FR2936508A1 - METHOD AND DEVICE FOR FORMING INSOLUBLE CHEMICAL COMPOUNDS IN A LIQUID ENVIRONMENT - Google Patents

Abstract

The present invention relates to a process for the formation of insoluble salts in a liquid medium, in a single step or reactor where reaction mechanisms and physical changes occur, such as the initial precipitation of complexes which serve as nuclei for Lateral mechanisms of nucleation and adsorption of other species formed. The formation of these first precipitates is due to the action of an electric and magnetic field applied by an ultrafiltered electric current transmitted through electrodes, in addition to the ionic contribution of one of the electrodes which acts as a sacrificial electrode. Then, a second addition of ions, usually aluminum, calcium, iron, lead or tin, is added to form new complexes with the salts contained in the liquid. With this process, the nuclei initially formed increase their size by virtue of these novel complexes and, at this stage, there is also a phenomenon of adsorption of other non-complex salts formed. The different complexes are formed by the selectivity of the processes that are carried out by the application of electromagnetic waves of frequencies in the radio wave spectrum (between 1 KHz and 2 MHz), with an equipment generating electromagnetic waves of different geometry. and frequency.

Description

R 2936508 1 METHOD AND DEVICE FOR FORMING INSOLUBLE CHEMICAL COMPOUNDS IN A LIQUID ENVIRONMENT

The present invention relates to the recovery of soluble salts by transforming them into insolubles by chemical, electrical and magnetic methods. In the state of the art, there are many processes in which chemical reactions give insoluble products. However, other reactions form soluble salts which, therefore, can not be separated from the liquid. The present invention solves this technical problem by taking all the soluble salts of a liquid and forcing them to form insoluble compounds. In the state of the art, there are examples of methods for forming insoluble salts: Japanese Publication JP2004255627 discloses a salt insolubilization process as pretreatment to prevent fouling of reverse osmosis membranes. This method does not use a magnetic field or frequency and is not able to insolubilize chlorides or sulfates.

Publication US 5858249 describes a process for the insolubilization of ionic species in an electrolytic cell-type plant, which operates by electrocoagulation to form insoluble species with the liquid's own salts and the supply of ions from the sacrificial electrode. This process is not capable of precipitating chlorides or sulphates.

CN Publication 1131127 describes a process for insolubilizing salts contained in a liquid by the addition of chemical reagents, such as phosphate salts and barium salts. The precipitates are separated by filtration, and therefore the liquid, in this case water, has a reduced salt content. This method does not use electric fields, magnetic fields or frequencies and is not able to form complexes. The present invention consists of a process for the formation of insoluble chemical compounds in a liquid medium by physical stimuli. The compounds formed can be inorganic or organic, simple or complex. This invention solves the technical problem of transforming highly soluble salts into insoluble compounds so that they can be separated from the liquid, allowing both separate salts and purified residual liquid to be obtained. In a single step or reaction, reaction mechanisms and physical changes occur, such as the initial precipitation of complexes that serve as nuclei for subsequent nucleation and adsorption mechanisms of other formed species. The formation of these first precipitates is due to the action of an electric and magnetic field applied by an ultrafiltered electric current transmitted through the electrodes, and to the ionic contribution of the sacrificial electrode. To this is added a second addition of ions, usually aluminum, calcium, iron, lead or tin, to form new complexes with the salts contained in the liquid. Thus, the size of the initially formed rings increases with these new complexes and, in this step, there is also an adsorption phenomenon of other non-complex salts formed. The different complexes are formed by selectivity of the processes that are obtained by the application of electromagnetic wave frequency in the radio wave spectrum at frequencies from 1 KHz to 2 MHz, with equipment generating electromagnetic waves of different geometry and frequency. The possible fields of application of this technique are, among others: - desalination of seawater, precipitation of chlorides and sulphates, 20 - elimination of salts from acidic waters of mines, - precipitation of PLS salts (pregnant leach solution ) - treatment of drinking water, precipitation of chlorides and sulphates, - treatment of boiler and chiller water, removal of sulphates and chlorides, - treatment of irrigation water, precipitation of chlorides and sulphates, - treatment of irrigation water, precipitation of phosphates and nitrates, - treatment of waste water, precipitation of chlorides, sulphates and phosphates, - treatment of waste water, precipitation of nitrates and nitrites, - insolubilisation of salts in methods for producing drugs and chemical reagents in general; - salt precipitation as pretreatment for ultrafiltration and reverse osmosis processes.

