponding number of recesses in the seal or a circumferential recess.

In an alternative, the seal may be glued to the coil housing or secured by ultrasonic welding. Also, the seal is reliably held on the bobbin case.

The invention also relates to a solenoid valve assembly having a coil assembly as described above.

The invention will be described below with reference to a preferred embodiment in conjunction with a drawing. Herein show:

1 is a solenoid valve with separate coil assembly,

2 is an enlarged detail II of FIG. 1,

Fig. 3 shows the coil assembly when mounted on the valve housing in a first position and

Fig. 4, the coil assembly when mounted on the valve housing in a second position. Fig. 1 shows a solenoid valve 1 with a valve housing 2, from which an anchor tube 3 protrudes. In the anchor tube, an anchor is arranged in a manner not shown, but known per se, which is connected to a valve element, also not shown, which releases or closes a fluid path from an input 4 to an output of the valve housing 2, not shown. The anchor tube 3 is sealed over the valve housing 2, for example by a stuffing box, of which only a torque application surface 5 can be seen. The stuffing box is considered below as part of the valve housing 2, in order to simplify the explanation.

The drive of the armature via a coil assembly 6, which has a coil housing 7, in which a coil 8 is arranged. The coil housing 7 is closed except for an opening 9. In the figures, parts of the bobbin case 7 are shown broken away to show details.

In the opening 9, a seal 10 is arranged. The seal 10 is connected to a fastening ring 11. The fastening ring 11 has a radially inwardly pointing projection 12, which engages in a recess 13 in the seal 10. As a result, the seal 10 and the fastening ring 11 are initially connected to each other with a positive connection. You can pour the seal 10 with the mounting ring in a two-component injection, so that they are also connected to each other fluidly.

The coil housing 7 is formed of a plastic. The fastening ring 11 can be welded to the coil housing 7, for example by ultrasonic welding. The gasket 10 is formed of a rubber or rubber material, preferably liquid silicone rubber (LSR) or vulcanized silicone rubber. The use of EPDM rubber (ethylene-propylene-diene monomer rubber) is also possible.

The material of the seal 10 has a certain inherent rigidity. The seal 10 is made with the shape shown in FIG. 2, in which the inner circumference 14 is displaced or displaced away from the coil 8 in the axial direction with respect to the outer circumference 15. If one uses as the reference size for the size of the displacement or offset, the side of the seal 10, which faces away from the coil 8, then this side on the inner circumference 14 against a corresponding position on the outer circumference 15 by about 1 to 3 mm the coil 8 shifted away.

The seal 10 is formed as a ring whose axial extent or thickness is smaller than its radial extent or thickness. The ring does not necessarily have a rectangular shape in cross-section.

If now the coil housing 7 to be mounted on the anchor tube 3, then the coil housing 7 is pushed with the seal 10 on the anchor tube 3. This is shown in Fig. 3, where like parts are provided with the same reference numerals as in Figs. 1 and 2.

It can be seen that between the seal 10 and the anchor tube 3, a gap 16 is formed, can escape through the air, which is displaced by the insertion of the anchor tube 3 in the coil housing 7. The gap 16 is shown exaggerated here. It is in reality only a fraction of a millimeter, for example 0.05 to 0.2 mm.

The seal 10 maintains its shape shown in Fig. 2, as long as no external forces act on it. A possible friction between the seal tion 10 and the anchor tube 3 does not lead to a significant deformation of the seal 10. When the seal 10, as shown in Fig. 4, comes to rest against the valve housing 2, then it comes first in the region of its inner periphery 14 to the plant to the Valve housing 2. In the region of the outer circumference 15, it still has a distance from the valve housing 2. As a result, the inner circumference 14 can be displaced relative to the outer circumference 15, namely in the direction of the coil 8. The seal is then, so to speak, slightly tilted, so that the inner diameter of the seal 10 is reduced. When the bobbin case 7 is pushed closer to the valve housing 2 by about 1 to 3 mm, the inner radius of the seal 10 decreases by about 0.2 mm. This reduction of the inner diameter is sufficient to close the gap 16. However, this closing takes place only when the coil housing 7 has arrived in the desired position. If then still air is enclosed in the interior of the bobbin case 7, this is not critical, because this air is not further compressed by a movement of the bobbin case 7.

Instead of the fastening ring 11, it is also possible to use another fastening of the gasket 10 to the coil housing 7, for example by gluing the gasket 10 directly to the coil housing 7.

Claims

claims

1. Solenoid valve coil assembly comprising a coil (8) which is arranged in a coil housing (7) having an opening (9) into which an element (3) of the solenoid valve can be inserted, characterized in that in the region of the opening (9) a seal (10) is arranged, which has a reducible inner diameter.

2. coil assembly according to claim 1, characterized in that the seal (10) has an inner circumference (14) which is axially displaceable relative to an outer periphery (15).

3. coil assembly according to claim 2, characterized in that the inner radius decreases in a displacement of the inner periphery (14) in the range of 5 to 25% of the displacement movement.

4. coil assembly according to claim 3, characterized in that the inner circumference (14) in the unloaded state 1 to 3 mm axially against the outer periphery (15) is displaced.

5. Coil arrangement according to one of claims 1 to 4, characterized in that the seal (10) is formed as a ring, whose axial extent is smaller than its radial thickness.

6. coil assembly according to one of claims 1 to 5, characterized in that the seal (10) is formed of a material having a predetermined inherent rigidity.

A coil assembly according to claim 6, characterized in that the material is selected from a group of materials which Liquid silicone rubber, vulcanized silicone rubber and / or EPDM rubber contains.

8. coil arrangement according to one of claims 1 to 7, character- ized in that the seal (10) by means of a fastening ring (11) on the coil housing (7) is fixed.

9. coil assembly according to claim 8, characterized in that the fastening ring (11) and the seal (10) have a form fit with each other.

10. coil assembly according to claim 9, characterized in that the fastening ring (11) has a radially inwardly facing projection (12) which projects into a recess of the seal.

11. Coil arrangement according to one of claims 1 to 7, characterized in that the seal (10) is glued to the coil housing (7) or secured by ultrasonic welding.

12. Solenoid valve with a coil arrangement (6) according to one of claims 1 to 11.