WO1995032796A1

WO1995032796A1 - Process and device for enriching drinkable aqueous liquids, in particular drinking water, with oxygen

Info

Publication number: WO1995032796A1
Application number: PCT/EP1994/001707
Authority: WO
Inventors: Dariush Behnam; Abolghassem Pakdaman
Original assignee: Dariush Behnam; Abolghassem Pakdaman
Priority date: 1994-05-26
Filing date: 1994-05-26
Publication date: 1995-12-07
Also published as: DE9420518U1; AU6997294A

Abstract

A process is disclosed for enriching drinkable aqueous liquids, in particular drinking water, with oxygen, making it easier to enrich the liquids with oxygen while obtaining a stable final product. For that purpose, an oxygen-containing gas is introduced into a high-speed flow of liquid and the thus formed mixture is made to rotate along at least one path with a decreasing radius (30). Drinking water for example may thus be enriched with more than 60 mg/l oxygen. A device for carrying out the process has a pump (10) connected to a liquid source for feeding the liquid at high speed to an ejector unit (20) connected to an oxygen-supplying gas source (1). A rotary nozzle (22) and a spiral pipe system (30) are mounted downstream of the ejector unit and are followed by a tap (50) for the mixture. This device makes is possible to continuously produce about 6000 l/h mixture.

Description

DESCRIPTION

Method and device for the enrichment of oxygen in drinkable, aqueous liquids, in particular drinking water

The invention relates to a method for enriching oxygen in a drinkable, aqueous liquid, in particular drinking water.

Since the groundbreaking development of oral oxygen therapy (POT) by Prof. Dr. A. Pakdaman it is known that an increased oxygen partial pressure in the blood can be achieved by oral administration of water enriched with oxygen. The work on oral oxygen therapy (POT) by Prof. Dr. A. Pakdaman have recently been recognized by the awarding of the German Medicine Award.

The uptake of oxygen by the human organism after orally administered, oxygen-enriched water is only recently again at the instigation of and in close cooperation with Prof. Dr. A. Pakdaman and Dipl.-Ing. D. Behna through POT investigations by Prof. Dr. Dr. M. Wannenmacher has been documentarily confirmed at the Heidelberg University Hospital. Peroral oxygen therapy can alleviate a number of complaints such as circulatory disorders, pulmonary and respiratory disorders, cardiac and vascular dysfunction, hypoventilation, disorders of the internal respiration (cellular respiration), anemia, enzyme defect, poisoning, microcirculation disorders, disturbed energy supplies to the cell , Migraines, gastrointestinal complaints, immunodeficiency, fatigue, fatigue and poor performance as well as psychovegetative disorders can be positively influenced. In some cases, therefore

ORIGINAL DOCUMENTS the complex and risky therapy methods, such as respiratory and intravenous oxygen therapy, are replaced by peroral oxygen therapy. Further areas of application of the latter therapy result in the areas of surgery, anesthesia, internal medicine, cardiology, gastroentology, rheumatology, lung diseases, cancer prevention and therapy (surgery, chemotherapy, radiation therapy and biotherapy), gynecology, Dermatology (disinfectant solutions for external use, eg wound irrigation), in the ear, nose and throat area, eyes, geriatrics, sports and space medicine.

The invention is based on the object of specifying a method and a device for enriching oxygen in drinkable, aqueous liquids, in particular drinking water, with which the oxygen enrichment, for example in drinking water, can be simplified with good stability of the product obtained.

For this purpose, according to the invention, an oxygen-containing gas is drawn into the liquid flowing at high speed, optionally containing one or more medicinal active substances, and the mixture formed is rotated along at least one path with a decreasing radius. This enables drinking water, for example, to be enriched with more than 60 mg / l of oxygen. This value is considerably higher than the known saturation solubility of oxygen in water. The mixture obtained in this way has an excellent shelf life over a period of at least one year without any significant amount of oxygen escaping from the mixture. In combination with the use of medications such as vitamins, minerals and trace elements, an increased effectiveness is achieved.

