DE864810C - Oxygen breathing apparatus with breathing air circulation and lung-controlled oxygen supply - Google Patents

Description

Oxygen breathing apparatus with breathing air circulation and lung-controlled Oxygen Delivery The invention relates to. a closed loop oxygen breathing apparatus the breathing air and lung-controlled oxygen supply through an auxiliary valve controlled Sawstoffzufüihrungsyentil. The auxiliary valve was previously used in such devices solely for the purpose of supplementing the equipment wearer depending on the size and number of breaths consumed. Oxygen, from the oxygen supply valve to regulate. For the elimination of the. Contaminated as an impurity in the oxygen supply A special purge device in the form of a purge valve or nitrogen was used a constant oxygen supply in addition to the lung-controlled one, and for the elimination of any overpressure in the device, a special one was made. Overpressure vent valve arranged. This made a rational use of the carried oxygen supply prevented and the clarity and the Device difficult.

These disadvantages are avoided according to the invention in that the control chamber of the diaphragm case of the auxiliary valve. via a check valve is connected to the exhalation line and to the outside air via a second valve, so that the control device of the auxiliary valve also serves as a flushing pump, whose membrane flowed into the control chamber during exhalation Exhaust air, as soon as the breathing bag is filled by the exhaled air or the incoming oxygen has been, under the action of a spring, via the second valve as purge air into the Free presses.

Preferably: the control chamber of the diaphragm, ngeh.änases desi auxiliary valve via the non-return valve to the exhalation vent chamber and via that of the stiffened wall of the breathing bag operated pressure relief valve with the outside air connected, while, the back pressure chamber of the diaphragm housing of the auxiliary valve with the breathing line leading from the alkaline cartridge to the breathing bag in open connection stands.

In one embodiment of the oxygen breathing apparatus according to of the invention is the oxygen supply valve controlled by the auxiliary valve operated by a diaphragm which, after opening the auxiliary valve, is activated by the pressure of: Via the auxiliary valve in the control chamber of the mem: brangehäuses, des [email protected]: one: flowing Saaersto: ffs is moved into the open position. Preferably is In this breathing apparatus the control chamber of the membrane housing of the oxygen supply valve Via a stagnation nozzle with the oxygen supply line leading to the breathing bag tied together.

In another embodiment of this new oxygen breathing apparatus. the oxygen supply valve controlled by the auxiliary valve is covered by a membrane actuated, which is moved into the open position after the auxiliary valve is opened, that from: the back pressure chamber of the membrane housing of the oxygen supply valve Oxygen flows off into the breathing line via the auxiliary valve. The that. Oxygen supply valve actuating diaphragm is preferably provided with a narrow throttle opening, over which only balances the pressures in the control chamber and in the back pressure chamber takes place with a short delay.

Fig. I shows a schematic representation of an embodiment the invention.

The opening i becomes the: Oxygen breathing apparatus on the mask or that the mouthpiece of the device wearer is connected. The exhaled air takes hers Path through the exhalation port: also 2 ,, the: exhalation valve 3 and the pipe 4 in the alkaline cartridge 5, in which the carbonic acid of the exhaled air is bound. By the breathing line 6, the purified air flows into the breathing bag 7 and can out of it -through the line 8, the inhalation valve: l g, the, inhalation tube 1o and the opening i be inhaled.

Following the oxygen supply flap ii is behind the shut-off valve 12 in the scheme, a pressure reducing valve 13 is indicated that for the execution of the Invention is not essential and can therefore also be absent.

As: Example of one: regulated by a lung-controlled auxiliary valve Oxygen supply: sventi: The diagram shows an auxiliary valve 14, which: through a Diaphragm: r5 is actuated. The control chamber 16 and the back pressure chamber 17 above or below the membrane 15 is closed to the outside. The control chamber 16 is via a check valve 18 and a line 1g with the chamber 2o of the exhalation valve 3 and is connected to a second line z1 to a pressure relief valve 22 connected, which is attached to a fixed component 23 of the device and whose control button 2: 4 is a wall part 25 of the breathing bag stiffened by a plate 7 faces. The back pressure chamber 17 below the membrane 15 connects a Line 26 with the arranged between the alkali cartridge 5 and the breathing bag 7 Breathing line 6.

The movement of the diaphragm 15 is transmitted to the auxiliary valve 14 by a rod 27. In general, a lever transmission must be switched on between the rod 27 and the diaphragm 15. 28 is the closing spring of the auxiliary valve i4. The rod 27 is passed with a narrow guide 2g through the bottom of the counterpressure chamber 17 into a chamber 3o into which the oxygen flowing out through the auxiliary valve 14 flows. From the chamber 3 0 A line leads 31 @in: the control chamber located to the left of the diaphragm 33 32 of the actual Sauerstoffzuführungsventil9 34 and from this one: another line 35 having a narrow pitot tube 36 to the angesichlossienen to the breathing bag 7 oxygen line 37. This takes also the oxygen flowing out of the main valve 34. The scheme indicates that at the exit point: des. Oxygen from the main valve 34 nor a throttle opening 38 can be arranged.

