DE10130629C1 - Valve assembly for a magnetic valve comprises an exciter arrangement which can be arranged on two different axial positions of the housing, depending on the desired base function - Google Patents

Abstract

The valve assembly comprises an exciter arrangement (3) which can be arranged on two different axial positions of the housing (2), depending on the desired base function. The housing is filled with a material outside of the armature (7). The relative magnetic permeability of the material is less than 50. The exciter arrangement has a coil (4) which encloses the housing. It also has a C-shaped cover (5,6) made from a magnetic conductive material which covers the coil.

Description

The invention relates to a valve assembly for a solenoid valve with a housing, a valve element with an anchor, which is arranged in the housing, egg a valve seat and an electrical excitation arrangement, designed as a radial field generating device is.

Such a valve assembly is from US 4,452,424 known.

A measure can usually be made from the parts mentioned Assemble the solenoid valve that is closed when the valve element rests on the valve seat. The pathogen Order is designed so that it egg at the flow Nes current generates a magnetic field that on the armature acts. The anchor is under the action of the magnetic field which moves and thereby moves the valve element. at Valves that are closed in normal or idle state are, the movement of the valve element leads to a Opening the valve. For valves in which or idle state the valve element from the valve seat ent is distant, the movement of the anchor leads to one  Closing the valve element. The latter venti le are also referred to as "normally open", while the first named as "normally closed" be net.

Known solenoid valves work so that the Erre geranordnung acts on a magnetic core that is coaxial is arranged to anchor in the housing. When electricity flows then the magnetic core pulls the armature and causes there by the movement of the anchor. Has this training Proven in itself, it is disadvantageous in this respect as the force with which the magnetic core Anchor attracts, with decreasing distance between the anchor ker and the magnetic core changes. Such a valve is basically only suitable as a switching valve, not however as a proportional valve.

In the manufacture of valves, it is usually required a certain number of normally ge closed and a certain number of normally open solenoid valves. If you are a pro production line from the production of the one kind to the Manufacturing of the other type would like to retool requires this is sometimes a considerable effort. To have to new parts are fed to the respective Basic function (normally open or normally closed) of the solenoid valve are adjusted. The changed parts usually need to be put together in other ways be what a corresponding change in the handha exercise machines conditional. For this reason, one considers nor usually two production lines ready, in each because solenoid valves with other basic functions be put.

The invention is based, the produi to simplify solenoid valves.

This task is accomplished through a valve assembly solved for a solenoid valve of the type mentioned and that in that the pathogen arrangement in dependence from a desired basic function to two under different axial positions on the housing can be fixed is.

With such a valve assembly, the two basic functions "normally closed" and "normal open "can be realized with the same valve parts. You only need the parts mentioned above, Valve element with armature, valve seat and exciter arrangement voltage. By choosing the location where the pathogen order is appropriate, the basic function of Ven tils determined. If the pathogen arrangement is close the valve seat is arranged, it is a normally open valve because of the excitation arrangement the armature when current flows towards the valve seat emotional. If it is a normally closed one Valve is the exciter arrangement on the other En de of the armature arranged to the valve element from Ven pull the tilsitz away. Is of particular importance here the way the magnetic field runs in the valve, namely that the magnetic field is designed as a radial field is. Such a magnetic field naturally also has axia le components. The main feature is that in Contrary to an axial magnetic field an air gap, in the practically exclusively axial components of the Ma  gnetfelds are present when the anchor moves not downsized. Rather, the over changes cover between the anchor and the pathogen arrangement, so that there is also a state in which the ma magnetic resistance for the magnetic field if possible ring is. However, the magnetic field occurs radially from the pathogen arrangement and is not replaced by one axially provided in addition to the armature magnetic core directed. With the exciter arrangement described it is possible to use a solenoid valve as a proportional valve design and operate.

Preferably, the housing is outside of the armature a material filled, the relative magnetic Permeability in operation is less than 50. The rela Tive magnetic permeability of air is here equal to 1. Many materials such as plastics have one similar small relative magnetic permeability. she have little or no influence on the magnetic field. This applies as long as the relative magnetic permeability is less than 50. The magnetic field therefore becomes practical exclusively through the interaction of pathogens order that the magnetic field is essentially radial straightens, and anchor, influences.

