CH379062A - Apparatus for the production of aqueous ions for the treatment of living organisms - Google Patents

Description

  

  
 



  Apparatus for the production of aqueous ions for the treatment of living organisms
 The present invention relates to an apparatus for the production of aqueous ions for the treatment of living organisms in order to regulate and promote physiological and biological activity, animal or plant.



   In this regard, it is known that negative ions have a favorable action on living organisms. This is why the object of the invention is to provide a practical and inexpensive device, acting on living organisms by the action of negative ions.



  The object of the invention is also to increase the action of the negative ions as much as possible by ensuring the production of an intense negative ionization which can be maintained for a sufficiently long time, which makes it possible to prolong and intensify the effect of the negative ions. negative ions.



   The apparatus forming the subject of the invention is characterized in that it comprises a device for producing positive and negative gaseous ions, a sprayer of liquid droplets, the nozzle of which opens into the outlet pipe of the device. production of gaseous ions, the latter operating by bubbling and comprising a receptacle containing a liquid such as water, inside which opens a pipe for supplying a gas such as pressurized air, this device thus producing a gas stream laden with gaseous ions.



   The appended drawing represents, by way of example, an embodiment of the apparatus, object of the invention.



   Fig. 1 is a schematic elevation view thereof;
 fig. 2 is an axial sectional view of an ion selector device
 fig. 3 is an axial sectional view of an alternative embodiment of the bubbling ionization device.



   The apparatus shown in FIG. 1 is made up
 by the combination of a sprayer 1 and an ionization device by bubbling.



   The latter consists of a container 2 filled with water into which a pipe 3 for supplying compressed air from a compressor 4 provided with an air filter 5 at its inlet is immersed. A pipe 6 is connected to the opening of the bubbling vessel 2
 resulting in the sprayer 1 whose outlet nozzle 7 is capable of allowing the production of water droplets of relatively large diameter, but capable of remaining suspended in the air. Thus, the ionization apparatus produces in line 6 an air stream laden with negative light ions of great mobility. These ions then attach themselves to the water droplets produced by the sprayer and which are of sufficient size for the whole to constitute large ions of low mobility.

   This device therefore ultimately produces an aqueous aerosol loaded with large negative ions and which can be directed at will at the living organisms to be treated. Of course, the compressor provided in this device can be replaced by a turbine or a fan having sufficient power to deliver pressurized air into the bubbling vessel of the ionization device.



   The favorable action of the ions produced is improved by the fact that the apparatus described makes it possible to obtain large negative ions of very low mobility, ensuring ionization of prolonged duration, whereas the usual methods and devices for producing ions negatives only allow small ions of great mobility to be obtained. This result is achieved by the fact that, in the apparatus described, the small ions produced by a suitable apparatus of any type are fixed on water droplets which serve as a vehicle for them and whose relatively large diameter is such that these small ions of high mobility are transformed into large ions of very low mobility. Thus, the negative ions produced by the device have a very effective physical and biological action on living organisms.



   The apparatus described therefore makes it possible to exert on living organisms of any nature a particularly effective action accelerating biological exchanges and promoting the development of the organisms treated. This device can be used for all kinds of living organisms, such as useful bacteria, ferments, yeasts, various plants and animals as well as man.



   Fig. 2 shows an additional device capable of being added to the main device for producing aqueous aerosols shown in FIG. 1, in order to ensure a selection of the ions at the outlet of the device, so that the aerosols carry only negative ions outside.



   In fact, as can easily be understood, the main device always produces positive ions, in greater or lesser quantity, at the same time as negative ions. However, only the latter have a favorable action on living organisms.



   This additional device is essentially constituted by a metallic chamber 8, of cylindrical shape, for example made of brass. One of its ends is formed by a wall 9 carrying an inlet nozzle 10. The other end is formed by a cover 11 of insulating material, which carries a tube 12, also of insulating material, and which passes through it. part to part.



   Inside the chamber 8 is arranged a cylinder 13 made of wire mesh, for example brass, of significantly smaller diameter. The sides of the meshes of the wire mesh constituting this cylinder may have a length of the order of approximately 4 mm. This cylinder is fixed to the internal end of the insulating tube 12.



   The cylinder 13 has a length less than that of the chamber 8. Its end, positioned opposite the end wall 9, carries a partition 14 made of thin sheet metal pierced with multiple holes.



   The wire mesh cylinder 13, which is intended to serve as an electrode, is electrically connected to a high voltage terminal 15. This terminal also serves to secure the cylinder 13, at an intermediate point along its length, with the chamber. 8, these two elements being however isolated from one another.



   For this purpose, the terminal 15 is formed by a screw engaged in a nut 16, which is welded to the cylinder 13. This nut is held against a block 17 of insulating material, which is engaged in an opening made in the chamber 8. Furthermore, the screw 15 comprises a cavity 18 intended to receive a plug 19 ensuring the connection of a conductor 20 of a suitable high voltage circuit.



