FR2461868A1 - Adjustable multiway EM valve for vehicle working cylinders - has electromagnet housing fitting either way up to valve housing - Google Patents

Abstract

The valve has an armature (25) biased in one direction by a spring and moved in the opposite direction by a magnetic force, the armature movement operating the valve element (3) via an operating rod (19) projecting from the valve housing (1). The housing (23) containing the electro magnet (10) and the armature (25) can be fitted to the valve housing (1) either way up. A relief chamber (8') for the valve (2) is incorporated in the valve housing (1) on the side to which the electro magnet housing (23) is fitted. Pref the valve comprises a 3/2 way valve for operating working cylinders with pressurised air, e.g. in a vehicle.

Description

 The present invention relates to a reversible multi-way electromagnetic valve with a frame which, in one direction, is subjected to the force of a spring and in the other direction, is moved by magnetic force, the casing of the electromagnet which can be fixed, in two positions at 1800, to n valve housing in which a valve is operated by the movement of the armature.

 A valve of this type is known (Swiss patent 488,133). This known valve has a frame which directly constitutes the closing element of the valve. But therefore, the electromagnet is traversed by the fluid, which often is undesirable and also has a drawback.

 Electromagnetic valves are also known which have a pusher between the armature and the valve (patent of the Federal Republic of Germany 807,348). However, in these valves, the electromagnetic part is not reversible and the passage of the pusher requires a seal which produces a loss of energy due to friction.

The electromagnetic multi-way valve of the invention is characterized in that, in a known manner, the valve is completely separated from the electromagnet, in that in addition, in a manner also known, the movable armature acts on a tappet, possibly with the interposition of a spring element, the tappet penetrating into the casing to actuate the valve there, and in that a valve discharge chamber has been placed in the casing, on the c8td where the electromagnet rests. Thanks to this characteristic, the valve of the invention has the advantage that on the one hand the electromagnet is not traversed by the fluid and that on the other hand the pusher does not, however, require any friction generating seal, because the discharge chamber of the valve is located on the side of the electromagnet housing. The valve therefore responds easily, it has a very short switching time and a low energy requirement. I1 is added to this that the valve of the invention can, thanks to the reversal of the electro-aSmant, pass simply from an open valve in the absence of current to a closed valve in the absence current.

Other characteristics and advantages of the invention will be better understood on reading the following description of an exemplary embodiment and with reference to the accompanying drawings in which
FIG. 1 represents a section in which, to the left of a center line, the valve is closed in the absence of current and, to the right of the center line, the valve is open in the absence of current, and
- Figure 2 shows a variant with a device for adjusting the air gap.

 A multi-way electromagnetic valve has a casing 1 into which a valve 2 is introduced. This is a three-way / two-position distribution valve. It has a closing element 3 which cooperates with two seats 4, 5 and which is subjected to the force of a spring 6 which tends to push it against the seat 5. This seat 5 is an exit seat which is arranged on a insert 7. The interior of part 7 is opened by means of a recess 8 in the direction of a lateral surface 9 of the casing of the electromagnet side 10 of the valve. An annular seal 11 has been introduced into the surface 9 and inside of it is a discharge chamber 8 'from which an air exhaust channel 12 leads which leads to a lateral connection 13 to the outside air. This connection 13 can be covered to the outside by a non-return valve.

In case of assembly of several electromagnetic valves to form what is called a line of valves, preferably only one connection 13 is monitored by a non-return valve, the others are connected together from one end to the other.

 The closing element 3 and the valve spring 6 are located in a chamber 14 which is connected to a consumer 15 by channels not shown.

 The seat 4 is the inlet seat of the valve 2. I1 is located at the end of a nozzle 16 in the axis of which is arranged a channel 17 connected to a connector 18 for supplying air to the casing 1 .

Inside the outlet seat 5, the end piece 7 has been pierced in the axis so that a pusher 19 can pass through it with lateral play. The pusher 19 is guided in a socket 20 which is fixed annularly in the part 7. One of its ends 21 is reduced and rests on the closing element 3; its other end 22 protrudes beyond the lateral surface 9 of the casing 1 and is designed to cooperate with the electromagnet 10.