The excitation arrangement preferably has a coil which surrounds the housing, and a C-shaped in cross section Cover made of magnetically conductive material on the covers the outside of the coil. The cover defines the magnetic circuit outside the case. At the inside the magnetic circuit closes through the armature. As mentioned above, the anchor will then adjust itself len that the smallest possible magnetic resistance  exist. In other words the anchor will try the greatest possible coverage with the pathogen arrangement to achieve.

The cover preferably has a first leg on which is placed in the middle of the axial length of the armature is net, and a second leg that is at rest position is adjacent to one end of the anchor. The at the leg of the cover carry the magnetic field radially into the housing.

The second leg is preferably at least partially arranged axially outside the anchor. If the Spu le is energized, it is energetically before partial if there is coverage between the two th leg and the anchor enlarged. Therefore arises a force that moves the anchor in the direction that the coverage increases.

Preferably there is a return spring at the end arranged of the anchor, the second leg of the Er excitation arrangement is adjacent. In many cases Position of the valve element by a return spring be determined. In a few cases, the rest position of the valve element also by external Ensure circumstances, such as printing a liquid to be controlled. This is also evident here Advantage of valve assembly. It is enough to additionally the spring from one end of the valve to the other end to shift the reason change the function of the valve.  

The valve element is preferably at least partially depressurized. In other words, the pressure of the fluids to be controlled for loading the valve ment no role, d. H. the pathogen arrangement must Actuation or movement of the valve element only for this help overcome the force of the return spring.

The anchor preferably has at least one through passage opening and the housing has in the area ner two axial ends on connection openings. A such valve assembly is therefore as a through gear valve provided.

Is preferably between the valve element and the Valve seat arranged a servo stage. The servo stage is an auxiliary device with the help of which the valve can be opened or closed. The anchor works still together with a valve element. This Valve element does not act directly on the Ven tilsitz, but on a servo element, which in turn is on the valve seat acts. This will give you the power you need needed to open or close the valve, small ge hold.

Installation parts are preferably shaped in the housing held conclusively. This simplifies production. You can fi the corresponding parts in the housing should be fixed, simply by pressing in the casing Secure the sewand from the outside.

The invention is based on preferred in the following Embodiments in connection with the drawing described in more detail. Show here:  

Fig. 1 shows a first embodiment of a Magnetven TILs, which is designed as a valve passage,

Fig. 2 is a direct acting solenoid valve,

Fig. 3 is a direct acting solenoid valve with partial pressure relief

Fig. 4 is a servo valve.

In all figures, part a is normally open solenoid valve (NO valve) and in part b a norma closed valve (NC valve) is shown.

A solenoid valve 1 has a housing 2 , which is simply designed as a tube. The housing 2 is surrounded by an excitation arrangement 3 , which has a coil 4 and a cross-sectionally C-shaped cover with a becherar term part 5 and a bottom part 6 . The cover kung 5 , 6 is placed on the housing 2 with virtually no radial play. It can be provided with not shown Darge, but generally known means, such as gluing, welding or the like, attached to the housing 2 in the axial direction.

Inside the housing 2 , an armature 7 is arranged movably in the axial direction. The armature 7 is connected to a valve element 8 which is designed as a tube with a conical tip 9 . Connections between the armature 7 and the valve element 8 are not shown for reasons of clarity, but are present, so that the valve element 8 is always moved together with the armature 7 . A through opening 10 is arranged between the armature 7 and the valve element 8 ,

A base plate 11 with a valve seat 12 is also inserted into the housing. The base plate 11 is positively held in the housing 2 by an indentation 13 in the housing 2 , which engages in a groove 14 on the base plate 11 . On the opposite side, a head plate 15 is arranged in the housing and just if held by an indentation 16 which engages a groove 17 of the head plate 15 .

A cylindrical pin 18 , which projects into the interior of the valve element 8, is supported on the head plate 15 . A seal 19 is present between the cylindrical pin 18 and the valve element 8 .

Sliding and sealing elements 20 are provided between the armature 7 and the housing 2 .

These elements are present in identical form in both the normally open valve according to Fig. 1a and the normally closed valve according to Fig. 1b and assembled in the same order, ie the same axial order.

The difference between the normally open valve 1 according to FIG. 1a and the normally closed valve 1 'according to FIG. 1b results from two elements.