It is particularly advantageous to use a conical pipe system as the path, which allows better use of the flow speed allowed. The efficiency is increased if the mixture is passed through a plurality of paths connected in series, the axes of which form a right angle with one another, better results being achieved if the axis of a first path is horizontal and the axis of a second path is directed vertically. In the sense of a further improvement of the enrichment, the preferred measure is to draw the gas into the liquid via several parallel channels. It is also advisable to feed the mixture back into the liquid after rotation and to subject it again to the treatment described, in order to achieve an even higher or desired enrichment of oxygen in this way. Further gas can also be drawn into the mixture obtained after the rotation and then rotated again and only then can the withdrawn mixture be drawn off for use.

A device for performing the above-mentioned method has a pump connected to a liquid source, which feeds liquid at high speed to an ejector unit which is connected to an oxygen-emitting gas source, the ejector unit being followed by a spiral pipe system, behind which a tap for the mixture is provided. The ejector unit can advantageously have a plurality of ejectors which are connected in parallel to the gas source. An oxygen sensor which controls the oxygen content of the mixture and controls a downstream extraction valve is expediently arranged at the tap. Furthermore, it is advantageous to provide a return line which starts from the tap and leads to the upstream side of the pump and is provided with a control valve. Finally, a central controller is recommended, in which the output signals of the oxygen sensor, which represent the oxygen content, are compared with an adjustable setpoint and which controls the sampling valve and the control valve accordingly. With such a device, an amount of about 6,000 l / h of mixture enriched with oxygen up to 60 mg / l can be obtained continuously. The device works fully automatically and, if necessary, 24 hours a day. The invention can be used in the beverage, pharmaceutical, food and cosmetics industries, in oil refineries and in the field of environmental protection to improve water quality in waterworks, fish ponds, lakes and rivers.

Further expedient configurations of the device are specified in the subclaims.

The invention is explained in more detail below with reference to the attached schematic diagram in FIG. 1.

A gas line 11, 13, 15, 17, which is equipped with a gas meter 14, a magnetic shut-off valve 16 and a check valve 18, leads from an oxygen source 1 (not shown), which can be ambient air or an oxygen tank with a reducing valve an ejector unit 20 in which a plurality, for example five ejectors, not shown in detail, are connected in parallel to the downstream side of the check valve 18.

For example, drinking water is supplied from a water source 2 (not shown) to a tank 26 via a line 21 and a water meter 24. From the lower part of the tank 26, water is supplied to a pump 10 via line 27, in which a shut-off valve 28 is located, the pump output of which can be regulated up to a pressure of approximately 16 bar. The liquid emerging from the pump 10 at a high flow rate passes via line 29 into the ejector unit 20, in which through the liquid or water flowing in the line 13 generated negative pressure is drawn into the water in fine distribution by the ejectors mentioned. The ejector unit 20 is followed by a path for the oxygen / water mixture emerging from it, which path comprises a rotary nozzle 22 and a pipe system 30 in series. In the rotary nozzle 22, the oxygen / water mixture is directed into a circular path with an increasingly small radius, the axis of which is essentially horizontal. The rotating mixture emerging from a fine rotating nozzle opening reaches the pipe system via line 23

30, the serpents of which are arranged in a cone standing on the top with a vertical axis. The mixture leaves the pipe system 30 at the tip of the cone via line

31, in which a valve 32 is arranged.

The outflow line 37 of the solenoid valve 32 leads to a solenoid valve 34, which is the input valve to a series circuit comprising a pump 36, a further ejector unit 46, a further rotary nozzle 38 and a further pipe system 40. The units 46, 34, 36, 38 and 40 correspond to the solenoid valve 28, the pump 10, the ejector unit 20, the rotary nozzle 22 and the pipe system 30 from the upstream arrangement and are constructed and designed in the same way as this. A line 39 carrying the gas opens into the further ejector unit 46, which line is connected to line 15 and is equipped with a shut-off solenoid valve and a check valve.

