DE1008140B - Method and device for supplying air to a free diver by means of a compressed air breathing apparatus - Google Patents

Description

Method and apparatus for supplying air to a free diver by means of a compressed air breathing apparatus It is known to provide a free diver with nutrient gas to supply, which is stored in a container under high pressure and over a line, provided with control valves, is fed to the diver. One can Divide devices of this type into two classes. One class of equipment is used as a nutrient gas pure oxygen, the other air or z. B. a. Mixture of oxygen and helium. The oxygen devices are between the supply bottle and the mouthpiece of the diver preferably a water and lung pressure controlled inlet valve is provided which supplies the oxygen to the mouthpiece via a storage container. For devices this Art is therefore inhaled pure oxygen. Since the exhaled oxygen is that of contains carbon dioxide released into the lungs, the amount of gas exhaled must exceed a chemical cleaning chamber for the purpose of absorbing the carbon dioxide.

Devices of this type have the disadvantage that you are in water depths Do not stay above about 20 m, because the pure oxygen on the human Organism acts as a poison at a total pressure of more than 3 ata. Another disadvantage the oxygen diving equipment consists in the fact that in the case of contamination in the circles between The amount of gas carried in the cleaning chamber and lungs caused severe symptoms of poisoning by CO gas can occur without the user of the device by increased breathing can depress carbonic acid levels in the blood that are too high.

The diving devices working with compressed air avoid these previously described Disadvantages, because here the lungs are always flushed with fresh air and the air itself is non-toxic at great depths. But while the oxygen equipment is a relative can book small compressed gas cylinders for themselves as an advantage, have those with compressed Air working devices have the disadvantage that several compressed air storage bottles are arranged here Need to become; if you swap at a greater depth or under water for a long time want to stay. The reason for this is that the oxygen utilization of the Air is low. Of the 21% of the oxygen content supplied at normal pressure It is well known that only a few percent of the air is used up in one breath. In at great depth, however, the utilization rate for air oxygen per breath is practical even less, for it becomes with a certain effort of the human Body requires a constant amount of oxygen per breath, and the volume content one breath is also roughly constant. The mass of air, which however consumed in one breath under the aforementioned conditions is proportional the absolute pressure, e.g. B. in 50 m water depth 6 times larger than at the water surface.

For the practical use of the compressed air devices, besides the Unhandy of the devices caused by the large compressed air bottles (large Flow resistance), nor the difficulty in putting the bottles in place having to refill a new dive attempt.

The invention avoids the disadvantages described above by the following Procedure is adopted: When supplying air to a free diver by means of a compressed air breathing apparatus, with a breathing gas supply bottle and a lung and water pressure controlled inhalation valve is according to the invention in one and the same Suit first breathed in air released into the water while exhaling the last portion of air inhaled is exhaled into a savings container during exhalation and is used again as the first inhalation air for the next breath, the diver preferably in order to avoid a too low oxygen content of the total amount of air inhaled in this way constantly and independently of the lung and an additional amount of breathing gas is supplied to the water pressure-controlled inhalation valve, which is at most as large as the amount of air escaping into the water. .

While with the devices working with oxygen the related one Oxygen gas makes a perfect circle purchase; d. H.; it becomes lax at all oxygen Exhaled into the water is carried out according to the method proposed here during a One breath only creates a cycle for the last portion of air inhaled. The method now has the advantage that the first inhaled is strong with CO. Gas permeated air of a breath, as was previously the case with compressed air devices, into Water is given off while the last part of air breathed in considering his only a very small amount of carbon dioxide for another breath use Can be found. Carrying out this process is possible because of the oxygen content the last inhaled or first exhaled air practically hardly compared to has been reduced from its original state.

A further improvement of the method is that the Air exhaled in the savings container in known white from her to and for itself low C 02 content is chemically cleaned. Complete operational safety the new method is ensured by the fact that besides the lungere and water pressure controlled Inhalation valve according to a preferably adjustable, also by the water pressure controlled breathing gas nozzle of the inhalation line supplies a part of breathing gas that is so large is measured so that it corresponds to the diver's need for breathing in the case of immobility Diving depth covers.

One suitable for carrying out the method described above Device consists of a breathing gas storage bottle, a long and water pressure controlled Inhalation valve, on the one hand via a low pressure line and a reducing valve communicates with the storage bottle and on the other hand with a mouthpiece is connected for inhalation, being between the inhalation valve and the mouthpiece a deformable container by the water pressure or the pressure of the breathing air is arranged is, while the used air through a spring-loaded exhalation valve in the Water is expelled, according to the invention in that the deformable container in inflated state has a smaller volume than the lung volume and that the inflated state of the container is reached at a pressure which is at most as high as the pressure required to open the exhalation valve.

The invention is illustrated in the drawings. It shows Fig. 1 a diving device with lung and water pressure controlled inhalation valve and deformable Saving container, Fig. 2 shows a diving device in which the deformable saving container and the inhalation valve form a structural unit, FIG. 3 shows a diving device according to FIG. 1, at which, however, has a chemical cleaning chamber in the supply line to the economy container is switched on, Fig. 4 shows a diving device with valves on the mouthpiece, economy container and chemical cleaning chamber, FIG. 5, however, form a diving device as in FIG. 4 Inlet valve and chemical cleaning chamber one unit.

