DE1165369B - Push-button switch for rooms at risk of pressure surges - Google Patents

Description

Push-button switch for rooms at risk of pressure surges The invention relates on a push-button switch for rooms at risk of pressure surges, comprising a Push-button, which by resiliently engaging locking elements against unintentional displacement is secured, the locking members of an elastic, preferably simultaneously acting as a seal envelope are enclosed.

Push button switches of this type are known. There are also push-button switches known, in which a slide sliding in a guide by radially in locking notches spring-loaded locking elements on the slide to prevent unintentional displacement is secured up to a predetermined limit force.

The invention is based on the object of a particularly simple one Specify the structure of a push button switch of the type mentioned at the beginning.

To solve this problem, the push button switch is characterized by that the hood both on the pusher surface and on the locking members indirectly or immediately resiliently applied, so that when pressure surges occur, that of the locking force exerted on the locking members is increased.

The invention is illustrated in the following exemplary embodiments Reference to the figures described. It represent F i g. 1 and 2 a longitudinal section or a cross section through a first embodiment, FIG. 3 a section corresponding to that of FIG. 1 through a second and third embodiment, F i G. 4 shows a section corresponding to that of FIG. 1 by a fourth embodiment.

The in the F i g. 1 and 2 includes switching element shown as essential Part of a movable piston-like body 1 which widens in its upper part and there a number of pyramidal or conical surfaces Has annular grooves. A number of locking members engage in one of these annular grooves a. In the embodiment of FIG. 1 and 2 there are six locking elements. These Locking members are tapered towards cutting edges. These cutting edges are in one or more bottom grooves 3 of an annular body 4 through which the piston 1 passes will. The upper part of the piston-like body 1, the locking members 2 and the upper Part of the ring body 3 are enclosed by a spherical cap 5 made of elastic material.

If on the top surface of the piston-like body 1, a force F of A certain size is applied, the elastic dome 5 is flattened and allows a displacement of the piston-like body 1 downwards. The Locking members 2 apart, because by the interaction of the conical surfaces the locking members and the conical surfaces of the annular grooves becomes a force component generated radially to the longitudinal axis of the piston-like body 1, which is a displacement the locking members 2 causes radially outward. The locking members rotate in the process around their cutting edges lying in the bottom groove of the ring body. When relocating Outward locking elements also become the elastic dome in the area of these locking elements pulled outwards and thereby tensioned.

Once the radially inward tip of the locking members on has reached the highest point of a conical surface forming an annular groove, there is for the piston-like body 1 no longer an obstacle, very quickly and suddenly to advance below, in particular thanks to the stored in the tensioned spherical cap 5 Energy that acts on the locking members and the tips of the locking members now can cooperate with the conical surfaces of the annular grooves in the sense that the piston-like body 1 is pressed down.

When the elastic dome 5 of a sudden change in the ambient pressure P is exposed to a surrounding liquid, this pressure is effective on the top surface of the piston-like body 1, but at the same time also on the Coat of the dome in the area of the locking members 2, so that that on the pressure acting on the top surface is kept by the increased balance Locking effect of the locking members.

In the embodiment of FIG. 3, the locking members are cylindrical bolts 7, which engage with radially inner tips in the annular grooves again formed by conical surfaces, or balls B. Furthermore, the locking members 7 and 8 are pressed by an elastic ring 10 into the annular groove of the piston-like body 1 ' . This elastic ring 10 sits on a shoulder of the ring body 9. A dome 11 surrounds part of the ring body 9, the elastic ring 10, the locking members 7 and 8 and the piston-shaped body 1 'with its pusher plate 12. The dome 11 can be in this Embodiment, however, be made far weaker because the elastic restoring force for the locking members 7 and 8 is now supplied by the elastic ring 10 and the dome 11 therefore only has to provide a seal and also serves to transmit external pressures on the elastic ring 10 .

A pressure in the direction of the arrow F causes an adjustment of the piston-shaped Body down. A pressure that acts evenly on the entire switching element cannot bring about such an adjustment because of the increased pressure the top surface of the piston 1 'is opposed to an increased locking force.

Not even shock waves are able to operate the switching elements.

In the embodiment of FIG. 4, the switching element is used to actuate an electrical contact. The piston-like body 13 is guided in an annular body 14 and widens conically upwards. The conical surface engages with locking members 16, which are hingedly attached to the ring body 14. An insulating body 17 with a feed-through pin 18 to which an electrical line 18 'is connected is screwed into a lower opening of the ring body 14. The piston-like body 13 carries on its underside opposite the feed-through pin 18 a contact body 20 which, when the piston-like body 13 is displaced downward, comes into contact with the feed-through pin 18 and makes contact. The ring body 14 is grounded and forms part of the closed circuit when the contact 20 and the lead-through pin 18 come into contact with one another.

A spherical cap 22 surrounds the ring body, piston and locking members. she lies on both the piston and the locking members. With increased pressure on them the piston is loaded, but at the same time the locking members in the The sense of an increased locking effect, so that even with sudden increases in external pressure actuation of the switching element is not possible. The switch is only operated when on the top surface of the piston-shaped body, which here is concave is, an additional external force acts.

Also in the embodiment of FIG. 4, the elastic restoring force of the locking elements can be provided by an additional element. In this case, the calotte 22 can be dimensioned weaker, since it then only serves for sealing and not also as a restoring force for the locking members.

Claims (6)

Claims: 1. Push-button switch for rooms at risk of pressure surges, comprising a handle, which is secured against unintentional displacement by resilient locking members, the locking members being enclosed by an elastic, preferably at the same time acting as a seal cover, characterized in that the hood (5 , 11, 22) rests directly or indirectly elastically on both the pusher surface (1, 12, 13) and the locking elements (2, 7, 8, 16) so that the locking force exerted by the locking elements is increased when pressure surges occur . 2. Push button switch according to claim 1, characterized in that the push button is formed in a manner known per se from a piston-like body (1) guided in an annular body (4) , that the annular body opens towards the end face of the pusher surface and is formed by annular grooves formed by conical surfaces (3) has that the locking members (2) are pivotally mounted in the annular body in an annular arrangement and engage with the corresponding tips in the annular groove shape and that the hood (5) both on the end face of the piston-shaped body and on that of the tips remote back of the locking links. 3. Push button switch according to claim 2, characterized in that that the locking members (2) with cutting edges in rings (3) of the ring body (4) are. 4. Push button switch according to one of claims 1 to '. characterized in that the locking members (16) are articulated in an annular body (14) surrounding the pushbutton body (13) by means of axle bolts (15). 5. Push button switch according to claim 1, characterized in that the locking members are bolts (7) which in radial bores in an annular body surrounding the snap fastener body (1 ') (9) are guided and with points or rounded heads in ring grooves in the snap fastener body intervention. 6. Push button switch according to one of claims 1 to 3, characterized in that in a known manner the locking members are balls (8) which are mounted in radial bores of an annular body (9) surrounding the pushbutton body (1 ') and in the annular grooves of the snap fastener body. Documents considered: French Patent No. 1166 504; U.S. Patent No. 2,329,182; AWF-VDMA-VDI gear booklets, order no. AWF 6061, Berlin 1955, pp. 33 to 37.