ES2620737T3 - Procedure and device for physical heat treatment of liquid media - Google Patents

Abstract

Device for the physical thermal treatment of liquid media, intervening in a polar and / or ionic way in a medium (9) pre-treated in a hydrodynamic way through a system of electrochemical potentials, as well as electrochemical RC AC signals, comprising a body (1) preferably of insulating material on whose axis or in its vicinity it has a positive electrode (2) formed by a material with positive electrochemical potential and is separated from the medium (9) through a layer (21), while a negative electrode (3) of negative electrochemical potential is arranged on the perimeter, where the body (1) has a first inlet-outlet port (4) as well as a second inlet-outlet port (5), in whose area The first input-output negative electrode (31) or a second input-output electrode (32) are arranged at work.

Description

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DESCRIPTION

Procedure and device for the physical thermal treatment of liquid media

The invention relates to a method and a device for the physical thermal treatment of liquid and gas media.

Conventional methods and devices for heat treatment contain heating elements, by which they heat the liquid, preferably water or steam. The heating elements are regularly formed by heat conductive materials such as, for example, metal or semiconductor ceramic material. These heating elements are connected to an energy source. Other heating elements are formed by heat exchangers, which are heated through gas flames and in which water flows. Electroinductive heating elements are also known as disclosed, e.g. e.g., in WO 2004/062320. In this case, a heating element with contact is arranged inside the body and the body is wrapped by a coil controlled by frequency source.

These devices achieve a complicated distribution of the heating medium and the sockets and gas. The contact surfaces of the heating elements are small, the heat treatment is irregular and the operation is not profitable due to the high costs. It is common for steam to be used for the heat supply, which heats a liquid which, however, is very complicated and expensive. The regulation of the heat treatment process is complicated, and the speed of the heat treatment is low. Gas combustion products or combustion gases and radiant heat are harmful to the environment. During the heat treatment, crystals are produced in the liquid, which have to be reduced and eliminated by chemical means.

A procedure and a device for the physical thermal treatment of liquid media are known from GB 1,460,143. The procedure influences a medium through a system of electrochemical potentials as well as RC AC electrochemical signals. The device comprises a body of insulating material, on whose axis or in its vicinity, an electrode is arranged, while a negative electrode is arranged on the peffometer. The body has a first entry-exit hole as well as a second entry-exit hole.

Starting from the state of the art above, the invention is based on the task of remedying.

This task is solved in each case through the characteristics of the independent claims.

It is recognized that the invention in any case is put into practice when it is a procedure and / or device for the physical thermal treatment of liquid media, in which the pre-treated medium is actuated in a polar and / or ionic hydrodynamic manner. through a system of electrochemical potentials as well as RC AC electromagnetic signals. In this case, a simple or multiple flow of the medium is provided through the system of electrochemical potentials and electromagnetic signals Rc AC.

In this case, it is advantageous to act on the hydrodynamic medium in a hydrodynamic way at the outlet and / or inlet with the system of electromagnetic potentials with negative electrochemical potentials. The flow of the medium through the system of electrochemical potentials and electromagnetic signals RC AC preferably takes place in multiple ways. The size of the body with electrochemical potentials and electromagnetic signals is variable and adapts to the particularities of the case. In the hydraulic circuit (compressed air circuit) of the pre-treated hydrodynamic medium, measuring instruments can be preferably connected to continuously measure the physical and / or chemical variations, as well as the energy variations in order to control the parameters achieved. , for example flow, temperature, conductivity, viscosity, pH value, and the like. The positive electrode may consist primarily of a material with positive electrochemical potential, for example copper, carbon, and the like, while the negative electrodes may be formed of a negative electrochemical potential material, for example iron, aluminum or stainless steel, and the like. . In an alternative embodiment of the invention a positive electrode that narrows / decreases may be formed as a type of source for ions and / or colloids. This intervenes in the electrochemical material of the positive electrode that has an insulating layer of glass and Teflon on its peffometer. This narrowing electrode is separated from the hydrodynamically pre-treated medium by an insulating layer, whereby a part of this electrode is traversed through the medium.