The compressed air bottle 1 with closure 2 and the reducing valve 3 is through the low pressure line 4 to the housing 5 of the lung and water pressure controlled Inhalation valve connected, its membrane 6 with the inlet valve 7 and the openings 8 for the passage of water, the supply line 9 and the mouthpiece 11 with breathing gas supply in a known manner; and 10 and 10a is a water pressure and lung pressure, respectively deformable savings container in the supply line 9 in inflated and not inflated state. The exhalation line 12 connects the mouthpiece 11 with the Exhalation valve 13.

The working process is (see. Fig. 1) as follows: After opening the lock 2 penetrates through the reducing valve 3 up to the inlet valve 7 compressed air. Through the line 9, the lung pressure is established above the membrane 6 and below it the membrane 6 the water pressure. If both pressures are the same, so is the valve? closed. When inhaling, a negative pressure is created above the membrane, so that the valve 7 is opened by the water through the membrane 6 and compressed air into the Line 9 flows in. It is assumed that at this moment the savings container according to the invention would have assumed its smallest volume, as indicated by 10a is shown. The valve 13 is by a slight spring force against the exhalation line 12 pressed so that when exhaling the inhaled air through the mouthpiece 11 only the spring force including water pressure has to be overcome until the valve is open 13 opens. If you now exhale, then before the valve 13 opens, only the deformable container 10, which is only under the water pressure, with the exhaled air. It is assumed here according to the invention that this When inflated, the container has a smaller volume than the lung volume. After filling the tank 10, the pressure in the line increases when you exhale 9 and 12, so that now the valve 13 opens and the remaining air into the water is exhaled. The arrows drawn (solid) show the path that the inhaled air takes the dashed arrows the path that the exhaled air takes. During the next breath, valve 7 initially remains closed, and the savings container is emptied into the lungs via the line 9 and the mouthpiece 11. Subsequently, further suction of air through the lungs creates a negative pressure above the membranes 6 and, as described above, the water pressure opens the inlet valve, so that breathing gas directly from the storage bottle via line 9 and mouthpiece 11 is supplied to the lungs. Fig. 2 shows according to the invention a combination of Saving container with the boy and water pressure controlled inhalation valve. 14 is that Housing for the common arrangement, the housing part 15 allows the water Access to the bag-like diaphragm 16 shown. In this arrangement, the Inhaling the savings container also to its smallest volume due to the water pressure pressed together and the inhalation valve 7 opened, which then to completion of the breath n (± releases necessary breathing gas into the inhalation line 9 '.

In Fig. 3 is according to the invention in the line 9 ″ between savings container 10 and mouthpiece 11 a chemical cleaning chamber 18 switched on and the housing of the inhalation valve 5 is connected to the mouthpiece 11 by a supply line 17. The air exhaled into the economy container is in this version with the passage freed of carbon dioxide content through the chemical cleaning chamber. Furthermore the operation of the device takes place according to the description for FIG. 1.

Fig. 4: In the inhalation line 9 "'and the exhalation line 12' the valves 19 and 20 are arranged next to the mouthpiece 11. When you exhale opens the valve 20 and according to the invention brings the exhaled air over the Feed line 23 and the chemical cleaning chamber 18 into the economy container 10. When inhaling, the valve 20 closes, and via the valve 19 and the line 9 ″ 'the economy container 10 is emptied or the one discharged from the inhalation valve 7 Breathing gas is supplied to the mouthpiece 11.

Fig. 5 shows a diving device in which also in the vicinity of the Mouthpiece is a valve 19 in the inhalation line and in the exhalation line a valve 20 are located. According to the invention, the water and lung pressure controlled in the housing 21 Inlet valve 7 and the cleaning chamber 18 housed. Here is the operation the following: During exhalation, the air portion exhaled first is exhaled via valve 20 guided into the cleaning chamber 18 and passes from this into the supply line 9 and from here into the savings container 10. If the latter has been filled, the increases Pressure in the exhalation line 12 "on, and the exhalation valve 13 'opens, from which the air exhaled in the end escapes. Closes on inhalation the valve 20, and the air from the savings container 10 passes to the mouthpiece the supply line 9 and the valve 19. If the economy container is empty, so the remaining breathing gas required for the breath is now from the inlet valve 7, which is actuated by the water pressure from the membrane 6.

According to the invention, a nozzle 22 has an adjustment facility 24. While the inhalation valve 7 only works when a negative pressure is created by inhalation in the part of the housing 21 located above the membrane 6 occurs through the nozzle 22 is constantly flowing out of the breathing gas. The amount of breathing gas escaping can be regulated by the adjustment device 24. There is also the possibility of to control the nozzle gas in its amount directly by the water pressure.