On the one hand, in the normally open solenoid valve 1 according to FIG. 1a, a return spring 21 is provided in such a way that it pushes the valve element 8 away from the valve seat 12 . The return spring 21 acts on the valve element 8 via the armature 7 . In the normally closed valve 1 'according to FIG. 1b, on the other hand, the return spring 21 , which can be designed in the same way as in the normally open valve 1 , is arranged between the head plate 15 and the armature 7 .

On the other hand, the exciter arrangement 3 is arranged adjacent to the end of the armature 7 when normally open valve 1, which is closer to the valve seat 12, while in the normally-closed valve 1 'shown in Fig. 1b, the exciter arrangement 3 on at a different axial positi on the housing 2 is arranged, namely where the other end of the anchor is located.

As can be seen from the drawing, the cover 5 , 6 has a C-shaped cross section. If the valve 1 has the basic function "normally open", then one leg 5 of the C is oriented so that it lies in the middle of the axial length of the armature 7 and accordingly feeds the magnetic field radially into the armature 7, so to speak, while the other leg 6 is arranged outside of the core 7 . The leg 6 "feeds" the magnetic field also radially into the interior of the housing 2 . There it is then deflected and meets axially on the end face of the armature 7 in wesent union. This description of the magnetic field serves only as a clear explanation. In the gap between the end face of the armature 7 and the leg 6 there will in fact be a transition which is more difficult to describe. If a current flows through the coil 4 , then the magnetic field moves the armature 7 so that the overdec tion between the armature 7 and the leg 6 is as large as possible. A complete coverage will not be possible because the valve element 8 previously comes into contact with the valve seat 12 .

If the solenoid valve 1 'to realize the other basic function, namely "normally closed", then the exciter arrangement 3 is only moved so that the leg 6 ends in the middle of the armature 7 and the leg 5 ends so that it axially outside the An kers 7 is located on the other side of the anchor 7 , compared with Fig. 1a.

Since, moreover, the interior of the housing 2 is free of mate rialien, which could interfere with the magnetic field of the excitation arrangement 3 to a significant extent, the formation of the magnetic field is determined exclusively by the interaction between the armature 7 and the excitation arrangement 3 be. Small possibilities of influencing, such as could occur through a relative permeability of materials in the order of up to 50, are of course permitted.

In order to keep the explanation short, it is simplified that the exciter arrangement 3 generates a radial field. Of course, the magnetic field generated by the exciter arrangement 3 is not exclusively directed radially, but in particular has axial components on the free end faces of the armature 7 (bottom in FIG. 1a and top in FIG. 1b). Significant axial components also arise inside the armature 7 .

However, it is intended to express that there are no only axially extending field lines which bridging an air gap between two elements, namely the armature 7 and a magnetic core usually present in the axial extension of the armature, the distance between these two Sharing is changed when the anchor moves. In other words, the radial magnetic resistance changes when the armature moves. With ordinary solenoid valves, however, the axial magnetic resistance is changed.

The housing has a first opening 22 in the region of its base plate and a second opening 23 in the region of its head plate 15 . The valve 1 , 1 'is thus designed as a two-way valve.

A movement limit for the valve element 8 and thus for the armature 7 is formed in one direction by the fact that the valve element 8 comes with its upper end to rest on the head plate 15 and in the other direction in that the valve element 8 to rest against Valve seat 12 comes.

The valve element 8 is designed as a tube whose inner diameter is equal to the diameter of the opening 12 surrounded by the valve. The valve element 8 has an opening 24 which is net angeord in the tip 9 . Thus, the valve element 8 is completely relieved of pressure, ie the forces acting on the valve element 8 are determined practically exclusively by the return spring 21 and the exciter arrangement 3 , but not by the hydraulic pressures in the openings 22 , 23 . The solenoid valve allows fluid to flow in both directions.

Fig. 2 shows a direct-acting solenoid valve 101, 101 'and that in Fig. 2a as a normally open Ven til 101 and in Fig. 2b as a normally closed valve 101'. Parts, which correspond to those of FIG. 1, see ver with the same reference numerals as in Fig. 1.

It can also be seen here that one can simply move the exciter arrangement 3 into a different axial position on the housing 2 and by changing the position of the return spring 21 to achieve the transition from a normally open valve 101 to a normally closed valve 101 ' , The components used for the two valves are absolutely identical.

The armature 7 may also have a jump 25 at its upper end, which serves as a movement limitation and fixation for the return spring 21 in the solenoid valve 101 '.