The electrodes, which form the electrochemical potentials in the body of the alternative embodiment, are formed mainly of synthetic and natural minerals, ceramic material, and the like. A hydrodynamic treatment of the medium in the body can be achieved mainly with a tangential inlet and an outlet, which, however, is oriented against the direction of the current, whereby a circulation solution is achieved. The advantage of the procedure and the device is based on its simplicity. As a hydrodynamic medium pretreated in a hydrodynamic manner within the meaning of the invention, distilled and mineralized water, vegetable rapeseed oil, alcohol, petroleum, synthetic alcohol as well as propane-butane gas were used and advantageously tested. In these media there have been physical alterations that have been distinguished by the increase in temperature.

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During a multiple passage of the pre-treated medium in a hydrodynamic manner through the device according to the invention, an increase in water temperature from room temperature to 83 ° C was observed with approximately 4000 l of water. In this test, it was observed that the inlays present in the walls of the water container were considerably reduced, whereby this procedure is also advantageously applicable to thermal economics and hydroconophysics. The new and modified properties of the medium, especially water, can also be used for cleaning surfaces in lavenders and for the production of beverages in the food industry. It is also possible to modify the characteristics of oxidation and reduction of water and gas. These modifications are proportional to the number of passages through the device.

By treating according to the invention of the medium, the aggressiveness of the water can be reduced in a simple manner. For this, the water is sufficiently enriched with positive and negative ions of the elements, which leads to the reduction of the corrosion of the tubena or of the measuring instruments. With this treatment, a chemical water treatment can be prevented in some cases. The effect is nonpolluting. The heat treatment efficiency is very high, a medium temperature of up to 97 ° C can be reached. Through an optimal sizing of the interior spaces of the body as well as its successive and juxtaposed arrangement it is possible to increase the efficiency of the procedure and the device in a simple way for the physical thermal treatment of fluid media.

The invention is explained in more detail with the help of embodiments and the accompanying drawings. They show:

Fig. 1 a simplified horizontal plane of a device for carrying out the process according to the present invention for the physical thermal treatment of liquid media with an inlet and outlet perpendicular to the axis of the device,

Fig. 2 a device with an integrated negative electrode,

Fig. 3 an A-A section of Fig. 2 with a tangential inlet and outlet and

Fig. 4 an alternative embodiment of a positive electrode with a narrowing electrode.

The device for carrying out the process according to the present invention consists of an essentially cylindrical body 1, preferably of an insulating material, for example, polyethylene, polypropylene, silicate or glass ceramic material, on whose axis or in its enclosure it is arranged a positive electrode 2. Electrode 2 is composed of a material of positive electrochemical potential, for example copper, carbon and the like. In an alternative embodiment, this positive electrode 2 is totally or only partially separated from the pre-treated means 9 hydrodynamically by means of an insulating layer 23 of glass or Teflon. Along a part or along the entire length of the positive electrode 2, a negative electrode 3 formed of aluminum, stainless steel and the like, with negative electrochemical potential, is arranged on the penimeter. The body 1 has a first inlet-outlet port 4, as well as a second inlet-outlet port 5. These two holes 4, 5 can be arranged perpendicularly, parallel to their axis with reference to the body 1, but preferably they are arranged eccentrically tangential shape, the second inlet-outlet orifice 5 being arranged against the circulation of the hydrodynamically pre-treated medium 9 flowing through the first inlet-outlet orifice 4. Consequently, in body 1 there is produced a natural flow of the pre-treated medium 9 hydrodynamically. Circulation variations can be achieved when the surface structure of the positive electrode 2 and the negative electrode 3 is modified, possibly when its shape is changed and the body 1 is correspondingly dimensioned. In the first inlet-outlet orifice 4 and in the Second inlet-outlet orifice 5 is provided a first input-output electrode 31, or a second input-output electrode 32. The designation for these electrodes is derived from contact with the pre-treated means 9 hydrodynamically in the body 1 and not, for example, if they are arranged in the first and second inlet-outlet port 4 and 5. These two electrodes can also be arranged in a hydraulic pipe outside body 1 or can be replaced by a part of the hydraulic pipe that is made of a material with a negative electrochemical potential.

A control electrode 6 is located in body 1, possibly outside the body with electrochemical potentials, and the RC AC electromagnetic signal is supplied to it. For the specific embodiment, a frequency in the range of 150 to 400 Hz, mainly 300 Hz, was tested in a yield of 0.5 W.

