DE2837278A1 - Respirable gas supply - by automatically controlled pure oxygen admission to pure nitrogen - Google Patents

Abstract

Respirable gas with a variable oxygen concn. esp. for the cockpits of fighter planes, is supplied by mixing pure oxygen and pure nitrogen in the proportions required. The two gases are evaporated separately from the liquid phase and mixed in their vapour state. This saves having to instal special purification apparatus for air extracted from the gas turbine compressors. It adjusts the gas composition depending on the varying flight altitude.

Description

Method for providing breathing gas

with variable oxygen concentration The invention relates to a Method for providing breathing gas with variable oxygen concentration.

The problem of providing such a breathing gas occurs approximately in the supply of aircraft crews. So must especially with fighter jets Precautions are taken to adapt to rapidly changing flight altitudes. Of the The cabin pressure prevailing in the cockpit of such a combat aircraft changes with the altitude, in such a way that the rabin pressure with the altitude in drops less than the external pressure. Because the pressure inside the lungs of a Pilots must roughly correspond to the respective cabin pressure, depending on the flight altitude uses different amounts of breathing gas. Since the supply of a certain absolute The amount of oxygen that is physiologically necessary must be the oxygen concentration of breathing gas increase with altitude.

So far, various methods for providing breathing gas have been used proposed in aircraft cabins. What these processes have in common is that pure oxygen mixed to varying degrees with cabin air and, for example, the pilot is supplied as breathing gas. Thereby the oxygen in pure Form carried either in a liquid or in a compressed gaseous state or released chemically from oxygen-rich compounds. Farther it was proposed to produce pure oxygen from air by adsorptive means, which comes from the engine compressor.

All of these methods are disadvantageous in that that of the engine compressor The air supplied, from which the cabin air also originates, can be heavily contaminated can.

These contaminants can be a difficult problem to solve because a large number of the most varied compounds are mostly organic in nature are taken into account.

There are therefore only the alternatives, in terms of apparatus and control technology Very complex cleaning measures to take or almost pure oxygen to breathe. The last alternative requires a less technical one Effort, but should not be used for medical reasons.

The invention is therefore based on the object of a method of provide the type mentioned at the beginning, which allows it to be as economical as possible Way to generate a breathing gas that meets the changing demands on the oxygen concentration as flexible as possible is sufficient and at the same time the physiologically required purity without the need for technically particularly complex cleaning measures are.

This object is achieved according to the invention in that pure Oxygen and pure nitrogen in the to achieve the respective oxygen concentration required proportions are mixed.

The invention is thus based on the present context not applied and at the same time surprisingly simple idea of breathing gas to be mixed in a controllable manner from the components which are initially present separately.

In contrast, the path has so far been followed without exception been to provide only one of the components, namely the oxygen, separately in pure form and to combine this with a mixture of components. This has the obvious Advantage that only the oxygen has to be made available in pure form. The known procedure must therefore appear to be inexpensive and obvious, because air was already immediately available as part of the component mixture.

Even if the provision of pure nitrogen is an additional first As a cost factor, this is more than made up for by the fact that no Cleaning measures are more required. The equipment required for the mixing device, which must make it possible to combine the shares in a controllable manner, exceeds not the effort required with previously used devices.

Even when adding pure oxygen to cabin air, a controllable mixing device must necessarily be present, regardless of whether the oxygen carried along in pure form or by chemical or adsorptive means is won. Even the ideas to be solved when carrying out the invention Control problems do not go beyond the known methods and devices occurring and already solved problems. The invention thus makes it possible in a very simple way to provide a breathing gas that is required at any time Composition, with the risk that has never been completely eliminated so far that the sudden occurrence of particularly high concentrations is completely eliminated of contamination can no longer be dealt with by the apparatus.

The invention is particularly good for use in aircraft, particularly suitable for combat aircraft. The method for providing breathing gas for people in aircraft, depending on the flight altitude Oxygen concentration is therefore reduced indicates that pure oxygen and pure nitrogen in proportions depending on the flight altitude be mixed.

