DE1125771B - Lung-controlled breathing gas supply valve for breathing apparatus - Google Patents

Description

One group of the known breathing apparatus is with a so-called lung-controlled breathing gas supply valve equipped, which depends on the breathing air requirement of the device wearer through breathing is actuated and pressurized gas can flow into the device from the pressurized gas reservoir. Known lung-controlled valves include those that are connected to the respiratory organs through a valve standing membrane or a breathing bag can be controlled. If when inhaling a certain Negative pressure is exceeded, the control component, for example the membrane, bends, thereby opening the lung controlled valve. The movement of the control member, e.g. B. the membrane, is transferred to the valve closure body by a lever system. The lung-controlled valve is switched on in the compressed gas line and can either be immediately under high pressure Pressurized gas from the pressurized gas supply or with the interposition of a pressure reducer with under medium pressure standing pressurized gas are fed. These known lung-controlled valves have the disadvantage that the responsive to pressure changes control component, for example the membrane, relatively must be dimensioned large so that a sufficiently large control force to open the valve is available stands. In order to achieve a sufficiently large control force, the leverage can also be adjusted accordingly be chosen large. By using large control components that respond to pressure changes the device becomes bulky. In addition, large areas are difficult to move. The usage a large leverage, however, has the disadvantage that the opening path of the valve is only relatively can be small. As a result, the supply of pressurized gas may be inadequate if there is a very great need for breathing be.

The invention aims to eliminate the disadvantages of the known components. The invention relates to a lung-controlled breathing gas supply valve for breathing apparatus and consists in that the lung-controlled breathing gas supply valve is assigned an auxiliary valve is caused by the flow energy of the opening of the lung-controlled breathing gas supply valve released gas flow is operated. The valve according to the invention has the advantage that the for the air supply required control energy not only from the pressure-actuated control component of the valve Needs to be applied, but also taken from the flow energy of the inflowing gas will. This has the advantage that the surface of the control component or the leverage Lung-controlled breathing gas supply valve for breathing apparatus

Applicant:

Drägerwerk, Heinr. & Bernh. Dräger,
Lübeck, Moislinger Allee 53-55

can be made smaller, because when the main valve is opened, the gas flow actuates the auxiliary valve and thus releases an additional path for the breathing gas.

A simple design consists in that in the compressed gas line from the lung-controlled breathing gas supply valve a storage surface is arranged, which is connected to the valve closure body of the auxiliary valve is and this is actuated. Another embodiment of the invention consists in that on the gas downstream side of the lung-controlled valve, a storage area is arranged, which is connected to the valve closure body of the auxiliary valve is connected and actuates this.

The valve closure body of the auxiliary valve can also be used as a valve seat of the lung-controlled breathing gas supply valve be trained. The valve closure body of the auxiliary valve is then expedient connected to a storage surface arranged in front of the lung-controlled breathing gas supply valve, which the auxiliary valve is actuated.

The invention is illustrated by means of some exemplary embodiments shown schematically in the drawing explained. It shows

Fig. 1 shows a cross section through a lung-controlled breathing gas supply valve,

Fig. 2 shows another design of the lung-controlled breathing gas supply valve in cross section and in an enlarged view Scale,

Fig. 3 and 4 cross-sections of two further designs of the lung-controlled breathing gas supply valve and

Fig. 5 is a three-dimensional representation of the design according to Fig. 4.

In the embodiment according to Fig. 1 is on the housing 1 of the lung-controlled breathing gas supply

209 519/56

valve 9 a of the inhalation hose leading to the device carrier is connected to the nozzle 2. The control chamber 3 of the housing 1 is covered by the control membrane 4, which in turn is protected by a cover 5 in which bores 6 are let in for pressure equalization with the surroundings. The control lever 7 of the lung-controlled breathing gas supply valve 9 a, which consists of the valve closure body 8 and the valve seat 9 firmly connected to the lever 7, rests on the control membrane 4. The valve seat is not permanently connected to the housing 1, but rather is arranged on the valve closure body 10 of the auxiliary valve 11, which lies against the valve seat 11 in the closed position. The two valves 9 a and 11 a are loaded by the closing spring 12, which is arranged in the high-pressure chamber 13, to which the compressed gas flows through the connecting piece 14. The valve closure body 10 of the auxiliary valve 11a is provided with a storage surface 15 which is located in front of the opening of the connecting piece 14. If a negative pressure is generated in the control chamber 3 when the device wearer inhales, the membrane 4 moves downwards. Doing this will the control lever? taken so that the closure body 8 tilts relative to the valve seat 9. As a result, compressed gas can flow from the high pressure chamber 13 into the control chamber 3 through the open valve 9 a. The flow energy of the compressed gas flowing through the nozzle 14 pushes the storage surface 15 away from the nozzle, so that the closure body 10 of the auxiliary valve 11 α is tilted relative to the valve seat 11 and this valve is opened.

