FR2654273A1 - Mini-accelerator with friction device for rapid particle collision and formation of ions from liquid and gaseous sources - Google Patents

Abstract

In order to produce ions, particularly negative ions, a mini-accelerator is proposed, comprising a reservoir (13) in which a liquid is placed, a system for injecting gas under pressure, with a friction tube (26) oriented along the axis of the reservoir, and a liquid intake channel (28) immersed in the reservoir, the end of which is curved over towards the outlet of the friction tube. A metal wire (34) allows the charges of positive ions formed to be absorbed, while the negative ions are removed by inwards-curved tubing (18, 20). This device, which is particularly simple and devoid of any risk of explosion or fire, may be used especially for producing negative ions, in order to implant liquid medication or medication in solution on the surface of living tissue, or for depositing a layer of a product on an object.

Description

DESCRIPTION
The invention relates to a mini-accelerator comprising a friction device for sucking up liquid particles and causing them to collide at high speed with gaseous particles, to form ions, particularly negative ions.

 Such a device can in particular be used to produce negative oxygen ions such as 2 and 2 (H2O) n in order to improve the quality of the air breathed, and protect the health and longevity of humans, animals and plants.

 Such a device can also be used to produce suitable ions of aqueous chemical, biological or medical materials (natural or artificial), and to implant these ions on the surface of living tissue or on the surface of any material or object solid, or to add it to another chemical composition, or to introduce it into chemical, biochemical or biological processes.

 Such a device can also present a new technique called ion layer technology.

It could have many important applications.

 In addition, there are many techniques for producing negative and positive ions from gases, liquids or solids.

 All these known techniques require a contribution of natural or artificial power which can be provided by radioactive materials, a source of high electrical power, a high pressure, a high temperature or a significant source of radiation, which can be of origin. nuclear, electrical, mechanical or electromechanical. These different technologies make it possible to produce ions which can be used in very diverse fields.

 The object of the invention is precisely to use the properties of friction tubes to produce ions, particularly negative ions such as Oj and 2 (H2O) n, in order to protect the health and longevity of men, animals and plants. , and also suitable ions of aqueous materials and implanting these ions on the surface of living tissue to facilitate the introduction of drugs into the cells without this drug being injected using a syringe, and deposition ions (positive or negative) of certain liquid products on the surface of any support, without the need to have recourse to a source of electrical, nuclear, radiative power, etc.

According to the invention, this result is obtained by means of a mini-accelerator for the production of ions, particularly negative ions, characterized in that it comprises: - a liquid reservoir of given axis; - a negative ion production chamber in which
open a friction tube oriented along the axis of
Said room and suitable for being connected to a source of
gas under pressure, and a liquid suction channel
immersed in the liquid tank and including an ori
outlet is oriented towards said axis, a means
absorption of positive ion charges linked to the
earth also being placed in said chamber; - a curved outlet tube extending the chamber
producing negative ions in the outgoing gas direction
both from the friction tube.

 In a mini-accelerator thus formed, negative ions are produced from a gas and a liquid by the charge separation process, without it being necessary to carry out a power supply, whether under electrical, nuclear or other form.

 The dimensions of the mini-accelerator, which can vary in particular between less than 1 cm and several cm depend on the envisaged application.

 In addition, this mini-accelerator can be manufactured using any suitable material such as metal, plastic, glass, etc., provided that this material resists corrosion, acid attack and is sufficiently resistant to pressure and temperature as well as to mechanical stresses. The least costly material for medical and biological applications is quartz, whereas for industrial applications, a metal or a plastic material preferably coated with a protective layer may be chosen, which may for example be gold.

 In a first embodiment of the invention, the friction tube is connected to a pressurized gas inlet connection opening laterally on the liquid tank by a curved tube, the liquid suction channel being formed in a suction tube substantially parallel to the axis of the chamber, a first end of which opens out near the bottom of the liquid reservoir and the opposite end of which includes a part folded at right angles which opens out beyond the end friction tube.

 The folded part at right angles to the suction tube then preferably has an outlet orifice situated in a plane which makes an angle between 0 and 200 with respect to the axis of the chamber, this angle being turned towards the friction tube.

In a second embodiment of the invention, the friction tube is connected to a pressurized gas inlet connection opening into the bottom of a liquid tank by a straight tube centered on the axis of the chamber, the liquid suction channel being an annular channel formed between said rectilinear tube and an outer tube concentric with this rectilinear tube, a first end of this outer tube opening near the bottom of the tank, while
The opposite end opens radially into a cylindrical passage extending the friction tube along the axis of the chamber.