   On the wall of the chamber 8 is fixed a terminal 21 for connecting another conductor 22 of the high voltage circuit. The connections are made so that terminal 15 is of positive polarity and terminal 21 of negative polarity. Thus, the wire mesh cylinder 13 constitutes a positive electrode, while the wall of the chamber 8 constitutes a negative electrode.



   The present complementary device is adapted to the device producing ionized aerosols shown in FIG. 1, by arranging the inlet nozzle 10 in the chamber 8, so that the aerosols produced by the device in question enter the interior of the chamber 8. Obviously, if the aerosol production device has an outlet nozzle , the nozzle 10 is then connected to this nozzle.



   When the ionized aerosols enter the chamber 8, the ions entrained by these aerosols are subjected to the intense electric field which prevails between the wall of the chamber 8 and the cylinder 13. The latter being connected to the positive pole, the negative ions are attracted by him and are accelerated. They then pass through the wire mesh and are thus extracted from the electric field. They can then travel outwards through tube 12. On the other hand, the positive ions are attracted by the negative electrode formed by chamber 8. They are therefore precipitated on the internal wall of this chamber and thus eliminated from the chamber. aerosol gas stream. Under these conditions, the aerosols which finally exit through the tube 12 entrain only negative ions. They therefore only contain ions which have a favorable action on living organisms.

   Preferably the inner wall of the chamber 8 has an opening on the edges of which is fixed a receptacle 23, which is intended to collect the humidity produced by the positive aerosols eliminated, this receptacle being provided with a drain valve 24.



   Fig. 3 shows an alternative embodiment of an ionization device by bubbling, which forms part of the device for producing ionized aqueous aerosols. This variant is designed so as to increase the number of ions produced by the ionization apparatus.



   On this subject, it is observed experimentally that the number of ions obtained is proportional to a large extent to the number of air bubbles which pass through the liquid. This is why the present variant is produced so as to multiply the number of air inlet orifices inside the body of water.



   In this variant, the ionization apparatus consists essentially of a container 2a made of glass or of plastic material, for example having a cylindrical shape. Close to the bottom of this container is welded a partition 25 made of porous material, for example porous porcelain or sintered glass, or else sintered metal, or any other suitable porous material. In the compartment formed between the partition 25 and the actual bottom of the container, opens a compressed air inlet pipe 3a, which can be delivered by a compressor, or any other suitable device. On top of the container 2a is welded an outlet nozzle 26 which has a side port to which is welded an outlet tube 6a. This tube is preferably a baffled tube of the type of refrigeration type for the volatile organic product distillation columns.

   The role of the baffles of this tube is to prevent the droplets of the liquid contained in the receptacle from being entrained by the current of air escaping through this tube. The liquid 27 provided in the receptacle is placed above the porous partition 25. The height of the liquid must be determined as a function of the air flow.



   As is easily understood, the compressed air arriving through line 3a in the bottom of the container is passed through the porous plate 25 over its entire surface. This air therefore enters the mass of the liquid through the multiple orifices of this plate, which causes a considerable increase in the ions produced by the device.



   The porous partition 25 arranged transversely in the bottom of the container could be replaced by a partition also made of porous material placed on one of the sides of the container and the edges of which would be welded to the internal wall of the latter so as to provide a compartment. into which the line 3a of compressed air supply would open. In this case also, the air would be made to penetrate into the liquid through the multiple orifices of this porous plate.



   The partition 25 could be replaced by a cylindrical sleeve made of porous material, with a diameter smaller than that of the container and placed inside the latter, being welded to its bottom as well as to its cover. This porous sleeve would then determine in the receptacle an annular compartment into which would open a compressed air supply line, which would be required to pass through the multiple orifices of this sleeve.



  Under these conditions, the number of compressed air passage orifices would be increased even more significantly.
  

 

Claims (1)

CLAIM Apparatus for the production of aqueous ions for the treatment of living organisms, characterized in that it comprises a device for the production of positive and negative gaseous ions, a sprayer of liquid droplets, the nozzle of which opens into the outlet pipe the device for producing gaseous ions, the latter operating by bubbling and comprising a receptacle containing a liquid such as water, inside which opens a pipe for supplying a gas such as pressurized air, this device thus producing a gas stream charged with gaseous ions. SUB-CLAIMS 1. Apparatus according to claim, characterized in that it further comprises an ion selector device into which the said pipe opens and comprising cylindrical electrodes between which an electric field exists intended to effect the separation between the ions of different polarities. 2. Apparatus according to claim and subclaim 1, characterized in that it comprises, in the bottom of the container of the ionization device by bubbling, a partition of porous material, above which is the mass of liquid, the pressurized gas supply pipe then opening into the compartment formed between this porous partition and the actual bottom of the container.