DE10230180A1 - Bistable electromagnetic valve e.g. for refrigerator, comprises valve chamber located inside control coil and permanent magnets located in valve housing - Google Patents

Abstract

In the valve chamber (15) is slidable a valve member between two end positions, forming a magnetic armature for several permanent magnets (9,10) and at least one control coil (3). The permanent magnets are located inside the valve casing (2). Preferably the valve chamber is located inside the control coil. The permanent magnets are fitted next to the valve seat (17) and their polarization extends in axial direction. They are typically formed as annular magnets. Independent claims are included for cold generating circuit and for household machine containing such a circuit.

Description

The invention relates to a bistable electromagnetic Valve according to the preamble of claim 1.

Such valves are used, for example, in Refrigerant circuits used as in the Publications DE 37 18 490 or EP 10 54 200 are described are.

With such valves, this creates a bistable situation achieved permanent magnets outside the valve body arranged next to the valve chamber or next to the pole pieces are so that the valve body has two end positions at the Owns pole pieces, in which he uses these permanent magnets is held.

Such valves have high requirements with regard to the tightness and long-term stability. About that there is, as usual, the requirement for such a valve to manufacture as inexpensively as possible.

The object of the invention is accordingly a valve to propose that can be produced with little effort and is reliably tight.

This task is based on a valve for one Refrigerant circuit of the type mentioned by the characterizing features of claim 1 solved.

By the measures mentioned in the subclaims advantageous embodiments and developments of the invention possible.

Accordingly, a valve according to the invention is distinguished characterized in that the valve chamber within the control coil arranged and the outer wall of the valve chamber within the Control coil formed by a cylindrical tubular body is. The tubular body extends at least over the pole pieces inserted in the cylindrical tubular body out.

This means that unlike traditional valves not the pole shoes have the connections, but these are simply inserted into the tubular body.

There are tightness problems between the tubular body and the pole shoes completely prevented with the least effort.

In a development of the invention, the tubular body is so long trained that he was at least up to the Front faces of the control coil extends. Thus the Pipe body easily accessible even when the control coil is attached. In addition, the tubular body to the inside diameter be adapted to the coil without connecting points are taken into account.

Furthermore, fluid connections of the valve can be made in this case particularly easy on the outside of the control coil accessible, cylindrical tubular body can be attached.

A particularly simple training of such Fluid connection results from the fact that at least one End of the pipe body as a pipe connection for the fluid is used. In addition to a minimal number of sealing points this in turn offers the advantage of being extremely cheap Manufacturing, since the pipe connection in the simplest case by a End of the already existing cylindrical Tubular body is formed.

Further valve components are preferably used in the Pipe body used. Here, for example, come into question those necessary for the bistable function Permanent magnets or filter elements to remove dirt particles or more generally contaminants from the fluid filter out. In principle, however, can still other valve components easily in the cylindrical Tube body to be integrated.

Dirt filter, for example as a sieve tube or as magnetic filter element for the separation of magnetic or magnetizable particles can be formed, keep contaminants from the valve body and valve seat remote, so the wear of these components is effective is reduced. This in turn results in a high one Long-term stability of the valve. This is particularly important to point out that such valves are usually in closed fluid circuits are used so that the Filter capacity only for a single cleaning of the in Circulation fluid volume must be sufficient.

It is also advantageous to use at least one of the named Valve components on the inside of the tube body to fix at least in the axial direction. This forms the valve is manageable when not connected Unit without any valve components on the front can fall out of the cylindrical tube body.

The axial fixation can be done for example achieve the corresponding valve component inside of the tubular body is pressed with this. Such Compression can be done, for example, by external pressure accomplish on the tubular body with little effort, whereby especially several in one operation Valve components can be fixed. By pressing can also be a valve component in fix radial direction reliably.

For an axial fixation can be done in a simple Embodiment a circumferential bead or an outside pressed-in nose will already be sufficient. So can for example, all valve components are designed that they have a stop against each other so that the complete valve unit inserted into the tubular body by attaching a bead or nose on both sides is fixed in the tubular body, as well as by the mutual attacks against moving among themselves is secured.

In a further advantageous embodiment an additional one at least on one side of the valve chamber Inner tube inserted into the tube body. In this way a so-called 3/2 valve can also be implemented. The Space between the inner tube and the cylindrical tube body therefore serves as an inflow line, on or in the corresponding pole piece a channel to the inside Valve chamber is to be trained. In the simplest case, a such channel through a peripheral recess on Pole shoe are formed. The inner tube itself then forms a drain for the fluid in a switch position of the Valve body. In the other switch position it is opposite end of the tubular body can be used as a drain.