The decisive influencing factor in regulating the mixing process is therefore the flight altitude or that which is firmly related to it Cabin pressure.

As particular embodiments of the invention are, for example The following possibilities are provided: There will be liquid pure oxygen and liquid pure nitrogen evaporated separately and in vapor form in the required proportions mixed. This embodiment is particularly advantageous when for the Breathing gas supply device is only a small space available. In this case the pure oxygen and the pure nitrogen are each in separate liquefied gas containers carried along. The procedure can be that the required proportions in liquid Form withdrawn from the containers, evaporated separately and then in a regulated manner be mixed.

There is also the possibility of pure oxygen and liquid to mix liquid pure nitrogen in the required proportions and the resulting liquid mixture to completely evaporate. From the separate liquefied gas containers can, for example, in a time-adjustable sequence and / or in controllable quantities corresponding partial volumes are deducted and combined with one another. By Evaporation of the mixed liquid partial volumes then results in a breathing gas of the desired type Composition. Suitable metering devices can be used to withdraw the liquid partial volumes be used.

Finally, it is provided that compressed gaseous purer Oxygen and compressed gaseous pure nitrogen are partially expanded separately and mixed in the required ratio. This particular case takes place then Use, when it is not important, the breathing gas supply device as small as possible To accommodate space. Then the pure Oxygen and pure nitrogen can also be carried in pressurized gas containers. This has the main advantage that there are no cold insulation measures and no evaporation devices required are.

A breathing gas supply device used to carry out the method according to the invention can in particular be designed so that for the oxygen and nitrogen a liquid gas container is provided, one of the two containers at least partially arranged within the other and the outer container as well as optionally the part of the inner container protruding from the outer container opposite are thermally insulated from the environment. This particular embodiment has opposite a device having two spatially separated liquid gas containers has the advantage of that the thermal insulation of the container from the outside temperature is used Measures can be reduced to a minimum.

With regard to the pressure differences to be absorbed by the container walls it is particularly favorable if the nitrogen tank is inside the oxygen tank is arranged. Since that is intended for the inside of the outer container Partition, i.e. no special thermal for the outer wall of the inner container If insulation measures are provided, the two liquefied gases are always in good condition thermal contact. In thermal equilibrium, it forms above the liquid Nitrogen exerts a higher pressure than above liquid oxygen. Is the liquid nitrogen container now arranged inside, none of the container walls have to be between the ambient pressure and record the pressure difference prevailing under the nitrogen pressure, as is the case would be if the oxygen tank is arranged inside the nitrogen tank.

A particularly favorable geometric arrangement is given by that the outer container is spherical and the inner one is cylindrical. The spherical shape is known to be the geometrical one that is most stable to the action of pressure Shape. The cylindrical shape of the inner container must also be in terms of pressure stability can still be considered cheap. The optimal form of construction against the effects of pressure occurs when both containers are spherical. This way of construction makes it necessary, however, that the inner container with the help of special support devices is stabilized within the outer container. In this context it can be sufficient that the support devices are supported by the Formed vapor space of the inner container leading to the outside supply and discharge pipes will.

In the figure is a particular embodiment of the invention Procedure shown in a schematic manner. At the same time there is a possible one Form of construction of a device for carrying out the method according to the invention indicated.

Accordingly, there is a spherical container 8 and one arranged in it cylindrical container 7 is provided for receiving the liquid oxygen respectively.

of liquid nitrogen. Both containers are of a common, thermally insulating sheath 6, the thermally insulating effect for example through a space filled with super insulation and / or evacuated can be achieved.

To fill the container 7 and 8, with the valves 5 and 4 as well as 14 and 13 and with closed valves 18 and 19 via lines 1 and 2 a liquid oxygen or nitrogen stream is introduced. The containers are thus filled from below, and as soon as the filling process is completed, will be the valves 4, 5, 13 and 14 closed. To maintain the desired pressures within the container, which can be, for example, approx.