A branch line 33 from line 37 leads via a magnetic valve 44 and a further line 35 to a tap 50, to which a line 41 coming from the top of the conically arranged pipe coils of the pipe system 40 also comes, which has a solenoid valve 42 is provided. A return line 65 branches off from line 35 into the tank 26 via an engine valve 66. The electrode of an oxygen sensor 56, which The material content of the mixture arriving at the tap 50 is detected and the output signals representing the oxygen content are fed via a control line to a central controller 60.

Downstream of the tap 50 there is a motor valve 52 in a tap 51. The tap 51 opens into a storage container 54 for the finished mixture, from which the water enriched with a desired oxygen content can be removed at 55 via line 53.

The liquid-carrying lines of the device can be emptied via a drain line 59 connected to the bottom of the container 54, in which a magnetic shut-off valve 58 is located, and via a drain line 61 coming from the bottom of the tank 26 and equipped with a shut-off solenoid valve 64.

Above the water level of the container 54, for example, collecting gas, which is practically pure oxygen, can be fed into the gas line 15 via a line 57 and fed back to the ejector units 20, 46.

One should also mention a bypass line 63 leading from the upstream side of the solenoid valve 28 into the line 33 with a solenoid valve 62.

The system described allows several modes of operation. In a first mode of operation (series connection), the solenoid valve 16 and the corresponding valve in line 39 as well as the valves 28, 32, 34 and 42 are opened, while the valves 62 and 44 are closed. The motor valves 52 and 66 regulate the inflow of the finished mixture into the container 54 and the backflow into the tank 26 via signals from the oxygen probe 56. Therefore, the water withdrawn from the pump 26 by the pump 10 is fed into the ejector. units 20 and 46 oxygen are drawn in from line 15 and the mixture is rotated along paths 22, 30 and 38, 40. The pump 36 is set by the control 60 such that it compensates for the pressure loss in the water flowing through the ejector unit 20 as well as the rotary nozzle 22 and the pipe system and thus produces the same flow rate in front of the ejector unit 46 as that of the pump 10 Flow velocity generated in line 29. At the tap 50, the oxygen sensor 56 measures the oxygen concentration of the gas arriving from the pipe system 40 via the valve 42 and supplies an output signal representing the oxygen content at the tap 50 to the controller 60 via a signal line Output signal compared with a signal that is representative of a setpoint of the oxygen concentration set in the controller 60. As long as the output signal from the oxygen sensor 56 is smaller than the desired value, the motor valve 66 remains open on the basis of a corresponding output signal from the controller 60, so that the mixture which has not yet been sufficiently enriched with oxygen is returned to the tank 26.

As soon as the output signal from the oxygen sensor 56 corresponds to the desired value of the desired oxygen concentration in the mixture at the tap 50, the control 60 closes the motor valve 66 and opens the motor valve 52. The finished mixture then reaches the storage container 54 and can be discharged this can be removed via line 53 at 55.

It is also within the scope of the invention to switch the first stage of the device comprising the units 10, 20, 22, 30 and the second stage of the device comprising the units 36, 46, 38, 40 in parallel between the tank 26 and the tap 50 and in parallel to operate. This will make the Throughput performance increased with lower oxygen concentration.

In the event that the desired oxygen concentration in the finished mixture is lower, for example 30 mg / l, it may be sufficient to continuously operate only the stage comprising the pump 36, the ejector unit 46, the rotary nozzle 38 and the pipe system 40, which is possible by shutting off valves 28, 32 and 16 and opening valves 62, 34 and 42. The pump 36 must then of course generate the full water pressure.

The output of the pumps 10 and 36 can be regulated and can be set as a function of the desired oxygen concentration and / or the type of liquid being treated.

In the event that a malfunction occurs on the pump 36, the ejector unit 46 or the paths 38 and 40 or maintenance has to be carried out, the first can be closed by closing the valve 34 and the valve 62 and opening the valves 28, 32 and 44 Pump 10, the ejector unit 20 and the path 22, 30 take over the preparation of the mixture alone. Maintenance or repair work on the system can therefore be carried out without interrupting the continuous operation.