The meaning of the per se known nozzle 22 according to the invention is the following: It is the user of the diving device with the appropriate setting of Nozzle constantly supplied as much breathing gas from the supply bottle as he z. B. at Requires immobility at a suitable diving depth, d. H. so a minimum amount of gas, if necessary in the event of a disaster (fainting of the diver, failure of the inhalation valve etc.) supplies the diver with sufficient nutrient gas. This enables when not in use the breathing gas exiting through the nozzle, due to the rising bubbles that Establishing the location of the diver.

The difficulty of correctly sizing the deformable economy container 10 compared to the different deep breaths of the diver is countered by that breathing gas constantly flows out of the nozzle 22 in relatively small quantities. Suddenly breathes the diver is very shallow, so that the reservoir is no longer emptied when inhaling and the inhalation valve 7 no longer supplies breathing gas, the breathing gas is limited from the nozzle 22 the maximum saving factor - this is the ratio of the inhaled Amount of air to the amount of gas delivered from the compressed air cylinder 1 in the same period of time -and the lowest permissible oxygen content of the inhaled air.

Falling below the minimum, endangering the life of the diver This avoids the required oxygen content. One way of According to the invention, the size of the savings container can be changed in a purely mechanical manner Ways to be made. Is the savings container as a rubber bag. trained so can for example, through an adjustable net, the maximum size of the container when inflated State to be limited.

The arrangement of the cleaning chamber according to FIGS. 3, 4 and 5 has the advantage that neither the air exhaled into the water nor the air flowing out of the inlet valve 7 Air flow through the cleaning chamber. This can reduce the flow resistances be kept low. The arrangement of the cleaning chamber according to FIGS. 4 and 5 has furthermore the advantage that the air to be cleaned only enters the cleaning chamber during exhalation flows through.

The examples shown in FIGS. 1 to 5 are by no means represent all possible combinations, which in the arrangement of the above Device parts can be applied and with which the invention can be implemented can. On the contrary, manifold changes are still possible without the principle of Invention to leave.

Claims (3)

PATENT CLAIMS: 1. Method for supplying air to a free Diver by means of a compressed air breathing apparatus, with a breathing gas supply bottle and a lung and water pressure controlled inhalation valve, characterized in that that the proportion of air inhaled first in one and the same breath during exhalation is released into the water, while the last part of the air inhaled is released during exhalation is exhaled into a savings container and with the next breath as the first inhalation air is used again, the diver preferably to avoid a too low oxygen content of the total amount of air inhaled in this way constantly and independent of the lung and water pressure controlled single valve an additional The amount of breathing gas supplied is at most as large as that which escapes into the water Air volume is. 2. The method according to claim 1, characterized in that the in the air exhaled in the economy container chemically cleaned of CO2 in a manner known per se will. 3. Apparatus for performing the method according to claim 1, consisting from a breathing gas storage bottle and a lung and water pressure controlled inhalation valve, on the one hand via a low pressure line and a reducing valve with the storage bottle and on the other hand connected to .einem mouthpiece for inhalation is, with a through the water pressure between the inhalation valve and the mouthpiece or the pressure of the breathing air deformable container is arranged while the consumed Air is expelled through a spring-loaded exhalation valve into the water, thereby characterized in that the deformable container (10) is a smaller one in the inflated state Volume than the lung volume and that the inflated state of the container (10) is reached at a pressure which is at most as great as that to open the Exhalation valve is necessary pressure. 4. Apparatus according to claim 3, characterized in that the deformable container (10) preferably directly is arranged next to the inhalation valve (7). 5. Apparatus according to claim 3 and 4, characterized in that the deformable container with the inhalation valve (7) forms a structural unit and the container wall functions as the lung and water pressure control of the inhalation valve takes over. 6. Apparatus according to claim 3 to 5, characterized in that that the air exhaled in the deformable container (10) via a chemical cleaning chamber (18) while the breathing gas that is passed from the inhalation valve to the mouthpiece and the stale air exhaled into the water does not flow through the cleaning chamber. 7. Apparatus according to claim 3 to 5, characterized in that the exhaled Air through the exhalation tube (12) past the closed exhalation valve (13) passed via a chemical cleaning chamber (18) to the deformable economy container (10) is, with two control valves (19, 20) in the mouthpiece the inhalation or. Exhalation path close and open accordingly. B. Device according to claim 3 and 4, characterized in that that the chemical cleaning chamber (18) with the inhalation valve (7) in one and the same Housing is disorganized. 9. Device according to arrangement 3, 4 and 6 to 8, characterized in that that the receiving volume of the savings container (10) influenced by the shape of the container Means, e.g. B. an enveloping network of variable size, to different values is adjustable. 10. Apparatus according to claim 3 to 9, characterized in that that a known per se, connected to the low pressure line Atemgas.düse (22), provided independently of the inhalation valve (7) controlled by the lungs and water pressure is. 11. The device according to claim 10, characterized in that the nozzle (22) can be adjusted to the specific needs of the device user, preferably a desired change in the delivery rate of the nozzle with the water pressure an automatic water pressure control takes place. Considered publications: French patent specification No. 942 351.