DE1406700A1 - Device for controlling the flow of gas from pressure vessels to the Atma, especially in diving equipment - Google Patents

Description

Device for controlling the flow of gas from pressure vessels for breathing, in particular -, #, in dew devices The invention relates to a device for controlling the outflow of gas from pressurized containers for breathing, especially when on your back the diver's portable diving equipment for breathing underwater, with the gas leakage by means of a pressure reducing valve arranged between the pressure vessel and a gas consumer is fed to the consumer in a controlled manner.

Be, 1 such known devices will make the diver breathe necessary gas is supplied when the diver pulls the pressure reducing valve through a suction force opens, i.e.

the diver has to create such a negative pressure on one side of an Iviembran by sudden suction that the membrane moves and the pressure reducing valve is opened. The valve is only open during this suction force. Such a control of the gas flow has the following disadvantages: The breathing gas only flows as long as the diver exerts a fairly large suction force. This rather high suction force is necessary because the kembra # has to be moved against a certain force that ensures the closing and sealing of the valve seat of the pressure graduation valve. The known control devices achieve the finest responsiveness of the pressure reducing valve up to the gas flow at a suction pressure of 3 cm water column. Furthermore, should the suction force increases with increasing depth, as acted upon by the water membrane keeps the pressure reducing valve is closed so that it requires a great effort to suck the required breathing gas at greater depths.

i, L, i-t The aid of the known control device is therefore an anoxmal Breathing required.

The object of the invention is to provide a device for controlling the gas flow that allows the diver to breathe in the same way as it is also common to kenschen outside of the water. The flow of gas should be achieved by the normal breathing movement, in such a normal way that that when breathing begins, there is first a large flow into the respiratory organs and then, with the gradual filling of the respiratory organs, the flow is diminished until the gas flow ceases completely when normal inhalation ceases is. The type of flow is thus precisely adapted to the normal breathing process results in a flow course with increased flow velocity with increasing immersion depth.

This object is achieved according to the invention in that the the pressure vessel connected to the unthrottled gas pressure, closed Pressure reducing valve by means of the movement of a iviembrang from which the device surrounding external pressure is loaded, with a pressure difference between this external pressure and the pressure occurring at the 1 #, (and piece of the consumer when breathing is, whereby the membrane is a space in which this external pressure prevails, of a another room connected to the consumer, in which the breathing occurs Pressure prevails, separates "and that the open pressure reducing valve through the dynamic Effect of the gas outflow is held in the open position.

Further characteristics of the invention emerge from the subclaims, the description and the drawing.

In the drawing, an expedient embodiment of the control device is shown purely by way of example. 1 shows a plan view of the opened diaphragm can; FIG. 2 shows a section along line II-II of FIG. 1 of the CD closed lilembrandose; 3 shows a section along line III-III of FIG. 1 of the closed Igembrand can; 4 shows a pressure reducing valve.

A diaphragm box 5 possesses two circular can shells 6 and 7. An interior space formed by the two can shells 6 and 7 is divided by a rubber membrane 8 into two spaces 9 and 10 , the space 9 by means of openings 11 with the outside and by means of a line 12 over Any known one-way valve (connected to a not shown #lundstUck of a diving device. Through the line 12 in the direction of the arrow the used respiratory gases are passed through the water-filled space 9 and the openings 11 into the open. The space 10 is with a line 13. Through the line 13 the breathing gas is fed to the diver in the direction of the arrow by means of the same, previously mentioned mouthpiece.