Claims

EXPECTATIONS

1. A process for the enrichment of oxygen in a drinkable, aqueous liquid, in particular drinking water, characterized in that an oxygen-containing gas is drawn into the liquid flowing at high speed, optionally containing one or more medicinal active substances, and the liquid formed Mixture is rotated along at least one path (22, 30) with decreasing radius.

2. The method according to claim 1, characterized in that a conical pipe system (30) is used as the path.

3. The method according to claim 1 or 2, characterized gekennzeich¬ net that the mixture is passed through a plurality of ge connected series, the axes of which form a particular right angle.

4. The method according to any one of the preceding claims, da¬ characterized in that the axis of a first path (22) horizontally and the axis of a second path (30) are selected vertically.

5. The method according to any one of the preceding claims, characterized in that the gas is drawn into the liquid via a plurality of parallel channels.

6. The method according to any one of the preceding claims, characterized in that the mixture is at least partially fed back into the flowing liquid after the rotation if the desired oxygen concentration of the mixture has not yet been reached.

7. The method according to any one of the preceding claims, characterized in that the gas is drawn into the flowing liquid and the subsequent rotation of the mixture is carried out several times in succession in this order.

8. The method according to any one of claims 1 to 6, characterized in that the gas is drawn into the flowing liquid and the subsequent rotation of the mixture is carried out several times in parallel.

9. Device for enriching oxygen in a drinkable, aqueous liquid, in particular drinking water for carrying out the method according to one of the preceding claims, characterized in that a pump (10) connected to a liquid source (2) pumps the liquid at high speed Ejector unit (20) feeds, which is connected to an oxygen-emitting gas source (1), and that the ejector unit (20) is followed by a spiral pipe system (22, 30), behind which a tap (50) for the mixture is provided.

10. The device according to claim 9, characterized in that the pipe system (30) is conical.

11. The device according to claim 9 or 10, characterized gekenn¬ characterized in that several, preferably two pipe systems (22, 30) are connected in series, which are advantageously arranged at right angles to each other.

12. The device according to one of claims 9 to 11, characterized in that one of the pipe systems (22) is designed as a rotary nozzle.

13. Device according to one of claims 9 to 12, characterized in that the axis of a first pipe system (rotary nozzle 22) horizontally and the axis of a second pipe system (30) are arranged vertically.

14. Device according to one of claims 9 to 13, characterized in that the ejector unit (20) has a plurality of ejectors which are connected in parallel to the gas source (1).

15. Device according to one of claims 9 to 14, characterized in that a mixture return line (65) to the suction side of the pump (10) is provided between the pipe system (22, 30) and the tap (50).

16. Device according to one of claims 9 to 15, characterized in that between the tap (50) and the pipe system (22, 30) a further stage with a series-connected pump (36), ejector unit (46), and another spiral pipe system (38, 40) is switched.

17. The apparatus according to claim 16, characterized in that the further spiral pipe system has a further Rota¬ tion nozzle (38) and a further conical pipe system (40), wherein the further Rotations¬ nozzle (38) horizontally and the further conical Rohrsy¬ stem (40) are aligned vertically.

18. Device according to one of claims 9 to 17, characterized in that an oxygen sensor (56) for detecting the oxygen content of the mixture is arranged at the tap (50) and represents a central control (60) for the detected oxygen content ¬ tive output signals, the controller (60) the output signals with a predetermined target compares the value and, depending on the result of the comparison, controls a withdrawal valve (52) connected downstream of the tap (50).

19. The apparatus according to claim 18, characterized in that the controller (60) controls a valve (66) arranged in the mixture return line as a function of the result of the comparison.

20. Device according to one of claims 9 to 19, characterized in that the performance of the pump or pumps (10, 36) is adjustable and can be adjusted depending on the desired oxygen concentration and / or the type of liquid being treated.

21. Drinkable, aqueous liquid, optionally containing one or more medicinal active ingredients which are enriched with oxygen and produced by a method according to one of claims 1 to 8 and / or a device according to one of claims 9 to 20 .