DE253494C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

As is known, Mallet did a long time ago proposed from atmospheric air by repeated absorption in a suitable Liquid to gradually produce a gas that is more and more oxygen-rich the eighth absorption would receive nearly pure oxygen. The various attempts Applying this method either resulted in very expensive machines with little Efficiency or simple equipment indicated such a low yield oxygen-rich air that the application in technology seemed futile.

The present invention relates to a device which is also built on the fact is that different fluids make the oxygen of the atmospheric air in stronger Absorb measure than nitrogen. In the following, only water will be used as absorption liquid can be mentioned, but any other suitable liquid can of course also be used. In the The main thing is the device that depending on the desired degree of purity of the generated oxygen-air mixture a number of absorption chambers filled with water at the same time first pressurized and then sucked off at the same time. Shortly before the highest pressure is reached, the more nitrogen-rich, unabsorbed one blows Gas from the air collection spaces above the water by appropriately contaminated Valves off. The absorption chambers are connected to one another in such a way that they are pressed through Air must take its way through the water space of each chamber. The latter takes place in strokes in that fresh air from the atmosphere on each suction stroke of the piston sucked in through a valve and pushed away more oxygen-rich air through a valve located at the end of the last chamber will. In this way, a progressive one follows each piston stroke Movement of the amount of air from the first chamber to the last and accordingly by forcibly expelling the nitrogen-rich mixture during the high pressure period a progressive oxygen enrichment of the mixture from chamber to chamber.

The accompanying drawing shows an embodiment of such a device, namely in FIG. 1 a vertical section and in FIG. 2 a cross section through the absorption chambers along the line AB of FIG.

The standing air compressor α with the suction valve b and the pressure valve c contains in its closed lower part d the tubular, nested two absorption chambers e and f. In these, tubular counterparts h, i and k , which are attached to the pump piston g , are also immersed, which are the opposing chambers I, m and η form. The lower part d is filled with water to such an extent that only a small air space remains above the water when the piston is at its lowest point. The unabsorbed gas mixture blows off during the high pressure period through the spring-loaded valves 0, p, q, r from the chambers I and m into the free atmosphere. The chamber η becomes the oxygen-rich one

Gas mixture through the pipe s and through the pressure valve c, which, like the valves o, p, q, r. is loaded accordingly, pushed away with each piston downward movement to the point of use or to the gasometer.

In the embodiment described above, absorption is carried out twice an air gas mixture with about 50 percent oxygen content is achieved, each wide chamber increases the oxygen level until it is about 98 percent after the eighth absorption. If more than two chambers are used, it contains that which escapes into the free atmosphere Gas mixture has an increasing oxygen content with each additional chamber, and this mixture can be passed through feed a pipe back to the suction valve δ; this increases the efficiency of the machine significantly increased.

Claims (4)

Patent Claims: i. Device for the production of oxygen-rich air according to the absorption process, characterized in that an air compression pump with several through the liquid spaces with each other communicating absorption chambers of circular cross-section in such connection stands that without any control by the pump piston alternately compressions in the absorption chambers and suction effects are produced. 2. Embodiment of the device according to claim 1, characterized in that in tubular nested chambers (e and f) likewise tubular counter- chambers (h, i and k) protrude, which are attached to the compressor piston (g) and follow its movements. 3. Embodiment of the device according to claim 1 and 2, characterized in that it has a suction valve (b) on the outer chamber (e) and a pressure valve (c) on the discharge pipe of the innermost chamber (s) . 4. Embodiment of the device according to claim 1, 2 and 3, characterized in that in the piston (g) relief valves (0, -p, q and r) are mounted. 1 sheet of drawings.