DE829844C - Closing organ for pressure vessels, which is also provided with a device for pressure reduction - Google Patents

Description

Closing organ for pressure vessels, which at the same time with a device The shut-off valve of the invention is provided with a device provided, through which the emanating gaseous agent during emanation can be kept at a certain pressure level. 1) ic pressure regulating membrane is housed in your handwheel of the valve and can isoinit as a result of its large size Area appear relatively accurate.

Furthermore, the arrangement in this valve is such that the organs for the pressure reduction find space in the valve housing, without the size ratios to increase compared to the simple valve of the usual design. By twisting the In addition, the edge wheel can shut off the passage opening in the same way as lrei the usual oil shut-off valve.

The drawing shows four different exemplary embodiments Shut-off device with pressure reduction in axial section illustrated. Fig. I shows the axial section of the first embodiment, FIG. 2 the view of the, in the valve housing rotatable valve spindle with sealing plug.

The passage opening i of the valve can pass through the closure piece 2 be closed and opened in a known manner. For this purpose are at the Valve spindle 3 two pins 4 are provided, which are in the upper cross section of the closure piece 2 protrude. Through, the axis of the valve spindle 3 leads a hole 5 from below after ollen, where it extends into a cavity 7 formed by the handwheel 6 continues. In this cavity is the membrane 8, the edge of which by the screwed-in cover 9 is held tightly pressed. In, the middle of the diaphragm 8 a spindle io is attached by means of a nut i i. I) the spindle has io at the bottom End of a valve cone 12, which is the lower opening of the drilling 5 able to conclude in a suitable manner. The hole 5 stands. Through cross holes 13 with an annular groove 14 in connection, opposite to the leading to the outlet port 15 Bore 16 runs around the spindle io. Above and below the ring canal are 3 grooves screwed into the spindle, in which rubber rings are used for sealing 17 and 18 lie.

The membrane 8 or the spindle io are under the action of an or several springs which strive to lift the valve cone 12 from its seat to obtain. For this purpose, in the Ilohlraum of the handwheel 6 a through the Spring 19 held on cover 9 may be provided, which presses on membrane 8.

A coil spring 2o can also be incorporated in the cavity 5 be that between the approach 21 of the valve spindle on the one hand and a shoulder 22 is clamped, and tries to keep the valve in the open position.

The mode of operation of the valve is as follows: If the connecting piece 2 is screwed down, the passage opening i is closed. By turning the hand wheel 6 and the stopper 2, the off voltage will be uncovered i. The compressed gas can pass through channels 23 in the plug 2 into the space above the closure piece, in which it is sealed by the rubber ring 18. If the valve spindle io is lifted from the seat by the pressure of the spring i9 with the cone 12, the compressed gas can pass through the bores 5 and 13 into the groove 14 and from there through the bore 16 into the outlet port i5. The spindle 3 is also sealed off from the housing of the valve by the rubber ring 17 above the annular groove 14. As a result, the gas can only pass through the bore 5 when the valve cone 12 is lifted from the space above the dull closure piece 2 and pass through the annular groove 14 to the outside. If the pressure rises: in the cavity 7 of the handwheel below the membrane 8 so strongly that the springs i9 and 20 are compressed, the valve cone 12 closes the passage of the compressed gas to the bore 5. If, on the other hand, the pressure in the cavity 5 drops through escaping Compressed gas falls below a certain level, so the compressive stress falls in the cavity 7 and under the membrane 8, so that the springs 19 and 20 raise the valve cone 12 again for the passage of the compressed gas. By continuing this game, the constant pressure reduction of the outflowing pressurized gas is achieved. The top of the membrane must be under normal air pressure and for this purpose a hole 24 is provided in the cover 9 of the handwheel 6, which keeps the passage of air to the cavity above the membrane 8 open. So that the main spindle 3 is not pushed out of the valve body by the pressure of the gas, the spindle must be secured. This can be done by a stud screw 25 which projects into the neck of the spindle 3 and which holds the spindle on the upper shoulder. In order to fill the pressure vessel with the pressure medium, the valve spindle 3 must be raised so far that the rubber ring 18 is located above the bore 16. For this position, the stud screw 25 must be screwed back, and the main spindle 3 is secured in the raised position by the upper stud screw 26.

In the embodiment of the pressure reducing valve shown in FIG. 3, the spindle 27 with a thread 28 can be screwed into the valve body 29. In the lower end of the closure piece sits 3o, hard elastic material such. B. hard rubber in which there is a valve seat 31 above, the lower opening of which is connected to the free space around the lower end of the closure piece 30 by a transverse channel 32 . Above the locking piece 30 there is an axially continuous bore in the spindle 27 in which the locking spindle 134 with a conical tip is axially located. The tip closes the passage 31 in the lowered position or releases the passage in the raised position. The spindle 34 consists of a tube and has a transverse passage 35 at the bottom, which forms the connection between the bore 33 and the space 36 above the membrane 37. The membrane is suitably, e.g. B. connected to the spindle 34 by nut 38. The spindle penetrates a transverse wall 39 which tightly seals the cavity 33 at the top, while the spindle 34 can be moved up and down through the transverse wall 39. Above this wall 39 there is a sealing ring 40 which seals the passage of the spindle 34. A spring 41 presses the rubber seal 40 on the one hand and tries on the other hand to keep the passage 31 free by pressing against the membrane 37 by lifting the valve spindle 134.