The two can shells 6 and 7 provided with flanged edges 14 and 15 are held together by means of a U-shaped, finite ring 18 with the interposition of a rubber sealing ring 16 and der'Mreffibran 8 and by means of a screw which is passed through an eye 17 (Fig. 3) suffices as a through hole and is screwed into another threaded eye at the other end of the ring, pressed together to form a seal. On the side of the membrane 8 facing the space 10, a Cleitplatte 19 is fastened by means of screws 191. The space 10 accommodates a pressure reducing valve 20 and its actuating members 21. The pressure reducing valve 20 is inserted into an opening 22 in the can shell 7 . The housing of the valve 20 is designed in two parts and consists of an insert 23 and a union piece 24. A push rod 27 with a sealing body 28 is guided axially displaceably within the sleeve 26 inserted in a bore 25. This push rod 27 is displaced by the movement of the Iviembran 8 by means of the actuating members 21 (FIG. 3) . An opening 29 arranged in the insert 23 , together with the sealing body 28, forms the valve seat with which a throttling of the high pressure from the pressure vessel is achieved. An annular sealing package 30, for example made of a polyamide plastic, is inserted in the cylindrical sealing body 28. The union piece 24 is insulated over the insert piece 23 with the interposition of a disk 31 and thus holds the pressure reducing valve in the bottom of the can shell 7 . In a blind hole 32 , the sealing body 28 can be axially displaced with a lateral play 34 against a compression spring 33 which is connected in series with the main body 28 and is supported on the bottom of the blind hole 32. If no force acts on the membrane 8 , the sealing body 28 closes the opening 29 in a sealing manner by the force of the pretensioned spring 33.

Metal wool 36 to keep dust out is introduced within bores 35, which are arranged in the throw-over piece 24 and through which the unthrottled gas of the pressure vessel flows. The bores 35 are arranged approximately parallel to the direction of movement of the sealing body 28. The union piece 24 has a conical, metal seat 37, on which a valve piece 39 of the pressure vessel, shown in dash-dotted lines, rests in a sealing manner without the interposition of a soft sealing washer. With the help of a screw 38 rotatably arranged on the union piece 24, the entire diaphragm box 5 is screwed onto the valve piece 39 of the pressure vessel. The reduced gas stream flows through the insert 23 and a line 40 into the space 10 and the line 13. In FIGS. 1 and 3 , the actuating members 21 for the sealing body 28 are shown. On a rod 41 fastened in the insert 23 , a double-armed lever is pivotably mounted in its bearing eye 42 and is secured against axial displacement by means of a locking ring 45. The lever consists of an angled round rod 43 and a tab 44 welded onto it. The round rod rests on the sliding plate 19 of the membrane 8 (FIG. 3). A one-armed lever 46 for actuating the push rod 27 is pivotably mounted in the insert 23 via a pressure plate 47 and a bearing pin 48. In the other end of the lever 46, an adjusting screw 49 is inserted, on which the tab 44 opens.

The operation of the control device is as follows: By means of the adjusting screw 49, the control device is adjusted in such a way that, for example, at a pressure of 1 cm water column on the Lembrar- 8 this via the actuators 21 the sealing body 28 against the force of the spring 33 of the opening 29 lifts and the gas can flow. Due to the dynamic effect of the gas flowing through the opening 29 , the sealing body 28 is still moved against the force of the pedal 33 "because the gas flowing through the stanchions 35 and the opening 29 entrains the gas in the backhole 32 in the same direction of flow and thus the . gas pressure in the blind hole 32 is reduced, the gas then flows through the newspaper 4C into the space 10. This flow of breathing gas from the Druckbehblter in the space 10 is independent of the gas requirements of the diver, and it continues until back in the space 9 and 10, the same pressure prevails. 1111.11it increasing depth of the scuba unit under water so that the gas flows in the space 10 to increase the pressure to the pressure acting on the diaphragm 8 pressure to maintain the equilibrium. during inhalation of the diver, that is at a pressure gradient from the line 13 to the space 10 , the gas flows through the line 40 into the line 13. The line 40 forms a jet apparatus with the space 10 , and at high speed from the Le tion 40 flowing gas entrains the gas volume from the space 10 . As a result of the reduced pressure in space 10, the membrane acts more intensely on sealing body 28 via actuating members 21.

By means of the low pressure of 1 cm water column on the Miembran 8 and the flow of gas thus set in motion, the valve is opened more intensely with the aid of the kinetic energy of the gas.

