DE644212C - Oxygen breathing apparatus with lung-controlled oxygen supply - Google Patents

Description

Oxygen breathing apparatus with lung-controlled oxygen supply The invention relates to further developments of the oxygen breathing apparatus according to patent 6o5 97o, namely the respiratory protection device according to claim 3 and the respiratory protection device according to claim z of this patent.

In the oxygen respirator according to claim 3 of the main patent his throttle or shut-off element is switched on in the breathing line, the one with the Device for supplying the oxygen is coupled. According to the invention there is the shut-off element from your control membrane that is switched into the breathing line, di2 my chamber is arranged in such a way that its central part forms the opening one protruding into this chamber and connecting the chamber to the breathing bag Pipe section closes and the rest of the annular part of the control diaphragm through the flow energy of the circulated air volume is exposed to dynamic pressure is.

This ensures that the flow energy in the breathing line The back pressure on the legs caused by the circulated air volume is relatively high Acts surface of the control membrane and, as a result, the control device for the The supply of oxygen with each exhalation is so forcefully operated that a reliable one Operation of the lung-operated control is guaranteed and the control device have a low oil ratio and can be designed in a structurally simple manner.

The control device of the oxygen supply valve coupled to the control membrane is preferably in the membrane chamber on the one facing away from the mouth of the pipe section Side of the control diaphragm arranged so that they are from the air circulated in the device is not touched and is not exposed to the humidity of the air we breathe.

In the case of the oxygen breathing apparatus according to claim a of the main patent a throttle point is arranged in the breathing line, which is used to control the oxygen supply device serving dynamic pressure generated. According to the invention, this breathing apparatus is also used a control diaphragm is used as a lung-operated control element, through which each Exhale a strong pressure on the one actuating the suction valve Control device is exercised. For this purpose, the breathing line is in direct proximity Close to the one switched on in the breathing line before it flows into the breathing bag Throttle point a Karnmer, which one with the device for supplying the oxygen contains coupled control membrane, connected such that the control membrane to the in the breathing line back pressure caused by the throttle point is exposed.

In this embodiment of the oxygen breathing apparatus it is particularly advantageous ;, two Sat: fuel supply valves to be arranged # n,: those of which gektip; "- polten Stcucrvorrichttnig with the control membrane are operated so, ' that one valve when the diaphragm flexes to one side, that the other valve is opened when the diaphragm deflects to the other side.

In the case of the oxygen breathing apparatus according to the invention, finally except for your oxygen filling valve operated by the control membrane second oxygen supply valve. be arranged by an on static Print responsive. z. B. through the wall of the breathing bag actuated device is controlled. The common arrangement of the oxygen supply valve controlled by the membrane and a static pressure responsive oxygen delivery device the advantage that with the liibetricbnaltine of the empty device the required initial oxygen supply also through one through the Lang; actuated device he follows.

Several exemplary embodiments of the invention are shown in the drawing. Figs. I to 3 show three different: @ embodiments in which in the breathing line a control membrane acting as a shut-off element is switched on. The embodiments according to Fig. i and 2 differ only in the arrangement and training of the lever linkage connected to the control membrane. At the execution form after Fig.3 is dependent on the oxygen supply valve controlled by the membrane second oxygen supply valve controlled by static pressure is arranged.

Figures 4 and 5 show two different embodiments. at them A throttle point is arranged in the breathing line, which is used to control the Oxygen supply device serving dynamic pressure generated. In the embodiment According to Fig. 5, two oxygen supply valves @ e controlled by the membrane are arranged.

In all exemplary embodiments, i is the oxygen cylinder, 2 the closing valve of the oxygen bottle, 3 the pressure reducing valve, .f the breathing bag and 5 the carbonic acid absorption cartridge. 6 and 6 "are the connecting pipes between your valve box 7 and the carbonic acid absorption cartridge 5 or the breathing bag .l. In the valve box 7, the inhalation valve S and the exhalation valve o are arranged. The mouthpiece with the valve box, ^ through the exhalation tube is designated with io i i and the inhalation tube 12 is connected. Line, -13 is used for metering of oxygen to the air circulation system of the Gcrä @ es. 15 is the lung "controlled @" Saucrst.offztiführungsc-cntil, the -Clitrch kept a spring i: 1 closed will. The lever 17, which is rotatable at 03, acts on the spindle 16 of the valve i5 is stored.