In the case of using several bodies 1, these can be arranged in series or parallel to each other, namely, with different sizes of volume and different parameters, for example of frequency, of changing electromagnetic field, of circulation speed and variations of the direction of circulation, or also of the circulation distribution. In an alternative embodiment, the positive electrode 2 shows at least one end of a narrowing electrode 22, which is in a glass envelope, which forms an insulating layer 21 and which is introduced into the material with positive electrochemical potential, preferably carbon, as a source for ions and / or colloids, and which, in addition, is separated from the material with positive electrochemical potential through an insulating layer 23. A positive electrode 2 of this type is disposed near the material of the negative electrode 3. This solution is necessary in case of aggressive water, by means of which a high corrosion of the metallic instruments of measurement and control and also of the tubenas is formed. In this specific case the narrowing electrode 22 is formed

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by the same material as the measuring and control instruments with the highest corrosion. In the case of a bacterial treatment, the narrowing electrode material 22 is formed of antiseptic material, for example copper, silver or zinc, and the like. Through a single or multiple passage of the pre-treated hydrodynamic means 9 through the body 1 with electrochemical potential and electromagnetic frequency, physical, possibly chemical, and energy variations occur. It is advantageous that the body 1 is arranged vertically and that in its upper part a gas circuit 7 is disposable to be closed and in its lower part a mud circuit 8 capable of being closed.

The hydrodynamically pre-treated medium is mainly mineralized water, distilled water, industrial water or wastewater, a polar or non-polar fluid or a gas. The positive, negative 2, 3, 31 and 32 electrodes of the alternative embodiment are formed of artificial, synthetic or synthetic minerals, silicates or equivalents. In a further embodiment of the invention the body 1 is arranged in a closed hydraulic circuit, in which there are, for example, a flow meter, a thermometer, a viscosity measuring device and other instruments, with which the physical or chemical variations. This embodiment is suitable as a measuring post. It is advantageous that the positive and negative electrodes 2, 3, 31 and 32 have a rough surface that, for example, through a perforation, causes a perforation process or a conformation or a pleat.

An advantageous embodiment of the invention provides that the essentially cylindrical body 1 has a length of 510 mm and is composed of polypropylene (PPR). The outer diameter of the body 1 amounts to approximately 63 mm, while its inner diameter is approximately 42 mm. The axis of the inlet-outlet orifice runs at a right angle to the axis of the body 1. On the axis of the body 1 or around it are arranged positive electrodes 2, as well as control electrodes 6 of quartz glass with a diameter of approximately 12 mm. On electrode 6 there is carbon in powder form which, e.g. eg, it is isolated and bonded by epoxide. In the control electrode 6 there is an electric copper conductor, in the form of a spiral, whose diameter ranges between 0.1 and 3 mm and whose length ranges between 200 and 2000 mm. The conductor is connected to an RC AC frequency signal of 150 to 450 MHz, mainly 300 MHz. In general, frequency ranges from 30 MHz to 5 GHz with a power of 0.1 to 3 W. are considered. The positive electrode It could also be formed by a copper rod with a Teflon coating. The glass coating or the Teflon layer does not have to be distributed over the entire surface of the positive electrode 2.

It is convenient that the positive electrode is not in contact with the medium 9. The negative electrodes are composed of aluminum, mainly with a piece of curved sheet that is in contact with the medium 9. However, it could also be coated with Teflon. Electrodes with insulating coatings are used in the polarization regime, while non-insulated electrodes are used in the ionization regime of the device. The power of the circulation pumps used can range between 20 W and 3,000 W. For the heating of distilled water from room temperature to 50 ° C, 1.5 to 2.5 m3 / h were circulated at a speed of 50-79 m / s An optimization or an increase in the performance of the installation can be achieved through the increase in electromagnetic potentials between the electrodes and / or through the increase in the performance of the rA AC signals. Very good results can be achieved with a body 1 with tangential eccentric arrangements of the inlet-outlet holes with diameters of 12, 18 and 36 mm. This results in a breakdown of the current whirlwind by means of changing the orientation of the current. In this case, the speed of the medium amounts to 0.5 to 150 m / s. In the operation of ionization of the installation, the internal density of Cu, Al, etc. amounts to approximately 0 to 1 g / m3.