The pressure acting on the membrane 8 can only lead to the opening of the valve if the pressure in space 10 is lower than that in space 9 . As soon as the diver makes a normal movement of the tfri-afMn-s' by means of the first piece, not shown, there is a pressure gradient between spaces 9 and 10, and the water pressure moves the meander to open the valve. ie the grösoer the pressure difference is, the more the valve is opened and the greater the flow of gas from the pressure vessel to the diver. If the inhalation almost to the end, ie the pressure difference between the respiratory organs of the diver and the space 9 is lower, reduced As soon as the gas flow in the line 13 is interrupted, e.g. by closing the respiratory organs, the pressure wave forming in the line 13 immediately affects the space 10 and moves the membrane in the closing direction of the valve; the valve is closed again , and the sealing body 28 is created by means of the force of the spring 33 and the force of the sealing body acted upon by the unthrottled gas pressure from the differential area of the end faces of the sealing body 28, held closed.

Claims (2)

Patent claims before 1. Device for controlling the gas outflow from pressure vessels for breathing, in particular in the case of diving equipment for breathing underwater that can be carried on the back of the diver, the gas outflow being fed to the consumer in a controlled manner by means of a pressure reducing valve arranged between the pressure vessel and a gas consumer, characterized in that the closed pressure reducing valve (20) connected to the pressure vessel and acted upon by the unthrottled gas pressure is loaded by the external pressure surrounding the device by means of the movement of a membrane (8), in the event of a pressure difference between this external pressure and that at the mouthpiece of the consumer pressure occurring during breathing is open "whereby the membrane separates a space (9) in which this external pressure prevails, from another space (10) connected to the consumption -" in which the during breathing #According pressure prevails, separates, and that the open pressure reducing valve is activated by the dynamis chemical effect of the gas outflow is kept in the open position. 2. Apparatus according to claim 1, characterized9 that the reduced gas flow from the housing of the pressure reducing valve (20) to the consumer line (40) together with the space connected to the consumer (10) forms a known jet apparatus, and that this Movable membrane, which at least partially encloses the space, is movably connected to a sealing body (28), the position of which determines the valve seat. 3. Device according to claim 2, characterized in that the displaceable sealing body (28) is guided in a blind hole (32) of the housing of the pressure reducing valve (20) with lateral play (34) and that the faces in the direction of this mobility of the sealing body can be acted upon by the gas pressure, and the sealing body is arranged between the base and the valve seat by means of a valve spring (33) connected to it one behind the other and bit at the bottom of the blind hole, and that the crash guide are arranged for the movement of the sealing body. 4. Apparatus according to claim 3, characterized gekennzeichiie t ,. that the cylindrical sealing body (28) has, in its end face facing the valve seat, an attached sealing package (30) to cover the valve seat in a sealing manner. 5. Apparatus according to claim 3, characterized in that the pressure vessel for Ventileitz ührenden gas guide conduits (35) for gas-permeable and staubabhaltende, fine mesh screens (36) are arranged in the. 6. Apparatus according to claim 2, characterized in that the arm (43) of a double-armed plane rests on the inside of the membrane (8) that is on the Rw-m (10) , the second arm (44) of which is mounted on one in the housing of the pressure reducing valve , one-armed lever (46) rests, which itself is directly connected to the sealing body (28) in terms of movement via a push rod (27). 7. The device according to claim 6, characterized in that the position of the levers (43, 44) to one another is variable by means of adjustable screws (49) inserted at their mutual support points. 8. The device according to claim 6, characterized in that an inelastic sliding plate (19) is attached to the Iviembraneite lying on the arm (43). 9. The device according to claim 6, characterized in that the membrane (8) is arranged inside a membrane box (5) and the interior of the Iviembrandose through the membrane into a first space (9), which by means of openings (11) with which the membrane can = giving medium is in connection, in order to be subdivided into the second 1tEam (10), which is connected to the consumer and in which the D-ruokreduziezventil (-20) and the actuators (21) are arranged.