In the embodiment according to Fig. I, the saturant supply valve 15 is attached to a control membrane 3o by means of the spindle 16 1> ctätigendc liebe] 17, specifically in the middle of a reinforced part 3o "of the membrane. The membrane 3o and the lever 17 are arranged in a chamber 31 , which is connected to the carbon dioxide absorption cartridge 5 by a pipe section 32 and to the breathing bag 4 by a second pipe section 3-3 protruding into the chamber. The control membrane 30 is clamped in the chamber; i in such a way that that the mouth of the pipe section 33 is closed off by the middle part 3o "of the membrane 3o.

If the device is in operation, the flow energy acts with every exhalation the air content of the device moved by the lung activity on the control membrane 3o, so that it assumes the position shown in dashed lines. The lever 17 is around its pivot point i S in the position also shown in dashed lines rotated so that the closure body of the oxygen, offzuführungsventils 15 against the action of the spring 14 is fully lifted from its seat and oxygen through the Line 13 flows into the breathing bag 4.

Since the pipe section 33 surrounding, the dynamic pressure of the circulated air volume exposed annular surface of the control membrane 30 is relatively large, can for the The control device of the valve 15 has a low transmission ratio; n a high reliability of the control device is achieved and also of the Breathing resistance in the device `significantly reduced.

The embodiment according to Fig. 2 differs from the one according to Fig. i only by the arrangement of the control device of the oxygen supply valve 15 and its connection with the control membrane 3o. This is here in a chamber 3 r "arranged with the carbon dioxide absorpti-olis cartridge 5 through a piece of pipe 32 is connected. To connect the chamber 31 ″ to the breathing bag 4 .ein serves Pipe section 33Q, which is also with a chamber 3.I in communication, which is between the Chamber 3 r "and the breathing bag n and in which the H., - bel 17 and the rest Parts of the control device of the Valve 15 are housed. Of the Lever 17 is fixed in the middle of the reinforced part 30a of the control membrane 3o, but on the side of the control membrane facing the pipe section 33 ″. The wall the comb 31a has openings 35 through which the one located to the right of the membrane 3o Part of the chamber 3 i "is in communication with the outside air.

In the embodiment according to Fig. 2, the flow touches the circulated Air is the control device of the oxygen supply valve 15, while in the embodiment according to Fig. i the control device is not touched by the air flow and therefore the Humidity in the air that you breathe, which can lead to the formation of rust or deposits can not be exposed.

3 shows an oxygen breathing apparatus in which, in addition to the oxygen supply valve 15 controlled by the membrane 3o, a second oxygen supply valve 137 controlled by static pressure is arranged. In front of the valve 15 a line 36 is branched off, in which the valve 37 is arranged, which is controlled in a manner known per se by a device actuated through the wall of the breathing bag [. This consists essentially of a lever 38 which is mounted at 39 and which assumes the position shown in dashed lines during regular operation of the device. At the beginning of breathing, that is to say when the breathing bag is empty, the lever 38 assumes the position shown in solid lines, whereby the valve 37 is opened and the oxygen can flow into the breathing circuit. After completion of this single suction process, the spring 4o returns the lever 38 to the position shown in dashed lines and the valve 37 is closed again. Furthermore, an overpressure valve 41 is arranged in a known manner, which, when a certain filling level of the breathing bag 4 is exceeded, strikes a stop 42 and is thereby opened.