5 bar in the oxygen tank and at approx. 14 bar in the nitrogen tank pressure control valves 18 and 19 and pressure build-up evaporators 20 are used and 21. If the pressure in one or both of the containers falls below the desired level If the value decreases, the valves 18 and 19 open, so that liquid is under the influence of gravity reaches the pressure build-up evaporator (s) 20 and 21. These take from the area Heat up, and the evaporation process that starts leads over the opened Valves 18 and 19 and via lines 16 and 11 or 17 and 12 to a pressure increase also in the containers. When the desired pressure values are exceeded, the Pressure regulating valves 18 and 19.

In continuous operation, liquid oxygen and liquid nitrogen get through Via lines 9 and 23 or 10 and 22 in heat exchangers 25 and 24, which for the purpose the evaporation of the liquefied gases absorb heat from the environment. In a pressure control device 26 the pressure of the vaporized nitrogen is reduced to the desired breathing gas pressure. Both vapor components are regulated in a mixing device 27 Way merged, so that a breathing gas of the desired oxygen concentration results. The regulation takes place automatically taking into account the desired Breathing gas pressure, which corresponds to the cabin pressure in aircraft. The mix of Both components are carried out in such a way that with a stream of oxygen a corresponding one Amount of nitrogen is sucked in and mixed with the oxygen. This ensures that the breathing gas always has the required oxygen concentration. There for Uptake of nitrogen, an oxygen flow must always be present in particular, the possibility of ever pure or excessively concentrated nitrogen is excluded leaves the mixing device. The breathing gas obtained in this way can finally be used in a breathing mask 28 are fed.

Any excess pressures occurring in the liquefied gas containers 7 or 8 will be degraded by opening the valves 13 and 14 via an outlet line 15.

In principle, the invention is not intended for use in aircraft limited. This applies both to the particular one described above and to one of them different designs. Rather, the invention can be used anywhere where a breathing gas in the required composition is not immediately available and where in particular changing concentrations of the nitrogen components and oxygen are required. Particular areas of application are certain medical ones Experiments, working in protective gas atmospheres, in mine shafts or in great depths of the sea. If necessary, the corresponding breathing gas supply device is to be made compact and portable.

Claims (1)

Claims 1. A method for providing breathing gas with variable Oxygen concentration, characterized in that pure oxygen and pure Nitrogen in the amounts required to achieve the respective oxygen concentration Proportions are mixed. 2. Method for providing breathing gas for use in aircraft stopping persons, with the oxygen concentration dependent on the flight altitude, thereby characterized by having pure oxygen and pure nitrogen in from altitude dependent proportions are mixed. 3. The method according to any one of claims 1 and 2, characterized in that that liquid pure oxygen and liquid pure nitrogen evaporate separately and mixed in vapor form in the required proportions. 4. The method according to any one of claims 1 and 2, characterized in that that compressed gaseous pure oxygen and compressed gaseous pure oxygen Nitrogen are partially expanded separately and mixed in the required ratio 5, Device for carrying out the method according to one of Claims 1 to 3, characterized in that characterized in that one liquid gas container each for the oxygen and nitrogen is provided, with one of the two containers at least partially within the the other and the outer container and optionally the one from the outer Container protruding part of the inner container with respect to the environment thermally are isolated. 5. Apparatus according to claim 5, characterized in that the nitrogen container is arranged within the oxygen tank. 7. Device according to one of claims 5 or 6, characterized in that that the outer container is spherical and the inner one is cylindrical. 8. Device according to one of claims 5 and 6, characterized in that that both containers are spherical in shape. 9. The method according to any one of claims 1 and 2, characterized in that that liquid pure oxygen and liquid pure nitrogen in the needed Fractions are mixed and the resulting liquid mixture is completely evaporated will.