The possibilities of application of the invention are given by the size of the physical properties of fluids and gases that pass through the device. The variations are proportional to the number of entries of the passages through the electrochemical potentials, possibly the use of the control electrode. The application can be used in the industry of the enrichment of drinking water and water for industrial use, in industrial water and wastewater, in construction, in crenotherapy and hydrothermal stations, in cleaning and laundry facilities, in the food industry, in the production of alcohol, in the beer industry, in healthcare, in dermatology, in the manufacture of ceramics and in the generation of heat, in the thermal industry, in treatment plants, in the energy industry, in water sources, in swimming pools, also in treatments of the oil industry and in the automobile industry and in similar industries.

Due to a high crystallization of carbonates it is advantageous in the course of heating the medium to minimize oxidation. This can be achieved when the treated medium leaves the device and comes into contact with a negative electrode, especially Al. This is important, e.g. eg, in the treatment of corrosive water in wells. In multiple cycles of the medium through the devices light effects occur in the medium that can be used for special purposes, e.g. eg, in factories.

Claims (11)

5 10 fifteen twenty 25 30 35 40 Four. Five 1. Device for the physical thermal treatment of liquid media, intervening polarly and / or ionically in a medium (9) pre-treated in a hydrodynamic way through a system of electrochemical potentials, as well as RC electrochemical signals AC, which comprise a body (1) preferably of insulating material on whose axis or in its vicinity it has a positive electrode (2) formed by a material with positive electrochemical potential and is separated from the medium (9) through a layer (21), while on the penimeter a negative electrode (3) of negative electrochemical potential is arranged, wherein the body (1) has a first inlet-outlet port (4) as well as a second inlet-outlet port (5), in whose working area is arranged a first negative input-output electrode (31) or a second input-output electrode (32). 2. Device according to claim 1, characterized by a control electrode (6) to which the RC AC electromagnetic signal is provided. 3. Device according to claim 1 or 2, characterized in that the positive electrode (2) is formed by a material with positive electrochemical potential, mainly Cu, C and the like, and because the negative electrodes (3, 31 and 32) are made of a material with negative electrochemical potential, preferably steel Stainless, Fe, Al and the like. 4. Device according to one of claims 1 to 3, characterized in that the ions and / or colloids of the positive electrode (2) have their origin in the form of a narrowing electrode (22), which intervenes in the electrochemical material of the positive electrode (2) that is separated from the pre-treated medium (9) hydrodynamically by means of an insulating layer (23) and why The positive electrode (2) has an insulating layer (21). 5. Device according to one of claims 1 to 4, characterized in that The electrodes, which form the electrochemical potentials, are formed by natural and / or artificial minerals. Method for the physical thermal treatment of liquid media by means of a device according to one of the preceding claims, in which polar and / or ionic intervention is carried out in a medium (9) pre-treated hydrodynamically through a system of electrochemical potentials, as well as RC AC electrochemical signals, a single or multiple flow of the medium (9) being provided through the system of electrochemical potentials and RC AC electromagnetic signals. 7. Procedure according to claim 7, characterized in that The hydrodynamically pre-treated medium (9) is exposed to the negative electrochemical potentials at the entrance and / or exit of the system. 8. Procedure according to claim 7 or 8, characterized in that The hydrodynamically pre-treated medium (9) is repeatedly conducted by a body (1) with electrochemical potentials and RC AC electromagnetic signals. 9. Method according to one of claims 7 to 9, characterized in that both the size and arrangement of the electrochemical potentials and the RC AC electromagnetic signal are modifiable and because in the hydrodynamic circuit of the medium (9) measuring instruments can be arranged for the continuous measurement of physical and / or chemical parameters of the medium such as temperature, pressure, conductivity, viscosity, pH value, oxidation and reduction reactions. 10. Method according to one of claims 7 to 10, characterized in that The hydrodynamically pre-treated medium (9) is enriched in negative and / or positive ions of the elements Ag, Au, Cu, Al, Fe and also in other elements, which are necessary to achieve the desired modifications, for example the bacterial modifications 11. Method according to one of claims 7 to 11, characterized in that The hydrodynamically pre-treated medium (9) also acts outside the body (1) through an electromagnetic control electrode (6).