In the case of the oxygen breathing apparatus shown in FIG. ¢, a chamber 31b is connected to the breathing line 32 in the immediate vicinity of the throttle point 33b which is switched on into the breathing line 32 before it flows into the breathing bag 4. This chamber contains a control membrane 30 coupled to the control device 17 for supplying the oxygen and is connected to the breathing line 32 in such a way that the control membrane is exposed to the dynamic pressure caused by the throttle point 33U during exhalation in the breathing line. In contrast to the embodiments according to FIGS. 1 to 3, the control membrane in this embodiment is not a shut-off element switched into the breathing line, but is only actuated by the dynamic pressure b ° generated by the throttle point 33b during exhalation. The blocked breathing air flows through the throttle point 331, more slowly into the breathing bag 4 than it would flow without the arrangement of the throttle point, and pushes the membrane 3o into the position shown in dashed lines, the air to the right of the membrane escaping through the openings 35 into the open . As a result, the valve 1 5 is opened and oxygen is let into the breathing line. The effect of the dynamic pressure on the control membrane 30 is even greater here, since the entire circular area of the membrane is exposed to the dynamic pressure. With every change in the breathing air speed during exhalation, the dynamic pressure of the breathing air caused by the throttle point 33b also changes, which causes a change in the deflection of the membrane and thus the opening width of the valve and the strength of the oxygen flow.

In the oxygen breathing apparatus shown in Fig. 5, two oxygen supply valves i 5 "and 15b are arranged. The pivot point i 8 of the lever 17 lies between the two valves. Each valve spindle has an elongated hole 43 or 4.1 at its end, into which the lever 17 engages. the oxygen supply through the valve 15 'the same way, hi 331, fluctuations occurring in the pressure elt as in the embodiment of Fig. 4 by the result of the arrangement of the throttle point in the breathing conduit 32 Gereg @. The arrangement of the second lung-controlled valve i 5b ensures that oxygen can be introduced into the breathing bag 4 immediately when the device is started up. If the breathing bag is empty at the beginning of breathing, a negative pressure is created in it when breathing in. As a result, the control membrane 3o is sucked inward into the position 301 shown in dashed lines and the valve l 5U is opened. When exhaling, a dynamic pressure arises at the throttle point 33b, by means of which the control membrane 30 is pressed into the position 3o shown in dashed lines and the valve i 5a is opened. If the device is in operation, only the oxygen supply valve 15 ″ is actuated with each exhalation.

Claims (5)

PATENT CLAIMS: i. Oxygen breathing apparatus with lung-controlled Oxygen supply according to claim 3 of patent 6o5 97o, characterized in that that this is in the breathing line (32) switched on shut-off element a control membrane (30) which is arranged in a chamber (31) in such a way that with its middle part (3o,) it is the opening of a chamber (3 i) which projects into it and the chamber closes with the tube piece (g3) connecting the breathing bag (4.) and the rest of the ring-shaped part of the control membrane (3o) due to the flow energy is exposed to the dynamic pressure caused by the circulated air volume (Fig. i to 3). 2. Oxygen breathing apparatus according to claim i, characterized in that the with the control device (17) of the oxygen supply valve coupled to the control membrane (3o) (15) in the membrane chamber (31) on the one facing away from the mouth of the pipe section (33) Side of the control membrane (3o) is arranged so that it is circulated by the in the device Air is not touched (Fig. I and 3). 3. Oxygen breathing apparatus with lung-controlled Oxygen supply according to claim 2 of patent 6o5 97o, characterized in that that to the breathing line (32) in the immediate vicinity of the breathing line (32) the confluence of the same throttle point (33U) switched on in the breathing bag (.l) a chamber (3i1,) which is one with the device (17) for supplying the oxygen coupled control membrane (30) .contains, is connected in such a way that the control membrane (30) the back pressure caused in the breathing line (32) by the throttle point (33b) exposed (Fig. 4 and 5). . 4 .. Oxygen breathing apparatus according to claim 3, characterized by two oxygen supply valves (15Q, I 5b) which are actuated by the control device (17) interlocked with the control membrane (30) so that the one valve (15Q) when the membrane is bent ( 3o) to one side, the other valve (15b) is opened when the membrane (30) is bent to the other side (Fig. 5). 5. Oxygen breathing apparatus according to one of claims i to 3, characterized characterized in that in addition to the oxygen supply valve actuated by the control membrane (30) (15) a second oxygen supply valve (37) is arranged, which is through a static pressure responsive e.g. B. through the wall of the breathing bag (: f) actuated device is controlled (Fig.3).