DE250867C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- M 250867 CLASS Ad, GROUP

in Berlin.

Patented in the German Empire on February 19, 1911.

The invention relates to a switching mechanism, in particular for operated with compressed gas or compressed air Remote detonator, in which the front of one of two differently loaded membranes with the back of the connected to the other by a bypass channel. While with a known rear derailleur this type of bypass channel is directly connected to the supply line

ίο and thus the one with the less burdened Diaphragm connected valve is kept closed, which is only when the pressure is reduced opens below the normal pressure level, the mode of operation of the switching mechanism according to the invention is essential other. It consists in the fact that the less loaded (operating) membrane on both sides with the same pressure is loaded if the more heavily loaded (pressure wave) membrane at

Lifting by a pressure wave releases the opening of the bypass channel. This is because of it achieved that the side connected to the supply line of the more heavily loaded Membrane also closes the opening of the bypass channel.

Several embodiments of the device are shown in the drawing.

Fig. Ι shows the cross section of a switching mechanism in rest position,

FIG. 2 shows the plan of FIG. 1,
■ ■. 3 shows the switching mechanism in the working position,
FIG. 4 shows the cross section offset by 90 ° from FIG. 3; FIG.

Figs. 5 to 7 are cross-sections of another embodiment,

8 and 9 show sections of this embodiment in connection with a changeover switch ;

Figs. 10 to 13 as well

14 and 15 each show a further embodiment.

The passage from the inlet nozzle 1 to the outlet nozzle 2 is in the rest position (Fig. 1) interrupted by a membrane 3, which by a spring 7 against the valve surfaces 5 is pressed. The pressure of the spring 7 is chosen so that the diaphragm 3 is affected by the operating pressure of the one entering at 1 Air or the gas is lifted from the valve seat 5 (Fig. 3) and, as a result, air or gas can reach outlet 2.

If the operating pressure is increased, the pressure under the pressure of the spring 8 is also increased The membrane 4 is lifted off the valve seat 6 (FIG. 4), and the air now passes through a diversion channel 11 on the back of the membrane 3. Since in this way the Membrane 3 is under the same air pressure on both sides, the spring 7 comes to the effect by pressing the membrane 3 against the valve seats 5 (Fig. 4) and the air passage after the outlet 2 shut off. If the higher pressure is later completely reduced again, the will also return Diaphragm 4 returns to its rest position, and the game can begin again.

In Fig. 5, 6 and 7, an embodiment is shown which differs from that just described only differs by the special design of the valve seat 6. In In the rest position, the pressure surface of the pressure wave membrane 4 is smaller than in the working position, and it is therefore only temporarily increased to control the rear derailleur Operating pressure required. At low pressure, the operating pressure diaphragm 3 closes below Action of the pressure of the spring 7 the passage to the output 2 from. By Under the action of the operating pressure, the membrane 3 is lifted from its seat and the Passage to exit 2 released (Fig. 6). Becomes a pressure exceeding the operating pressure Given a pressure wave, the pressure wave membrane 4 is also lifted from its seat, so that the air pressure on the opposite side of the operating pressure membrane through the bypass duct 11 3 arrives, which as a result of the air pressure on both sides, following the action of the spring 7, is pressed against its valve seat 5 and closes the air passage (Fig. 7). When the pressure wave drops to the normal operating pressure, however, the Diaphragm 4 are in their open position, because by enlarging the pressure area, which occurs when the membrane 4 is raised, the total pressure acting on it from below the spring 8 is able to overcome. Despite the drop in the pressure wave to the normal operating pressure, the Passage through the rear derailleur blocked.

Only when the pressure in the pipeline network is reduced below the operating pressure comes the membrane 4 also returns to its rest position.

The embodiment according to FIGS. 5 to 7, for example, allows application to a Lighting system in which the lamps are operated in a known manner with compressed air will. So far, simple switches have been used in such a system, through which when turning on the operating pressure in the pipeline network open the and when turning off the Operating pressure the closing of the gas access to the lamps happened. If you wanted one lamp for another at midnight delete, this had to be done by operating each lamp tap by hand. at Application of the switch according to FIGS. 5 to 7 can switch one lamp to the other from the The control center must be switched off when the air supply to those lamps which are to be deleted at midnight, with the switching mechanism shown in FIGS. 5 to 7 be equipped. All lamps are included, including those that are not are to be deleted, provided with one of the usual switches, which is activated when the Operating pressure in the air line opens the gas flow and when the pressure drops closes the gas flow in the air line.

The switching mechanism according to the invention can lead from the main tube to the lamp Branch line to be attached before the usual changeover switch or from one with this Pieces exist, as for example the Fig.'8 and 9 show. In this embodiment the membrane 3 is provided with a pin 14 which closes off against the gas line Valve 15 can bump. Fig. 8 shows the device in the rest position. Will If the air pressure in the pipe network increases to the operating pressure, the one occurring at 1 lifts Air the membrane 3 from the seat 5 and arrives at the outlet 2, which is connected to the air line of the lamp. At the same time, when the membrane 3 moves, the pin 14 is pressed against the valve 15, so that the gas entering at 12 reaches the outlet 13 connected to the lamp can (Fig. 9).