The inner cavity 33 is formed by a transverse bore 42 and an annular groove 43 on the main spindle 27 with the outlet 44 on the nozzle of the valve in connection. Above and below the annular space 43 are rubber sealing rings in corresponding grooves 45 and 46 inserted, which ensure that the compressed gas only through the passage 31 pass into the cavity 33 and from there through the passages 42, 43 and 44 can. The space below the membrane 37 is through a bore 47 with the outside air in connection. The operation of this arrangement according to Fig.2 vst such that after Screw up the main valve spindle 27 with the handwheel, in which the diaphragm sits, the passage through the channel 48 is released and the pressurized gas through the Transverse channel 32 and can pass through the passage 31 of the valve, namely into the cavity 33 and from this into the transverse channel 42 and the outlet opening 44 in the Nozzle of the valve housing. The pressure prevailing in the cavity 33 divides through the transverse bore 35 of the spindle 34 with the space above the membrane 37 and this pushes the spindle 34 of the spring 41 counter downwards bir to close the valve seat 31. If the pressure decreases again, it is overcome Spring 41 the gas pressure on the membrane 37 and releases the valve seat. This game repeats itself or the valve 34, 35 arises when the gas passes through on a certain passage, which depends on the pressure of the spring 4i. The adjustment of the pressure can be done by changing the length between the transverse wall 39 and the membrane 37 by suitable adjustment devices, e.g. B. by screwing the mother 38, are brought about.

To fill the pressure gas into the pressure vessel are also in this Embodiment of the valve two studs to limit the stroke of the V, entilspiiidel27 intended.

A similar embodiment of the valve as FIG. 3 is shown in FIG. 4. Here, on the top with thread 49 screwable valve spindle 50 with handwheel 5 i below, the closure piece 52 with the conical valve seat 53 and the transverse passage 54 is provided Cross web 57 is connected. The membrane 58 located above acts with its center by means of a small plate 59 on two two-armed levers 6o, which engage with their outer ends on i (transverse web 57 and are pivotable in the middle around eyes 6i. It can be seen that when opening and Moving away the membrane 58 and the plate 59, the levers 6o exert up and down movements on the same, which are converted into movements of the transverse web 57 and the valve 55, 56 opposite to the movements of the membrane 58. The pressure on the lead wire the pressurized gas which fills the space of the valve thus causes the valve 55, 56 to close.

To bring about the open position of the valve, is above the Diaphragm a spring 62 is provided. The Hohlratun over the membrane 58 is with the Outside air in connection. To fill the pressure vessel with the valve closed a lateral connection piece 63 with check valve 64 is provided, which by a Closure cap can be closed. The passage of the check valve 6: I stands with your passage 65 of the valve in communication. In the case of the one shown in FIG Embodiment of the valve is the regulating diaphragm 66 in the one on the valve housing: seated housed upper cavity 67 and connected to your plunger 68, which in the axial Cavity 69 is displaceable. The cavity 69, which is connected to the passage opening 7o of the valve is connected through the side channel 71 with the connecting piece 72 in connection. The control valve 68 regulates the passage from the bottle to the connecting piece 72 in the same way as described for the other embodiments, where a spring 73 presses on the membrane 66 and the control valve 168 in the open position to keep looking. In order to be able to adjust the pressure of the spring 73, the cavity is 67 covered by a screwable cap 74 which acts on the compression spring 73. The cap 74 has a downwardly directed hollow projection 75 in the middle the bottom opening of which protrudes through all the spindles of the control valve 68. On the end of the spindle a stop 76 is screwed into the hollow extension 75; when the cap 74 is screwed back eats, the stop holds the control valve 68 and thus the passage 7o of the valve closed, so that the pressure-regulating effect is switched off. But you want to close the valve and leave the spring 73 unchanged in its setting, so can to complete the gas passage, the control valve 68 by tightening a The cord nut 79 is kept closed, which is attached to the outer end of the spindle of the control valve 68 can be screwed.

The lateral connection piece 77 can be used to fill the pressure vessel serve with check valve 78. Or it can control valve 68 .by pressing the stop 76 can be kept open for the filling of pressurized gas.

It may be desirable to close the low pressure side against high pressures secure, for which an overpressure safety device is used in a known manner can.

The exemplary embodiments described are not exhaustive. Of the The pressure reducer is organically assembled with the final part of the valve, and there is the possibility of the device for pressure reduction at a Perform normal size valve so that larger dimensions are not required. This results in a simplification and a reduction in the cost of production.

