DE612256C - Control activated by the lungs for an oxygen supply valve of breathing apparatus - Google Patents

Description

Lung operated control for an oxygen delivery valve of breathing apparatus The invention relates to a lung operated controller for an oxygen supply valve of breathing apparatus, which from one into the exhalation line switched on, non-positive with the closure body of the oxygen supply valve connected shut-off member exists. This training of the control for the oxygen supply valve The purpose of this is to reduce the nitrogen hazard that exists with other types of lung-operated controls, d. H. the accumulation of the im The amount of air present in the device with nitrogen, which is in the coming to be used Oxygen, especially in what is known as industrial oxygen, is contained thereby to eliminate that the oxygen supply does not depend on the input and exhalation changing the amount of air in the device, but by the flow energy the air moved by the lungs in the device. Compared to a well-known Control of this type, in which the shut-off element switched on in the exhalation line on one with the closure body of the oxygen supply valve, non-positive connected control lever is seated, the essential features of the subject matter exist in that the shut-off member switched into the exhalation line consists of a piston exists, the end face of which blocks the exhalation line in the closed position and the lateral surface of the outlet openings for the exhaled air only after releases a certain stroke of the piston. This is done with simple means achieves that the shut-off element switched on in the breathing line causes one to breathe travels such a long distance that the oxygen supply valve with certainty opens with every breath. The control according to the invention also offers the advantage that no long control lever is required to control the shut-off element is, and thus it cannot happen that the oxygen supply vehicle as a result the pendulum movements of a long control lever when the device is shaken opened unintentionally.

A particularly useful embodiment of the subject matter of the invention arises when the piston-shaped shut-off member in one with an inlet port and a cylindrical housing provided with an outlet for the exhaled air in which the oxygen supply valve controlled by the piston-shaped shut-off element, the pressure reducing valve and the oxygen supply valve to be actuated by means of a push button are arranged. According to the invention, the cylindrical housing can consist of two consist of parts connected by a cap nut; in the one part that the Inlet port and the outlet port for the exhaled air contains, is piston-shaped Shut-off member arranged, and in the other part is the pressure reducing valve, the Oxygen supply valve and the lung-controlled oxygen supply valve arranged, the axes of which are all parallel to the axis of the cylindrical housing. That Designed in this way housing can be easily disassembled, so that individual parts of the device, especially the breathing valves, can be easily cleaned can.

So that the carrier is provided with a control according to the invention Device is warned if there is no pressure in the medium pressure chamber of the pressure reducing valve or, there is insufficient pressure, so if z. B. the oxygen supply is exhausted is or the shut-off valve of the oxygen storage tank is closed, is according to the further invention of the spring plate of the loading spring of the pressure reducing valve inevitably connected to a locking lever that switched the into the exhalation line piston-shaped shut-off member holds in the closed position, if not sufficient Pressure is present.

In the drawing is a Ausführungsbei, game of the subject invention shown. Fig. I shows a longitudinal section through the control housing; Fig. 2 3 and 3 show the housing halves in an internal view, and FIGS. 4 and 5 show the arrangement of the control housing in the breathing apparatus. This is the cycle of breathing air indicated by arrows.

As can be seen from FIG. 1, the lung-operated control for the oxygen supply valve is arranged in a cylindrical housing which consists of two parts 4, 5 held together by the union nut 34. The part 4 of the housing provided with the oxygen supply nozzle i contains the pressure reducing valve 6 formed in a known manner, the oxygen supply valve 23 formed as a push button valve and the lung-controlled oxygen supply valve 7. These valves are arranged in the housing part 4 in such a way that their axes are parallel to the axis of the cylindrical housing get lost. The supply of oxygen to the nozzle 3 of the pressure reducing valve 6 takes place through the channel 35, which branches off from the channel 36 connecting the feed connector i of the housing to the pressure gauge connection 2. The channel 38 , through which oxygen is fed to the nozzle 27 of the oxygen supply valve 23, also branches off from this channel. The medium pressure chamber 8 of the pressure reducing valve 6 is connected to the nozzle 22 of the lung-controlled oxygen supply valve 7 through the channel 37. The housing part 4 is closed off after the other housing part 5 by a sealing plate 13.

Der.- Housing part 5 is with the inlet port 28 and the outlet port 42 provided for the exhaled air and contains the with the closure body ig of the lung-controlled Oxygen supply valve 7 non-positively connected shut-off member. This shut-off member consists according to the invention of a piston 16, which in an enlarged part g the exhalation line 41: is guided. This extended part g of the exhalation line 41 is provided with side air outlet openings 14, which are at some distance are arranged behind the piston 16 located in the closed position, and is closed off from the housing part 4 by the sealing plate 13. The housing part It is also connected to the inlet connection 29 and the outlet connection connected to the connection 29 3o provided for the inhalation air.