The operation of the oxygen respirator according to Fig. I is as follows: After opening the shut-off valve 12 of the oxygen storage bottle 1i, the oxygen passes through the pressure reducing valve 13 or, if this is missing, directly to the closed main valve 34 and the also closed auxiliary valve 14. If the device wearer exhales, an overpressure arises in the chamber 2o in front of the exhalation valve 3, which is caused by the resistances of the exhalation valve 3, the alkali cartridge 5 and the breathing lines 4 and 6 and the strength and duration of which is determined by the size and duration of the individual exhalations results. This pressure is transmitted through the line 1g and the non-return valve 118, which has only a low resistance, into the control chamber 16 of the auxiliary valve 14, which is closed off from the outside. Since the counter-pressure chamber 17 under the membrane 15 is in open connection with the breathing capacity 6 through the line 26, the membrane 15 can follow the overpressure effect and open the auxiliary valve 14 through the rod 27 Auxiliary valve is small and is only a fraction of the amount necessary to replace the consumption, flows into the chamber 30 and through the connecting line 31 into the control chamber 32 to the left of the membrane 33. Of the main valve 34 and meets in the outflow line 35 before its outlet in the oxygen line 37 leading to the breathing bag 7 to the stagnation nozzle 36. Since the chambers 30 and 3: 2 including the tubes 31 and 35 only have a capacity of a few cubic centimeters, the pressure here rises sharply in a fraction of a second and opens through its action on the membrane 33 the main valve 34, which remains open as long as the overpressure that triggers the auxiliary valve 14 is stops, ie during most of the exhalation period. Since only the approximately 4% oxygen consumption of the device wearer is to be replaced during this period, an optionally adjustable throttle opening 38 is expediently arranged in the outflow line of the main valve: 34. Instead of the Drosselöifntuig 38 can. a spring-loaded throttle valve can also be arranged.

The auxiliary valve 14 thus regulates the oxygen supply as a function on the number and size of the breaths taken by the wearer. The invention, however the control membrane 15 of the auxiliary valve 14 has another important task, namely the task of flushing out the impurity contained in the oxygen supply Sticksitoffes. By arranging the check valve 18 in the connecting line i9 between the chamber 2o des. Off: breathing valve 3 and the closed off to the outside Control chamber 16 above the diaphragm 15 ensures that .die with each diaphragm stroke Exhaled air sucked in through line i9 does not flow back into the device can. The amount of exhaled air that is sucked in depends on the size of the diaphragm stroke and thus also dependent on the strength of the individual breaths. It remains as purge air lie in the control chamber 16 until the end of exhalation or, if the Breathing with the whole of the partially empty breathing bag 7 was started by subsequent flow from the main valve 34, which has been kept open for so long, the breathing bag is filled so far is that the stiffened by a plate wall part 25 of the breathing bag 7 the push button 24 of the pressure relief valve 22 is actuated. Then the contained in the room 16 can Purge air escape to the outside.

The arrangement of an auxiliary valve. according to the invention thus enables also an inevitable nitrogen purging depending on the number and size the breaths, with the special advantage that the scavenging air of the carbonated ones arises Exhaled air and not from the cleaned contents of the breathing bag is taken.

Finally, according to the invention, no additional parts are necessary, around one that was created, for example, by operating a special Sausto: ffzuschussventils To remove excess pressure from the circuit of the device. An excess of circulating air can without difficulty from the space 20 in front of the exhalation valve 3 through the line ig, the check valve 18, the chamber 16, the line 2.1 and the pressure relief valve 22, which is then opened by the wall 25 of the breathing bag 7, blow off.

Another embodiment of the invention is shown in Fig. at this is the arrangement of the auxiliary valve: sl 14 in its relationship to the circuit of the device .the same as in the case of the embodiment according to Ab @ b. i, the auxiliary valve 14, however, blocks a counter-pressure chamber 39 which is delimited by a membrane 4o will. Between this membrane 4o and the closure body of the oxygen supply valve 41 there is a force-fit connection. In addition, there is one in the membrane 4o Throttle opening 42 arranged, which balances the pressures in the control chamber 43 and in the back pressure chamber 39 on both sides of the membrane 4o is intended to delay. the Control chamber 43 below membrane 4o is in open communication with the oxygen supply bottle i i or with the pressure reducing valve 13. From: the oxygen supply valve 41 flows the oxygen through a line 37, which with switching on a throttle opening 38 or a throttle valve into the breathing line or directly into the breathing bag 7 leads.