If a pressure wave is now given, the membrane 4 is lifted from its seat and the air is passed through the bypass channel 11 to the rear of the membrane 3. The from Both sides of the air pressure hit membrane 3 goes back to its seat 5 and thus closes the air access to the lamp. With the return movement of the membrane 3 the pin 14 is also free again, thereby giving the gas valve 15 the opportunity to under the action of the spring 16 to go back to his seat and the gas passage after locking the lamp.

By the device of FIGS. 8 and 9 it is achieved that the membrane, which is otherwise in the usual switch is saved, so that the whole facility requires only two membranes instead of the usual three.

In Figs. 10 to 13 is an embodiment shown, in which the space located on the back of the membrane 3 is not immediately with the open air, but through a channel 17 with the back of the other Membrane 4 is connected, the channel 17 being connected to the other membrane 4 coupled valve can be closed.

At low pressure, both membranes 3 and 4 rest on their seats (Fig. 10). at When the operating pressure is reached, the membrane 3 is removed from it in the manner already described Seat lifted and the gas passage according to 2 enabled. The room at the back the membrane 3 stands through a channel 17 with the space on the back of the other Membrane 4 in connection, so that when the membrane 3 is lifted, the on their Rear air can escape

(Fig. 12). When the pressure wave occurs, the membrane 4 is raised and thus also the valve 18 coupled to it closed, so that at the same time through the bypass channel 11 on the back of the membrane 3 reaching gas not on the back the membrane 4 and cannot escape (FIG. 13). After switching off the pressure wave the membrane 4 remains in the raised position and thus the valve 18 is closed. Only when the operating pressure is turned off and the membrane 4 the gas access to the bypass channel 11 has completed, the valve 18 is released and the rear of the Membrane 3 placed in connection with the outside air.

This switching mechanism intended for compressed gas or other gases set under higher pressure conditional on the use of lamps as soon as one lamp after the other is extinguished should, while the neighboring ones stay on, use a common switch in a manner similar to that used for the compressed air lamps has been described. The new device can also be combined with such a switch at the same time, as it is for example is shown in Figs. The membrane chambers are similar as in Figs. 10-13 through channels 11 and 17 connected to each other.

In the rest position, the low-pressure gas entering at 1 passes through channels 19, 17 and 22 to the pilot flame line. With a gradual increase in the gas pressure to the operating pressure the membrane 3 is raised and thereby the gas is allowed to pass through to the lamp connected at 2, while the membrane 4 is so loaded by the weight 8 that it is through the usual Operating pressure is not increased. At the same time, the gas passes through channel 19 into space 25 and from there through channels 17 and 22 to that of the latter connected pilot flame line. As soon as the full operating pressure is reached and that Weight 7 has assumed the highest position, the pin 20 provides access from Channel 19 completed.

If a pressure wave exceeding the operating pressure is given, the membrane 4 lifted and thereby the access to the channel 11 free. Passed through this channel 11 the gas through the membrane 3, which sinks back into its seat as a result of the pressure equalization on both sides. At the same time will when the membrane 4 is lifted, the valve 24 is closed, thereby preventing the Prevents gas in the space above the membrane 4. Through a throttle screw the pressure of the gas flowing to the channel 22 is reduced so far that a harmful back pressure on the membrane 4 is not possible. When the pressure wave decreases At the operating pressure, both diaphragms remain in the positions they just had -taken, since the same pressure is stored on both sides of the membrane 3 Membrane 4, however, as a result of the increase in area due to the weight during the lift 8 cannot be pushed back. Only when the operating pressure is turned off and low pressure occurs, the membrane 4 sinks back on its seat and lets through the Channel 17 flowing gas through the open valve 24, port 23 to channel 22 and flow into the connected pilot flame line.

In their details, the embodiments shown can be structural modifications without changing anything in the essence of the invention.

Claims (3)

Patent Claims: 1.Switching mechanism, especially for remote igniter operated with compressed gas or compressed air, in which the front side of one of two membranes with different stresses is connected to the rear side the other is connected by a bypass channel, characterized in that the less polluted (operational) The membrane is loaded with the same pressure on both sides when the more heavily loaded (Pressure wave) membrane when the opening is lifted by a pressure wave of the bypass channel. 2. embodiment of the switching mechanism according to claim 1, characterized in that that the side connected to the supply line of the more heavily loaded mem- . bran also closes the opening of the canal. 3. embodiment of the switching mechanism according to claim 1 and 2, characterized in that that the more heavily loaded membrane is connected to a valve (18), which, when the membrane is raised, connects the rear of the two membranes Channel (17) blocks. 1 sheet of drawings.