FI71191B - PNEUMATIC DOUBLE SAW VALVE - Google Patents

Abstract

1. Double-seat pneumatic valve, especially for rail vehicles, for example for actuating a current collector, an anti-slip device, or a sanding device, said valve comprising : - a movable valve plunger (11) ; - a valve body (13, 14) which is rigidly attached to the valve plunger (II) and possesses two sealing rings (23, 24) which protrude radially and are held in a manner such that they are axially spaced ; - two stationary valve seats (25, 26) which face one another and severally cooperate with one of the sealing rings (23, 24), these valve seats (25, 26) severally encircling a through-opening from a middle valve chamber (C) to an outer valve chamber (B, D), the diameter of the valve body (13, 14) being smaller than that of the through-openings ; - two rings (27, 28) which are installed on the valve body (13, 14), between the sealing rings (23, 24), in a manner such that they can be moved by sliding, a spring (29), installed between these rings (27, 28), causing them to press the two sealing rings (23, 24) onto the valve seats (25, 26) when the double-seat valve is in the neutral position, while in each of the opening positions the two rings (27, 28) limit the valve travel as a result of coming into contact with one another, characterized - in that the sealing rings (23, 24) are inset into peripheral grooves (21, 22) in the valve body (13, 14) ; - in that each of the peripheral grooves (21, 22) has a chamfer (31) on one side, this chamfer (31) serving as a supporting surface for the inset sealing ring (23, 24), and - in that each of the spring-loaded rings (27, 28) has a flange (30) which points radially inwards and bears against the valve body (13, 14) in order to limit its sliding movement thereon, in the direction of the valve seat (25, 26).

Description

71191

Pneumatic double seat valve

The invention relates to a pneumatic double-socket valve, in particular for rail vehicles, e.g. a valve seat cooperating with a sealing ring, each of which closes the bushing from the central valve chamber to the external valve chamber, the cross-section of the valve body being smaller than the bushings of the bushings valve seat, and the valve stroke in each open position on both sides are limited to each other.

Double-seat valves of this type, in which elastic sealing rings are arranged on the valve plates, are known. As long as the sealing rings are new, it can be seen that in the middle position of the valve plate, both valves are closed. However, as soon as the sealing rings have become less elastic due to aging, there is a danger that both valves will no longer be closed at the same time. However, it is particularly important that in the middle position of the valve stem both valves are closed at the same time, when, for example, only a small amount of compressed air at low pressure must be supplied by means of a hand pump in order to move the current collector. In this case, the compressed air will not be able to press the sealing ring tightly against its valve seat. In this case, it may happen that in the middle position of the valve stem 2 71191 the valve remains open and the double-seat valve does not work properly.

The task to be solved in the above invention is to be able to create a double-seat valve in which, in the central position of the valve seat, both valves are reliably closed. A pneumatic twin-seat valve according to the invention, in which this object is solved, is characterized in that the sealing rings are arranged in the circumferential grooves of the valve bodies, in each circumferential groove on one side there is a chamfer acting as a sealing ring support surface and in each spring-loaded flange to prevent movement of the supports to the valve body.

Preferred embodiments of the invention will become apparent from the appended subclaims.

Various embodiments of a double seat valve according to the invention will be described below with reference to the accompanying drawings. The figures show: Fig. 1: a perpendicular section of a first embodiment of a double-seat valve, Fig. 2: a perpendicular section of a second embodiment of a double-seat valve, Fig. 3: a perpendicular section of a third embodiment of a double-seat valve.

According to Fig. 1, the double seat valve according to the invention, corresponding to the first embodiment, has a valve pusher 11 which is movable in a way not shown, e.g. pneumatically, hydraulically or electromagnetically, that is, the valve pusher li 3 71191 can be pushed up or down from the middle position of the double arrow A direction, as is explained in more detail below. This valve pusher 11 has a shoulder 12 adjacent to a first valve plate 13. Adjacent to this first valve plate 13 is a second valve plate 14 with sleeve-like stops 15. These two valve plates 13 and 14 differ substantially in said sleeve-like stop 15. By means of the nut 16, both valve plates 13 and 14 are pressed against the shoulder 12 of the valve pusher 11. The valve pusher 11 has two grooves 17 and 18 in which the sealing rings 19 and 20 are inserted. Similarly, both valve plates 13 and 14 have two circumferential grooves 21 and 22 in which two sealing rings 23 and 24 are likewise placed. The sealing rings 19 and 20 in the valve pusher 11 have a circular cross-section and the sealing rings 23 and 24 in the valve plates 13 and 14 have . The sealing ring 23 of the first valve plate 13 is located in the position shown next to the upper valve seat 25 of the valve body (not shown) and the sealing ring 24 of the second valve plate.14 is located in the position shown. adjacent to the lower valve seat 26 of the non-stop valve body. The first ring 27 is slidably mounted on the upper valve plate 13 and the second ring 28 is slidably mounted on the lower valve plate 14. The coil spring, which rests on the first ring 27 on the one hand and the second ring 28 on the other hand, has a tendency to press both rings 27 and 28 against both sealing rings 23 and 24, and then presses the sealing rings against the associated valve seats 25 and 26. In the position shown, each of the two rings 27 and 28 with its flanges 30 is located against its associated valve plate 13 or 14. As can be seen from the figure, either of the rings 27 and 28 can be pushed against the force of the coil spring 29 a distance. The circumferential grooves 21 and 22 of the vent brick discs 13 and 14 each have a recess 31 which allows the sealing rings 23 and 24 to be inclined as long as they are held in contact against this chamfer.