In the embodiment example next Fig. 2: is the effect of the membrane 15 of the auxiliary valve 14 is the same as for the oxygen protection device according to Fig. i. The oxygen escaping from: the very small opening of the auxiliary sve: ntits @ 14 however, it flows through the chamber 17 and the line 26 directly without throttling into the breathing line 6. This drops in the counter-pressure chamber, which is kept very small 39 the pressure very quickly, because .the throttle opening 42 in the membrane 4o the compensation the pressures in chambers 43 and 39 are delayed. The pressure difference on both sides of the membrane has a corresponding stroke of the membrane 40 and thus the opening of the: oxygen supply valve 41 result. As soon as the exhalation has ended, the diaphragm 15 of the auxiliary valve reverses 14, as described above for the device according to Fig. I, in its starting position back, and the spring 2'8 closes the auxiliary valve 14. In the chambers 39 and 43 The pressure equalization now takes place through the throttle opening 42 and the main valve 41 is also closed.

This type of oxygen supply, which is known per se, results in connection with the present invention, in which the auxiliary valve 14 is not just the oxygen supply controls, but also causes the nitrogen purge and the arrangement of a special overpressure vent valve superfluous, special advantages.

Is the oxygen by opening the shut-off valve 12 of the oxygen cylinder i i released the path, it meets the control chamber 43 in a very short time. Throttle opening 42 prevents an immediate pressure equalization with the back pressure chamber 39, so that the resulting pressure difference on both sides of the membrane 4o the The oxygen supply valve 41 opens. Only when the pressure equalization is established, the valve 41 is closed and then has the use position taken. It therefore inevitably flows when you open the shut-off valve 12 the oxygen bottle i i put a few liters of oxygen into the device circuit and ensure for the Breathing air already, at the beginning of the use one has a high oxygen content. So there is no need for regulations like them Even for devices with ample oxygen supply exist, after which a start of use by vacuum cleaner or by actuating a supplement valve if possible a lot of nitrogen should be cleared from the airways of the device. Through this the oxygen supply can be used even better in favor of the consumption of breath be, d. that is, that a certain supply is sufficient for a longer working time or: that. one at fixed. Service life with a small supply of oxygen come and save weight on the oxygen cylinder.

The removal of air from the air can therefore be carried out on very small quantities of about 5 per cent of the oxygen consumed in breathing; d. H. on quantities of no more than 10 cm3 per stroke of the membrane 15. There, also the auxiliary valve 14 because of its very small opening cross-section of a membrane. with very little Can be controlled, the whole can be made from an auxiliary valve and a main valve device for oxygen supply, nitrogen purge and overpressure ventilation, shown in the schematic fig. i and 2 for the purpose of clearer Damstellung is strongly pulled apart, crowded together in the smallest of spaces, like that that a simple and easy-to-use structure of the breathing apparatus would be achieved.

Claims (6)

PATENT CLAIMS: i. Oxygen respirator with breathing air circulation and lung-controlled oxygen supply through one controlled by an auxiliary valve. Oxygen supply valve, characterized in that the control chamber (16) dis The auxiliary valve (14) via a check valve (r8) with the exhalation (4) and via a second valve (22) with the A-uBi (#nluft is connected, so that the control device of the auxiliary valve (i4) also serves as a flushing membrane pump, the membrane (15) of which the exhaust air flowed into the control chamber (16) during exhalation, as soon as the breathing bag (7) comes through, the exhaled air or the influx of oxygen has been filled, under the action of a spring (2.8) via the second valve (22) as purge air presses outside. 2 :. Oxygen breathing protection device according to claim i, characterized in that the control chamber (16) of the diaphragm housing of the auxiliary valve (14) via the backlash valve (18) with the chamber (2o) of the exhalation valve (3) and via that of the stiffened wall (25) of the The pressure relief valve (22) operated by the breathing bag (7) is connected to the outside air , while the counter-pressure chamber (17) of the membrane housing of the auxiliary valve (14) is in open connection with the breathing line (6) leading from the alkaline cartridge (5) to the breathing bag (7) stands. 3. Oxygen breathing apparatus according to claim x or 2, characterized in that the auxiliary valve (14), controlled oxygen supply valve (34) is actuated by a membrane (33), after opening the auxiliary valve (14) by the pressure of the .über the, auxiliary valve (14) into the control chamber (32) of the meridian unit of the saturated substance feed valve, (34) flowing oxygen is moved into the open position (Section i). 4. Oxygen breathing apparatus according to Claim 3 ,, characterized in that the control chamber (32) of the Mernbrangehäuses. dels oxygen supply valve (34) via a stagnation nozzle (36) with the to the breathing bag (7) leading oxygen supply line (37) is connected (Dept. i). 5. Oxygen breathing apparatus according to claim i or 2, characterized in that the of, the auxiliary valve (r4) controlled oxygen supply valve (41) is actuated by a membrane (4o), which is moved into the open position after the auxiliary valve (14) is opened, da; ß from the back pressure chamber (39) of the diaphragm housing of the oxygen supply valve (4i) oxygen flows into the breathing line (6) via the auxiliary valve (14) (Dept. 2). 6. Saueratoff breathing apparatus according to claim 5, characterized in that the the oxygen supply valve (41) bebä.tenden membrane (4o) with a narrow throttle opening (42) is provided, via which a balance of the pressures in the control chamber (43) and takes place in the counter pressure chamber (39) only with a short delay (Dept.: 2).