Two embodiments of the invention will now be described, by way of nonlimiting example, with reference to the appended drawings, in which:
- Figure 1 is a longitudinal sectional view showing a first embodiment of the mini-accelerator according to the invention;
- Figure 2 is an enlarged view showing the end of the friction tube and the end of the liquid suction tube in the mini-accelerator of Figure 1; and
- Figure 3 is a view comparable to Figure 1 illustrating a second embodiment of the invention.

 In FIG. 1. the reference 10 generally designates the body of the mini-accelerator for producing ions according to the invention. In the position illustrated in the figure which corresponds to the position of preferential use of the mini-accelerator, the wall of the body 10 comprises a cylindrical lower part 11, closed by a bottom 12 and delimiting a reservoir of liquid 13.

Above the reservoir 13, the wall of the body 10 of the mini-accelerator has a bulge 14 delimiting a chamber 16 for producing ions. Beyond this bulge 14, the wall of the body 10 is extended upwards by an outlet tube 18 whose part 20 adjacent to the bulge 14 is curved with respect to the axis common to the reservoir 13 and to the chamber 16.

 A tubular connector 22 is fixed radially outside the cylindrical wall II of the reservoir 13, at a level preferably greater than the level of the liquid contained in this reservoir. This tubular connection 22 is extended inside the body 10 of the mini-accelerator by a tube 24 in an arc of a circle which ends along the axis common to the reservoir 13 and to the chamber 16 by a converging part forming a friction tube. 26 oriented upwards along this axis. When the tubular connection 22 is connected, for example by means of a flexible pipe, to a source of pressurized gas, this gas penetrates inside the body 10, in which it is accelerated by the friction tube 26 to escape upwards into the negative ion production chamber 16 by creating a depression in the vicinity of the gas jet leaving the friction tube.

 The mini-accelerator shown in FIG. 1 also comprises a suction tube 28, the lower end of which opens in the immediate vicinity of the bottom 12 of the reservoir 13 and which is oriented substantially parallel to the axis of the latter over most of its length. At its upper end, the suction tube 28 comprises a portion 30, of reduced diameter, which is folded approximately at right angles so as to open out radially with respect to the axis of the reservoir 13 just above the end of the friction tube 26.

 More precisely and as illustrated in FIG. 2, the outlet orifice of the upper part 30 of the suction tube 28 is advantageously situated in a plane which makes an angle α between 0 and 200 relative to the axis common to the reservoir 13 and to the friction tube 26, this angle being turned towards the end of the latter. Preferably, the value of this angle a is 80.

 As illustrated in FIG. 1, the suction tube 28 is advantageously supported by the tube 24, by means of a connecting member 32 placed between the two tubes.

 The mini-accelerator according to the invention further comprises an electrically conductive metal wire such as a tungsten wire 34 constituting a means for absorbing positive and / or negative ions in the chamber 16 for producing ions. This metal wire 34 is supported by the tube 24 and the friction tube 26 so that the distance between the wire 34 and the friction tube is at least 1 mm and the end of the wire 34 is located slightly at the beyond the end of the friction tube 26, for example approximately 1 mm above this end. The wire 34 passes tightly through the body 10 of the mini-accelerator, to be connected to Earth outside of the latter, in the example shown.

When wire 34 has a negative charge, the mini-accelerator produces negative ions. If the charge of wire 34 is positive, the mini-accelerator produces positive ions. Finally, if this charge is neutral, positive and negative ions are produced, but most of them (around 80%) are negative.

 Finally, the mini-accelerator according to the invention comprises, in the bulge 14 delimiting the chamber 16 for producing ions, a port 36 for injecting fluid, which can be used to fill the reservoir with liquid 13 before putting in route of the mini-accelerator and also to inject other gases into chamber 16 when using the latter.

 The various elements constituting the mini-accelerator which has just been described can be made of any anti-corrosion, anti-acid material capable of withstanding mechanical stresses, pressure and temperature. This material can in particular be quartz in the case where the mini-accelerator is used for medical and biological applications or a metal covered with gold leaf or else a plastic material coated with a protective material in industrial applications .

 The nature of the ga # injected by the tubular connection 22 as well as the nature of the liquid contained in the reservoir 13 depend on the use which is made of the mini-accelerator.