 This electromagnet 10 has a casing 23 with a winding 24, a movable frame 25, a fixed core 26 and a tube 27 for guiding the frame. Whether the electromagnet 10 is mounted on the casing 1, as shown in the figure, on the left or on the right, all the parts 23 to 27 are identical. One of the montages is deduced from the other by a rotation of 1800.

We choose the left mounting mode when valve 2 is a closed valve in the absence of current (intake seat 4 closed), and the right mounting when right valve 2 is open in the absence of current (exit seat 5 closed).

 However, there are provided between the frame 25 and the core 26 elastic elements 28, 29, 30, 31 and 32 which are produced differently for the two types of mounting. For the left-hand mounting, only a spacer spring 28 is used which is stronger than the valve spring 6, and the core 26 is closed at the top by a plug 26 '.

In the assembly on the right, an elastic element 29, 30, 31, 32 has been introduced into the core 26 which consists of a sleeve 29 with a bottom 30, a pressure piece 31 and a tight spring 32 between the bottom 30 and the part 31. The sleeve 29 can slide in the core 26 and the length of the element 29, 30, 31, 32 is determined so that the spring 6 can hold the closing element 3 of the valve 2 on the outlet seat 5 when the electromagnet 10 is without current. The spring 6 must be weaker than the prestressed spring 32.

 When the electromagnet receives current, the following happens in the left-hand assembly: the armature 25 rises by compressing the spring 28. The spring 6 and the supply pressure existing under the closing element 3 lift it from the intake seat 4 and push it onto the outlet seat 5. The supply air reaches the consumer 15. In the assembly on the right, the appearance of current lowers the armature 25. The sleeve 29 is driven through the part 31 and its bottom 30 pushes the pusher 19 downwards, so that its end 21 moves the element 3 from the seat 5 towards the seat 4 and closes the supply in the air. The rest of the movement of the armature is absorbed by the spring 32. The compressed air then flows from the consumer to the atmosphere.

It can be seen that in the two mounting modes, the electromagnet 10 is always on the outlet side, that is to say on the air exhaust side of the valve 2. It therefore does not need to be pressure-tight. The valve housing 1 is the same for the two mounting modes, as are the essential parts of the electromagnet.

 FIG. 2 represents an assembly in which the elastic element 29, 30, 31 and 32 presents a variant in which the sleeve 29 is provided with a thread 33 and where, instead of the bottom 30, a screw 34 is introduced into the socket. With this device 33/34, the length of the prestressed elastic element can be modified to adjust the air gap between the armature 25 and the core 26. It is therefore possible to position the closing point of the intake valve 3/4 in the most favorable area of the magnetic force curve.

Of course, various modifications can be made by those skilled in the art to the devices or methods which have just been described only by way of nonlimiting examples without departing from the scope of the invention.

Claims (2)

1. Reversible multi-way electromagnetic valve with a frame which, in one direction, is subjected to the force of a spring and in the other direction, is moved by magnetic force, the casing of the electromagnet being able be fixed, in two positions at 180, to a valve housing in which a valve is operated by the movement of the armature, characterized in that, in a known manner, the valve (2) is entirely separated from the electromagnet (10), in that in addition, in a manner also known, the movable armature (25) acts on a pusher (19), possibly also with the interposition of a spring element (28, 29 , 30, 31, 32), the pusher penetrating into the casing (1) in order to actuate the valve (2) therein, and in that a discharge chamber (8 ') of the valve (2), on the side where the electromagnet (10) rests. 2. Valve according to claim 1, characterized in that means are provided in the core (26) for modifying the residual air gap between the frame (25) and the core (26) 2 Valve according to any one claims 1 or 2, for compressed air, characterized in that several subpumps (2) are connected so as to form a battery, and in that provision is made on the casing (1) of a valve ( 2) a connection (13) to the outside air monitored by a non-return valve,