An embodiment of the invention is in the drawing shown and will be explained in more detail below with reference to the figures explained.

Show in detail

Fig. 1 shows a cross section through a 2/2 way valve according to the invention and

Fig. 2 shows a cross section through a 3/2 way valve according to the invention.

The valve 1 of FIG. 1 comprises a cylindrical tubular body 2 according to the invention as a valve housing which passes completely through a control coil 3. Adapter pieces 4 ensure a good fit in the valve housing 2 and are at the same time designed as flux guiding elements for increased magnetic flux through pole shoes 5 , 6 and through a valve chamber 7 . Inside the valve chamber 7 there is a spherical valve body 8 , which in the position shown rests on the ball seat 9 of the pole piece 6 and thereby closes a through hole 10 . The through hole 10 opens into the drain line 11 of the valve 1 .

The tubular body 2 extends into the space outside the coil 3 and thus also beyond the pole shoes 5 , 6 .

Ring magnets 12 , 13 located outside the tubular body 2 ensure the bistable behavior of the valve and are fixed by a spacer ring 14 between the adapter pieces 4 .

The pole piece 5 has recesses or flats on its outer circumference, through which fluid channels 15 result between the pole piece 5 and the tubular body 2 into the interior of the valve chamber 7 . The fluid channels could also be realized through bores in the pole shoe 5 , the inflow-side openings of which lie in the ring region between a tubular screen 18 and the outer wall of the tubular body 2 . The pole piece 5 also has a ball seat 16 in order to bring about a defined end position of the valve body 8 in the second end position, not shown.

The pole piece 5 comprises a step 17 on which the tubular screen 18 is pushed. At the opposite end, the tubular screen 18 is fixed in a magnetic filter 19 designed as a ring magnet. The tubular area of the tubular body 2, in which the tubular screen 18 and the magnetic filter 19 are located, serves as an inflow line 20 for the corresponding fluid, that is to say in particular for refrigerant.

Incoming fluid (see arrow P) first reaches the area of the magnetic filter 19 , which is designed as a ring magnet and comes into direct contact with the fluid. As a result, magnetic or magnetizable dirt particles are already permanently fixed on the magnetic filter 19 at a distance from the valve chamber 7 .

The fluid then enters the interior of the tubular screen 18 , which is closed on the end face at the opposite end by the pole shoe 5 or its gradation 17 . Fluid flow must be in the tubular sieve 18 thus carried radially outwardly with dirt particles, which are larger than the screen openings 21 of the Rohrsiebs 18, are retained in the interior of the Rohrsiebs 18th Thus, only cleaned fluid gets into the outer space 22 between the tube screen 18 and the tube body 2 . From there, the fluid reaches the interior of the valve chamber 7 via the fluid channels 15 .

The flow naturally only takes place when the valve is open, that is to say in the switch position in which the valve body 8 rests on the ball seat 16 and the through bore 10 is released.

A valve 1 according to the invention can be easily installed in a fluid circuit, for example a refrigerant circuit, which contains dirt-related particles that are incompatible with conventional refrigerant valves and cause malfunctions.

The use of the valve 1 is aimed at closed fluid circuits which, when considered over the life of the valve 1 , remain closed after manufacture. The filter capacity of the filter system consisting of a tubular filter 18 and a magnetic filter 19 is to be designed in such a way that the fluid in the circuit can be cleaned once without clogging.

In this way, that is to say through the use of a filter 18 , 19 in the inflow line 20 of the tubular body 2 and in particular through the direct arrangement next to the valve chamber 7 , an entry of dirt into the valve chamber 7 is reliably ruled out to such an extent that a permanently sealed and low-wear function of the Valve 1 can be guaranteed.

Fig. 2 corresponds essentially to the aforementioned embodiment, with a difference now a second tubular drain line 23 is led into the interior of the tubular body 2 to the pole piece 5 and is tightly fixed there in a corresponding bore 24 . The tubular body 2 and the drain line 23 are sealed against one another at a sealing point 25 , for example pressed or soldered.

This results in an intermediate space 26 between the drain line 23 and the tubular body 2 , to which an inflow line 27 is connected. The inflow line 27 can be soldered, for example, in a corresponding opening in the tubular body 2 .

In this embodiment, the pole piece 5 also includes a through hole 28 which connects the valve chamber 7 to the intermediate space 26 via the fluid channels 15 .

The fluid or refrigerant can get in the direction of arrow P into the intermediate space 26 and from there through the magnetic filter 19 into the now annular interior between the tubular strainer 18 and the drain line 23 . The fluid then flows radially outward into the outer space 22 between the tubular screen 18 and the tubular body 2 , from where it reaches the valve chamber 7 via the fluid channels 15 .