A similar embodiment of the valve with pressure reduction as Fig. 5 shows FIG. 6 in axial section and FIG. 7 in side view. Here is in the valve housing 8o, namely in a sufficiently wide cavity 81, instead of the regelden Diaphragm built into a bellows 82. In the bottom 83 of the bellows 82 is from below The mushroom valve 84 used for regulation is screwed in. The spindle 85 sets continues above the bottom 83 over the bellows. The bellows 82 is with your threaded ring 86 tightly screwed into the valve housing 8o. Inside .des Spring body 82 is a compression spring 87 embedded, which rests on the floor 83, while .the upper end under the pressure of the hub 88 one on the valve housing 8o screwable cap rests, by screwing the spring pressure increases or can be reduced. On the end of the spindle 85 penetrating the cap 89 sits a screwable cord nut 9o, which in the screwed up position the allows free movement of the control valve 84 while tightening the cord nut 9o the regulating mushroom valve 84 can be kept pressed firmly onto the seat, so that the passage of the pressure medium is closed .ist. The valve of Fig. 6 is at the same time provided with a display device for the set pressure height. to For this purpose, a cylinder is expediently on the valve body in the longitudinal direction 9i provided, which is below with the room of reduced pressure is connected in the valve housing 8o. # A piston 9z can be displaced in this cylinder gi. A compression spring 93 presses on the piston 9a, which is controlled by a screw 94 in the cylinder can be regulated. It can therefore be determined by the position of the piston in the cylinder the pressure acting on the piston can be made visible, which pressure your reduced pressure is equal to by a mark 95 associated with the piston 92 is provided, which is provided in a provided on the cylinder 9i about half the length extending slot 96 slides. There are graduation lines 97 along the slot 96 Provided with numbers indicating the pressure height. Setting up the pressure gauge also serves as a pressure relief valve. This effect occurs when the piston reaches the slot with its lower edge by the compressed gas in this position can escape through the exposed part of the slot.

To the shut-off device of the invention it should also be mentioned that -the same not only reduces the pressure, but also a complete blocking of the passage is possible in the valve.

Claims (1)

PATENT CLAIMS: i. Closing element for pressure vessels, which is also provided with a device for pressure reduction, characterized in that the pressure-regulating membrane under spring action is built into the handwheel that actuates the closure and the tappet of the control valve connected to the diaphragm is installed in the one used for closure Closing element for pressure vessels according to claim i, characterized in that the spindle of the valve connected to the handwheel carries at the lower end the closure piece which shuts off the main passage and contains the seat of the control valve inside. 3. Closing element for pressure vessels according to claim i , characterized in that the closure piece at the lower end of the main spindle also forms the valve seat for the control valve actuated by the action of the membrane .4. Closing element for pressure vessels according to claim i, z or 3, characterized in that the inner cavity with the handwheel connected main valve spindle with D Passages are provided which connect these inner hollow roughnesses with the gas with the reduced pressure to the passage opening in the side connection piece, and that seals are provided on the outer surface of the spindle above and below the passages, which separate the passage openings above the spaces - and secure below. 5. Closure element for pressure vessels according to one of claims i to .4, characterized in that the regulating valve needle of the pressure reducer contains a longitudinal bore which connects the inner cavity for the pressure-reduced gas in the main spindle with the control space above the membrane in the handwheel. 6. Closing member for pressure vessels according to claim i to 5, characterized in that the regulating membrane acts on the regulating valve needle by means of two-armed levers in such a way that the movement directions of 1 @ 1einbran and valve needle take place opposite to each other. 7. Closing element for pressure vessels according to claim d, characterized in that the opening movement of the ld @ rtil) valve spindle which shuts off the bottle passage is limited by a stop, and that the main spindle for the filling can be screwed back by moving the stop back so far that the passage from Main termination to the side connection stub of the valve is exposed. S. Closing member for pressure vessels according to claim 4, characterized in that a connection piece provided with a non-return valve is provided on the valve housing for filling the bottle and opens into the bottle passage channel below the main closure. 9. termination and pressure reducing valve for pressure vessels, characterized in that the member actuating the control valve, for. B. a membrane or a bellows is tightly mounted in the valve housing itself and that the pressure of a spring acting on the '_-membrane or the spring body can be regulated by a screw cap, while a nut on the outer end of the regulating valve spindle outside the cap screwable eats, through the tightening of which the cone valve can be locked in the closed position. ok Closing member for pressure vessels according to claim 1 or 9, characterized in that the member is provided with a pressure display device which is connected to the space of the reduced pressure. ii. Closing member for pressure vessels according to claim 10, characterized in that the member connected to the space de,: reduced pressure is designed as a cylinder in which a piston can be displaced which is under the pressure of an adjustable spring and is moved outside by a piston Visible mark the pressure height makes a pressure reduction area recognizable. 1a. Closing element for pressure vessels according to claim ii, characterized in that the mark on the spring-loaded piston serving to display the internal pressure moves in a lateral slot opening of the cylinder and the display device also serves as a pressure relief valve.