The embodiment according to Fig. 2 differs from the design according to Fig. 1 essentially in that the valve closure body 16 and the valve seat 17 of the auxiliary valve 17a are next to the lung-controlled breathing gas supply valve 19a formed by the valve closure body 18 and the valve seat 19. Both valve closure bodies are loaded by springs 20 and 21. The valve closure body 16 is connected to a storage area 22. When, after opening the lung-controlled valve 19 a, pressurized gas flows through the connecting piece 23 into the chamber 24, it pushes the storage surface 22 away from the connecting piece, so that the auxiliary valve 17 a is opened.

With the design according to Fig. 1 and 2, the dimensions are to be selected so that the flow energy of the incoming compressed gas alone is not sufficient to open the auxiliary valve. For this purpose, for example, a diaphragm 24 a can be arranged behind the chamber 24 to guide the air. The storage area 22 lies between the connecting piece 23 and the diaphragm 24 a. This ensures that the storage area 22 is acted upon essentially only by the gas flow which is released when the lung-controlled valve 19 α is opened.

In the designs described above, the auxiliary valve is actuated by the high pressure. Both In the designs according to Fig. 3, 4 and 5, the auxiliary valve, on the other hand, is provided by the lung-controlled breathing gas supply valve outflowing compressed gas controlled.

In the design according to FIG. 3, a control lever 25 is also connected to the valve closure body 26 of the lung-controlled breathing gas supply valve 27 α, which rests against the valve seat 27. A branch line 29 leads from the high pressure line 28 to the auxiliary valve 31 a, which is formed by the valve closure body 30 and the valve seat 31. The closure body 30 is connected to a lever 32 which ends in a bored through storage surface 33 which is located on the downstream side of the lung-controlled breathing gas supply valve 27a and which includes the lever 25. When the lung-controlled valve 27 a is opened when the lever is moved and pressurized gas flows out through the outflow hole 34 to the left, the storage area 33 is also pressed to the left, whereby the auxiliary valve 31 a is opened.

The design according to Fig. 4 and 5 differs from the design according to Fig. 3 essentially only in that the valve seats 27 and 31 and the valve closure bodies 26 and 30 are parallel to one another. A pipe bend 35 is connected to the outflow bore 34 and is used at 36 to pass through it of the control lever 25 is pierced. The pipe bend 35 ends in front of the storage area 37, which is connected to the lever 32 of the auxiliary valve is connected. The mode of operation of the design according to Fig. 4 and 5 is the same like the mode of operation of the valve according to Fig. 3.

The two designs according to Fig. 3, 4 and 5 have the advantage that for the lung-controlled breathing gas supply Guide valve and the auxiliary valve are largely the same Components can be used.

Claims (5)

PATENT CLAIMS: 1. Lung-controlled respiratory gas supply valve for breathing apparatus, characterized in that it is assigned an auxiliary valve which is actuated by the flow energy of the gas flow released when the lung-controlled respiratory gas supply valve is opened. 2. breathing gas supply valve according to claim 1, characterized in that in the pressure gas line A storage area (22) is arranged in front of the lung-controlled breathing gas supply valve (19 a) which is connected to the valve closure body (16) of the auxiliary valve (17 a) and this actuated (Fig. 2). 3. breathing gas supply valve according to claim 1, characterized in that on the gas outflow side of the lung-controlled breathing gas supply valve (27 a) a storage area (33; 37) is arranged which is connected to the valve closure body (30) of the auxiliary valve (31a) and actuates this (Fig. 3 and 4). 4. breathing gas supply valve according to claim 1, characterized in that the valve closure body (10) of the auxiliary valve (Ha) is designed as a valve seat (9) of the lung-controlled breathing gas supply valve (9 a) (Fig. 1). 5. Breathing gas supply valve according to claim 4, characterized in that the valve closure body (10) of the auxiliary valve (lla) is connected to a storage surface (15) arranged in front of the lung-controlled breathing gas supply valve (9 a) which actuates the auxiliary valve (11 α). Considered publications:
German patent specifications No. 684 269, 748 598. 1 sheet of drawings © 209 519/56 3.