The arrangement of the control housing in the breathing apparatus is shown in Figs. 4 and 5. The oxygen supply nozzle i connects the control housing to the shut-off valve of the oxygen bottle f: the nozzle 28 provides the connection to the exhalation tube c, and the inhalation tube b is connected to the housing by means of the connector 3o. The connector a is used to connect the breathing tubes b, c to the mask. The breathing bag e is connected to the connecting piece 2, 9 connected to the connecting piece 30 , and the breathing cartridge d is connected to the exhalation connecting piece 42 and is connected to the breathing bag e at its other end. The connector 40 (Fig. 4) is used to feed the oxygen into the breathing bag e.

The air circulation in the device is shown in Figs. 4 and 5 by arrows. When you exhale, the exhaled air passes through the exhalation tube c into the exhalation line 4i located in the control housing. Due to the pressure of the exhaled air, the piston 16 is displaced until it clears the lateral outlet openings 14 for the exhaled air. This flows through the openings 14 into the exhalation nozzle 42 and from here into the breathing cartridge d; here the breathing air is cleaned and then fed to the breathing bag e. The movement of the piston 16 caused by the pressure of the exhaled air is transmitted by means of the shaft 15 penetrating the sealing plate 13 to the lever 17 and from there to the lever 2o carrying the closure body ig of the oxygen supply valve 7. As a result, this lever is rotated against the action of the closing spring 2.1; that the closure body i9 lifts from its seat. Oxygen thus flows out of the nozzle 22 of the oxygen supply valve 7 and into the breathing bag e through the connecting piece 4o. When the pressure of the exhaled air in the exhalation line 41 drops, the piston 16 is moved back into the closed position by the closing spring 2i, and the nozzle 2z of the oxygen supply valve 7 is shut off. The supply of oxygen into the breathing bag e therefore only takes place with each expiration. When inhaling, breathing air passes out of the breathing bag e through the connecting piece 29 and the connecting piece 30 connected to this connecting piece into the inhalation tube b and from here to the mask. Between the connecting pieces 29 and 3o there is the poppet valve 3 i, which closes when you exhale.

According to the further invention, a locking lever is now in the control housing 12 mounted, which engages under the lever 17 of the oxygen supply valve 7. Of the Locking lever i2 is with the spring plate io of the loading spring i i of the pressure reducing valve 6 inevitably connected and holds the lever 17 of the oxygen supply valve 7 and thus the piston-shaped shut-off member 16 in the closed position when in the medium pressure chamber 8 of the pressure reducing valve 6 no pressure or insufficient pressure prevails. So is z. B. the shut-off valve at the beginning of the use of the breathing apparatus When the oxygen bottle f is closed, the device wearer cannot and will not breathe this causes the shut-off valve of the oxygen cylinder to open. One use of the device with the oxygen bottle shut off is therefore not possible. on the other hand the device wearer is informed immediately by the increasing breathing resistance, if the pressure in the medium pressure chamber of the pressure reducing valve when using the device decreases when there is no longer enough oxygen available.

Claims (4)

PATENT CLAIMS: i. Lung operated control for an oxygen delivery valve of breathing apparatus, consisting of a shut-off element connected to the exhalation line, which is positively connected to the closure body of the oxygen supply valve is, characterized in that the shut-off member switched into the exhalation line (4i) consists of a piston (i6) whose end face in the closed position the exhalation line (4i) shut off and its lateral surface lateral outlet openings (i4) for the Releases exhaled air only after a certain stroke of the piston (i6). 2. Control according to claim i, characterized in that the piston-shaped shut-off member (i6) in one with an inlet port (28) and an outlet port (42) for the exhaled air provided cylindrical housing (4, 5) is arranged in which the piston-shaped Shut-off element (i6) controlled oxygen supply valve (7), the pressure reducing valve (6) and the oxygen supply valve (23) to be operated by means of a push button are arranged. 3. Control according to claim 2, characterized in that the cylindrical Housing (4, 5) consists of two parts connected by a union nut (34); in the one part (5), the inlet connection (28) and the outlet connection (42) for contains the exhaled air, the piston-shaped shut-off member (i6) is arranged, and in the other part (4) is the pressure reducing valve (6), the oxygen supply valve (23) and the lung-controlled oxygen supply valve (7) are arranged, their axes all run parallel to the axis of the cylindrical housing (4, 5). 4. Control according to one of claims i to 3, characterized in that the spring plate (io) the loading spring (T i) of the pressure reducing valve (6) with a locking lever (i2) is connected, the piston-shaped shut-off member switched into the exhalation line (4i) (i6) holds in the closed position when in the medium pressure chamber (8) of the pressure reducing valve (6) there is no pressure or insufficient pressure.