Depending on the switching position of the valve body 8 , the fluid then flows off either via the drain line 23 or via the drain line 11 . In the switching position shown, the through hole 28 of the pole piece 5 is open, that is to say the outflow takes place via the outflow line 23 .

The valve body 8 can be brought onto the opposing ball seat 16 by a control pulse of the control coil 3 , as a result of which the through bore 28 is closed and the through bore 10 is opened. In this switching position described, but not shown, the fluid flows out via the drain line 11 .

Instead of the adapter pieces 4 , which have a conical drain surface inside the control coil 3 , sleeve-shaped flux guide plates 29 are provided in the present case for guiding the magnetic flux inside the control coil 3 , which completely fill the space between the tubular body 2 and the control coil 3 . The flow guide plates 29 are each connected to an end plate 30 , which in turn is connected to, or merges with, so-called yoke plates (not shown). The flow guide plates 29 can be punched and bent or wound together with the end plate 30 and the entire yoke plate arrangement, not shown, from a flat material. REFERENCE NUMERALS 1 valve
2 tubular bodies
3 control coil
4 adapter pieces
5 pole shoe
6 pole shoe
7 valve chamber
8 valve body
9 ball seat
10 through hole
11 drain pipe
12 ring magnet
13 ring magnet
14 spacer ring
15 fluid channel
16 ball seat
17 gradation
18 tubular strainer
19 magnetic filter
20 inflow pipe
21 sieve opening
22 outdoor space
23 drain pipe
24 hole
25 sealing point
26 space
27 inflow pipe
28 through hole
29 flow baffle
30 end plate

Claims (13)

1. Bistable, electromagnetic valve with a valve chamber arranged between two pole pieces and a valve body displaceable therein between two end positions, which is designed as a magnet armature for at least one permanent magnet and for at least one control coil, characterized in that the valve chamber ( 7 ) inside the control coil ( 3 ) and the outer wall of the valve chamber ( 7 ) within the control coil ( 3 ) is formed by a cylindrical tubular body ( 2 ) which extends at least beyond the pole shoes ( 5 , 6 ) inserted into the cylindrical tubular body ( 2 ). 2. Valve according to claim 1, characterized in that the tubular body extends at least up to the end faces of the control coil ( 3 ). 3. Valve according to one of the preceding claims, characterized in that the fluid connections ( 11 , 20 ) of the valve ( 1 ) on the cylindrical tubular body ( 2 ) are attached. 4. Valve according to one of the preceding claims, characterized in that at least one end of the tubular body ( 2 ) forms a pipe connection ( 11 , 20 ) for the fluid. 5. Valve according to one of the preceding claims, characterized in that valve components ( 18 ) are inserted into the cylindrical tubular body ( 2 ). 6. Valve according to one of the preceding claims, characterized in that a dirt filter ( 18 ) is inserted into the cylindrical tubular body ( 2 ). 7. Valve according to one of the preceding claims, characterized in that at least one valve component ( 5 , 6 , 18 ) on the inside of the tubular body ( 2 ) is fixed at least in the axial direction. 8. Valve according to one of the preceding claims, characterized in that at least one valve component ( 5 , 6 , 18 ) inside the tubular body ( 2 ) is pressed with this. 9. Valve according to one of the preceding claims, characterized in that at least one bead or nose is at least for axially fixing a valve component ( 5 , 6 , 18 ) pressed into the tubular body ( 2 ). 10. Valve according to one of the preceding claims, characterized in that an inner tube ( 23 ) is inserted into the tubular body ( 2 ) at least on one side of the valve chamber ( 7 ). 11.Method for producing a bistable electromagnetic valve with a valve chamber arranged between two pole shoes and a valve body displaceable therein between two end positions, which is designed as a magnet armature for at least one permanent magnet and for at least one control coil, characterized in that a continuously cylindrical tubular body ( 2 ) is used as the outer wall of the valve chamber ( 7 ), valve components ( 5 , 6 , 18 ) being inserted into the tubular body ( 2 ). 12.Cooling circuit for a cooling system, in particular with a plurality of cooling rooms, a compressor, a condenser, a plurality of evaporators which are assigned to at least one of the cooling rooms and at least one electrical control valve for connecting the condenser to one or more of the evaporators in accordance with predetermined operating states, characterized in that that the control valve ( 1 ) is designed according to one of the preceding claims. 13. Household appliance with a refrigeration circuit, especially refrigerator or freezer, thereby characterized that a refrigeration cycle with a Valve according to one of claims 1 to 10 is provided.