Fig. 3 shows an embodiment modified from FIG. 2 of a solenoid valve 201 in the normally open state or 201 'in the normally closed state. The same parts as in FIGS. 1 and 2 are provided with the same reference numerals. The valve 201 , 201 'is partially depressurized. For this purpose, the Ven tilelement 8 is penetrated by a channel 26 which opens into a pressure chamber 27 which is movably limited by the cylinder pin 18 . The pressure chamber 27 has a diameter which corresponds to the diameter of the opening 22 delimited by the valve seat 12 .

Here, too, the normally open valve 201 and the normally closed valve 201 'are constructed from the same components, the difference in the basic function only resulting from the fact that the exciter arrangement 3 is at a different axial position and the return spring 21 is at the other En de the anchor is arranged.

FIG. 4 shows a normally open solenoid valve 301 and a normally closed solenoid valve 301 ', the valves being designed as servo valves. The same and corresponding parts as in Figs. 1 to 3 are hen with the same reference numerals verse.

Between the valve element 8 and the valve seat 12 , a servo plate 28 is arranged, which has a Durchgangssboh tion 29 , which connects the first opening 22 with an auxiliary pressure chamber 30 , and a throttle bore 31 , which connects the auxiliary pressure chamber 30 with the second opening 23 .

The valve element 8 cooperates with a servo valve seat 32 so that it can close the through channel 29 . The servo plate 28 has a servo valve element 33 which interacts with the valve seat 12 .

In the closed state, the valve element 8 bears on the servo valve seat 32 and the servo valve element 33 on the valve seat 12 . The pressure from the second opening 23 then arises in the auxiliary pressure chamber 30 . If the valve element 8 is now lifted off the servo valve seat 32 , then the pressure in the auxiliary pressure chamber 30 adjusts to the (normally lower) pressure in the first opening 22 because the cross section of the throttle opening is much smaller than the cross section of the through-channel, ie the pressure in the auxiliary pressure chamber 30 drops. The pressure in the second opening 23 then lifts the servo plate 28 , so that the servo valve element 33 lifts off the valve seat 12 and opens the passage between the first and second openings 22 , 23 .

As can be seen from a comparison of the two FIGS. 4a and 4b, here too the change from a normally open valve 301 to a normally closed valve 301 'results only from the fact that the return spring 21 to the other end of the armature 7 is set and the excitation arrangement 3 is accordingly shifted.

Claims (10)

1. Valve assembly for a solenoid valve with egg NEM housing, a valve element with an armature which is arranged in the housing, a valve seat and an electrical excitation arrangement, which is designed as a radial field generating device, characterized in that the excitation arrangement ( 3 ) in dependence of a desired basic function at two different axial positions on the housing ( 2 ) can be determined. 2. Valve assembly according to claim 1, characterized in that the housing ( 2 ) outside of the core ( 7 ) is filled with a material whose relative magnetic permeability in operation is less than 50. 3. Valve assembly according to claim 1 or 2, characterized in that the excitation arrangement ( 3 ) has a coil ( 4 ) which surrounds the housing ( 2 ), and egg ne in cross-section C-shaped cover ( 5 , 6 ) made of magnetically conductive Has material that covers the outside of the coil. 4. Valve assembly according to claim 3, characterized in that the cover has a first angle ( 5 ) which is arranged in the middle of the axial length of the armature ( 7 ), and a second leg ( 6 ) which in the rest position one end the anchor ( 7 ) is adjacent. 5. Valve assembly according to claim 4, characterized in that the second leg ( 6 ) is arranged at least partially axially outside the armature ( 7 ). 6. Valve assembly according to one of claims 1 to 5, characterized in that a return spring ( 21 ) is arranged at the end of the armature ( 7 ) to which the second leg ( 6 ) of the excitation arrangement ( 3 ) is adjacent. 7. Valve assembly according to one of claims 1 to 6, characterized in that the valve element ( 8 ) is at least partially relieved of pressure. 8. Valve assembly according to one of claims 1 to 7, characterized in that the armature ( 7 ) has at least one through opening ( 10 ) and the housing ( 2 ) in the region of its two axial ends has connection openings ( 22 , 23 ). 9. Valve assembly according to one of claims 1 to 8, characterized in that a ser vostufe ( 28-33 ) is arranged between the valve element ( 8 ) and the valve seat ( 12 ). 10. Valve assembly according to one of claims 1 to 9, characterized in that built-in parts ( 11 , 15 ) in the housing ( 2 ) are held positively.