 Thus, when the mini-accelerator is used to produce negative air ions such as negative oxygen ions in the form of 2 and 02 (H2O) n, the gas injected by the tubular connection 22 is L air or oxygen at a pressure between about 0.5 and 2 atmospheres. In this case, the tubular connection can be connected either to a mini pressurization engine aspirating ambient air, or to a capsule of air under high pressure. In both cases, the pressurized air is conveyed to the friction tube 26 by the tube 24.

 In this application, the reservoir 13 is filled with water. Water is sucked through the tube 28 by the depression created at the outlet of the friction tube 26, so that the air is ionized at the ionization point located # at the intersection of the extensions of the upper part 30 from the tube 28 and from the end of the friction tube 26. The positive ions are absorbed by the metallic wire 34 connected to ground, while the negative ions are ejected towards the outlet tube 18 under the effect of the jet of air coming out of the friction tube 26 along the axis of the bulge 14. The small negative ions such as 2 and 2 (H2O) n, which are the most beneficial for health, pass through the chamber 16 then the bent part 20 to be expelled through tubing 18.

On the other hand, heavy and large ions cannot cross the bent part 20 and fall back into the reservoir 13.

 Finally, a large quantity of negative air ions and in particular O2 and 2 (H20) n is produced by the mini-accelerator with a concentration which varies between 105 cm3 / s and 106 cm3 / s, depending on the air pressure, of the shape and dimensions of the friction tube 26, of the shape of the end of the part 30 of the tube 28, and in particular of the angle a, of the shape and dimensions of the chamber of negative ion formation 16 and of the purity of the air admitted into the mini-accelerator. In particular, it is easily understood that the quantity of ions produced increases with the pressure of the air.

 The mini-accelerator according to the invention can also be used to implant negative ions from a liquid which can be natural, chemical, medical, etc., either on the surface of living tissues, or on the surface of a solid material or object. With this in mind, the liquid contained in the reservoir 13 can be a drug or a drug solution, the negative ionization of which facilitates implantation inside the cells of the human or animal body. This liquid can also be a chemical in solution which it is desired to deposit in thin layers on an object and whose ionization facilitates attachment.

 As in the case of the production of negative air ions, the pressure of the gas injected by the tubular connection 22, as well as the chemical, medical and biological properties of this gas and of an additional gas possibly injected through the orifice 36 vary depending on the intended application.

 The mini-accelerator also functions in a manner comparable to the first application described, that is to say that the gas or the mixture of gases injected under pressure by the tubular connection 22 creates a vacuum at the outlet of the friction tube 26 , which has the effect of sucking up the liquid or the mixture of liquids contained in the reservoir 13 and of ionizing this liquid. The charges of positive ions being retained by the metal wire 34, only the negative ions formed by the shock of the gas and the liquid at high speed pass through the chamber 16, then the bent part 20 to escape through the outlet pipe 18 .

 In the embodiment of FIG. 3, in which the elements comparable to those of the mini-accelerator described with reference to FIGS. 1 and 2 are designated by the same reference numbers increased by 100, only the structure of the elements used to inject the gas and the structure of the elements used to suck the liquid have been modified.

 In this second embodiment, the bottom 112 of the tank 113 is pierced in its center by a circular opening onto which is externally connected a tube 121 coaxial with the tank 113 and into which opens out laterally a tubular connector 122 able to be connected to a source gas under pressure.

 The tube 121 is extended inside the reservoir 113 by a tube 124 terminated at its upper end by a friction tube 126. Both the tube 124 and the tube 126 are arranged coaxially inside the reservoir 113. They are doubled on the outside by an outer tube 128, the lower end of which is located at a very small distance (for example, about 1 mm) from the bottom 112 of the reservoir 113. The tube 128 defines with the tube 124 and the friction tube 126 an annular space 129 liquid suction, which opens into a passage 127 of small section extending the friction tube 126 along its axis.

 A load separation member which is in the form of a sphere 131 in the embodiment shown is placed in the axial extension of the passage 127 and connected to the tube 128 by two branches 133 in the form of C. Alternatively, the the load separation member could also have the shape of a pyramid with at least three sides. The distance between the outlet of the passage 127 and the separating member, of charges 131 is between 3 and 10 mm and; preferably equal to 6 mm. These dimensions depend on the dimensions of the entire mini-accelerator.

 In this embodiment of FIG. 3, the absorption of positive ions is also obtained using a metal wire 134, for example made of tungsten, one end of which is located outside the body of the mini-accelerator is connected to the earth This metallic wire 134 passes tightly through the wall of the mini-accelerator and travels inside One of the branches 133 and of the charge separation member 131, to exit the latter along the common axis to the reservoir 113, to the tubes 124 and 128 and to the friction tube 126, opposite the passage 127 extending the latter. The other end of the metal wire 134 is located a short distance from the member 131.