4,71191

The operation of the described double-seat valve 10 is as follows: In the shown central position of the valve pusher 11, both sealing rings 23 and 24 are located against their respective valve seats 25 and 26 and no compressed air can flow from chambers B, C or D. If the valve pusher is lowered by distance a, both valve plates 13 and 14 travel a, the first ring 27 being pressed against the second ring 28 against the force of the spring 29. The lower sealing ring 24 presses against the bevel 31 of the circumferential groove 22 and is further located against the lower valve seat 26. However, the upper sealing ring 23 is raised from its valve seat 25 so that compressed air can flow from chamber C to chamber B. Correspondingly, by raising the valve pusher 11, both valve plates 13 and 14 increase by a, then the second ring 28 is pressed against the first ring 27 . The upper sealing ring 23 is pressed against the bevel 31 of the circumferential groove 21 and is further located against the upper valve seat 25. However, the lower sealing ring 24 rises from its valve seat 26 so that compressed air can flow from chamber C to chamber D.

The second embodiment of the double seat valve 10 according to the invention, according to Fig. 2, differs from the first embodiment shown substantially in that instead of the circumferential grooves 21 and 22 the valve plates 13 and 14 have annular grooves 32 and 33 on the end faces of the rings 27 and 28. 34 and 35.

A third embodiment of a double seat valve according to the invention, according to Fig. 3, differs from the second embodiment shown essentially in that instead of annular grooves 32 and 33 on the end faces of rings 27 and 28, fixed valve seats 7 and 26 have annular grooves 36 and 37, 38 and 39 are set.

The mode of operation of the second and third embodiments is not substantially different from the mode of operation of the first embodiment. In this case, it can only be seen that in the first embodiment, in all the functions of the valve, there is a stronger deformation of the sealing rings 23 and 24 than in the case of the sealing rings 34 and 35 or 38 and 39 of the other two embodiments.

Claims (4)

1. Pneumatic double seat valve, especially for rail vehicles, e.g. for actuating a current pickup, or an anti-slip device for a sand spreader device, comprising a movable valve bump (11), a valve body (13, 14) rigidly attached to the valve bump, which are two axially spaced apart radially sealing rings (23, 24), two stationary facing each other and each through a sealing ring (23, 24) cooperating valve seats (25, 26), each of which suspends passage from the middle valve chamber (C) to the outer valve chamber (B, D), wherein the intersection of the valve body (13, 14) is less than the diameter of the passage in the valve body (13, 14) between the sealing rings movably adapted rings (27, 28), which are adapted by means of a between the rings (27, 28) spring (29) in the intermediate position of the double-seat valve pushes both sealing rings (23, 24) against the valve seat (25, 26), and in each open position of the valve stroke mutually adjacent to each other, characterized in that the sealing rings (23, 24) are adapted in the valve bodies (13, 14) pe ridge flaps (21, 22), each peripheral flange (21, 22) on one side having a bevel (31) which acts as a support surface for the sealing ring (23,24), and each spring ring (27, 28) having a radially inward flange (30) which supports the valve body (13, 14) so as not to displace. Double seat valve according to claim 1, characterized in that the sealing rings (23, 24) are loosely located in the peripheral spheres (21, 22). A double seat valve according to claim 1 or 2, characterized in that the bevel (31) is on the side of the peripheral sphere (21, 22) which is directed to the corresponding valve seat (25, 26). 2 Double seat valve according to any of claims 1-3, characterized in that the rings (27, 28) have a disc-shaped recess (32) in which the sealing rings (23, 24) are partially located.