 The mini-accelerator illustrated in FIG. 3 generally works like the mini-accelerator previously described with reference to FIGS. 1 and 2.

Thus, when pressurized gas is injected through the tubular connector 122, the vacuum created at the outlet of the friction tube 126 has the effect of sucking through the annular passage 129 the liquid contained in the reservoir 113. Under the effect shock between molecules
The gas and liquid, these are ionized and the ions formed are entrained by the gas stream until they strike the charge separation member 131. The resulting shock increases ionization. The charges of positive ions thus created are absorbed by the wire 134, while the negative ions are evacuated by the outlet tubing 118, the heaviest ions being brought back to the reservoir 113 by the curved part 120 of this tubing.

 The mini-accelerator of FIG. 3 has a higher yield than that of FIGS. 1 and 2, because it makes it possible to obtain a larger number of ions and ions of smaller dimension.

 Furthermore, the applications of this mini-accelerator are identical to those of the previous one.

 Of course, the invention is not limited to the embodiments which have just been described by way of examples, but covers all the variants thereof.

Thus, the reservoir 13 or 113 can in certain cases be closed at its upper part, so that the liquid which it contains does not escape when the mini-accelerator is tilted. Likewise, the reservoir 13 or 113 may be larger or be connected to an annex reservoir of greater capacity.

Claims (10)

 1. Mini-accelerator for the production of ions, particularly negative ions, characterized in that it comprises - a liquid reservoir (13,113) of given axis; - a negative ion production chamber (16) in  which open out from a friction tube (26,126) oriented  along the axis of said chamber and able to be connected to  a source of pressurized gas, and a suction channel  tion of liquid (28,129) immersed in the tank  liquid and with an outlet opening oriented  towards said axis, a means of absorbing ion charges  positive (34,134) connected to earth being also  placed in said chamber; - a curved outlet pipe (18,20) extending  the negative ion production chamber in the sense  gas coming out of the friction tube.  2. Mini-accelerator according to claim 1, characterized in that the liquid reservoir (13,113) extends the negative ion production chamber (16) opposite the outlet pipe (18,20).  3. Mini-accelerator according to claim 2, characterized in that the friction tube (26) is connected to a pressurized gas inlet connection (22) opening laterally on the liquid tank (13) by a tube curved (24), the liquid suction channel being formed in a suction tube (28) substantially parallel to the axis of the chamber, a first end of which opens near the bottom of the liquid reservoir and of which The opposite end includes a right-angled folded portion (30) which opens beyond the end of the friction tube (26).  4. Mini-accelerator according to claim 3, characterized in that the right-angled folded part (30) of the suction tube (28) has an outlet orifice situated in a plane which forms an angle (a) between 0 and 200 with respect to the axis of the chamber, this angle being turned towards the friction tube.  5. Mini-accelerator according to any one of claims 3 and 4, characterized in that the means for absorbing positive ion charges comprises a metal wire (34) which travels along the friction tube (26) on the side opposite the suction tube and one end of which is located slightly beyond the end of the friction tube.  6. Mini-accelerator according to claim 2, characterized in that the friction tube (126) is connected to a pressurized gas inlet connection (122) opening into the bottom of the liquid tank (113) by a rectilinear tube (121,124) centered on the axis of the chamber, the liquid suction channel being an annular channel (129) formed between said rectilinear tube and an external tube (128) concentric with this rectilinear tube, a first end of this outer tube opening near the bottom of the tank, while the opposite end opens radially in a cylindrical passage (127) extending the friction tube along the axis of the chamber.  7. Mini-accelerator according to claim 6, characterized in that a charge separation member (131) is placed in the extension of said cylindrical passage (127), in the chamber for producing negative ions.  8. Mini-accelerator according to claim 7, characterized in that the load separation member (131) is connected to the outer tube (128) by at least one C-shaped branch (133), in which runs a metallic wire (134) constituting said means for absorbing positive ion charges and one end of which passes through the charge separation member and opens out along the axis of the chamber, opposite said cylindrical passage.  9. Mini-accelerator according to any one of claims 7 and 8, characterized in that the distance between the load separation member (131) and the end of the cylindrical passage (127) is between 3 and 10 mm.  10. Mini-accelerator according to any one of the preceding claims, characterized in that the negative ion production chamber (16) comprises a fluid injection orifice (36) formed in the wall of this chamber.