Although these examples of application can be considered as the best known, many other processes can take advantage of the insolubilization of normally soluble salts and optimize the yield and / or purity of the products obtained. Thus, any method using, in part or in its entirety, the technology of the present invention is within the scope thereof. This technology uses the application of an ultrafiltered DC voltage, with a sinusoidal variable wave geometry, sawtooth pulse, square wave pulse and an electromagnetic wave signal of the radio spectrum, which apply through a pair of electrodes. All this makes it possible to favor the precipitation reactions. Likewise, there must be a preferred pH range for said precipitation, which range must be between pH 1 and pH 12; however, it is possible to obtain good results if the process is carried out at any pH range. There is then an isokinetic coagulation step of the precipitated particles, in which this precipitation is electrically assisted. The applied voltage, corresponding to electric and magnetic fields, is also in a range between 1 V and 100 V, while the intensity of the current used must be between 10 mA and 3 A. As mentioned previously, the voltage and the electromagnetic signal are applied through electrodes which are immersed in the solution to be treated. The construction material of said electrodes is variable, depending on the quality of the water. It can be: lead, platinum, aluminum, copper, carbon, gold, tin, zinc, iron, titanium, boron, nickel or diamond. The entire process for the formation of insoluble salts uses a single device, this device comprising the following different elements: a reactor which contains a pair of electrodes of different configuration and of different construction material, inserted by one side of the reactor, one opposite the other, connected to a power source and magnetic induction, placed outside the device; a second pair of electrodes of different configuration and of different construction material, inserted inside the reactor, facing each other and next to the first pair of electrodes, connected to a generator of frequency placed outside the reactor; a spiral conductive element placed outside the reactor and connected to a source of power and magnetic induction, which conductive element is traversed by a current generating specific magnetic fields; a photonized air injection produced by means of a blower pump and a photon emitter which enters the reactor via a capillary placed next to the electrode connected to the negative pole of the supply source, so that the capillary is as close as possible to the bottom of the reactor; a generator of an electric and magnetic field, in addition to an adjustable frequency generator, placed outside the reactor; - Adjustable speed blade stirring means placed in the center of the reactor. Moreover, the realization of all the processes can be implemented in other installations with several devices. The precipitate formation method includes a determined value of pressure and temperature, those being respectively in a range of 1 to 10 bar and 0 to 90 ° C. This is because the precipitation process is concentration dependent, implying a displacement of the equilibrium constant and allowing for supersaturation. The effect of temperature affects the kinetics of the reaction and produces an increase in the precipitation process because molecular collisions are accelerated and, as a result, increases the kinetic constant. The application of external pressure produces the same result. An obvious example is the precipitation of jarosite, the formation of which is not possible under normal conditions. Therefore, it is necessary to apply these variables. Figure 1 shows the components of the invention and the connections between them.

The process is carried out in a single step, in a device consisting of a reactor (1) which contains a pair of electrodes (2 and 3) connected to a source of power and magnetic induction (4), and a second pair of electrodes (5 and 6) connected to a frequency generator (7). In addition, a photonised air stream containing ozone and oxidizing free radicals from an air pump (9) circulates the air through a photon generator (10) into the reactor (10). . In addition, a spiral-shaped conductive element (11) surrounds the reactor on the outside, which element makes it possible to circulate a current that generates specific magnetic fields. The element is connected to a magnetic power supply and induction source (4) that generates the current. The assembly must be kept in agitation with a mechanical or magnetic stirrer (8), and a chemical reagent must be added which brings the ions which are not present in the liquid, but which are necessary to complete the desired insoluble complexes. In most cases, the calcium and hydroxyl ions are deficient and therefore lime is preferably used as the sole reagent. EXAMPLE 1: Considering, for example, the application of the process to the desalination of seawater, the mechanism used is as follows: A mixture of air which passes through photons is applied firstly in seawater. The reactions that occur are as follows: 1 K hv + e E K2It 0: + H .. 4-) 20H04- 20H- The previous reaction is applied until the pH> 9.8. The electric field is applied through aluminum electrodes, producing a second electrolytic reaction: A104-Kar-1'3 + 3e- Aluminum reacts with OH- ions, forming the first nucleation based on the following reaction: A2-2 +.41 (OH) a

Once the aluminum hydroxide cores have been formed, calcium hydroxide should be assayed and a radio frequency, whose wavelength is 1.8 MHz, should be applied. Thus, the following precipitation reaction of sulphates, chlorides and phosphates is formed: ## STR2 ## Ka '2 A (OH) e-3Ca6: 112 (504) s (O1-f) 1i 3 x.aE. e.R

4Ca + 201- + 2A1 (OH) z + 3H3O + 2O2 ^ - ica, Ai, C 2 (OH) 1i 5Ca-2 + 3P0: + OH-1-) Caz (PO +) 3OH Alternatively, it is possible to forming ionic copper by applying, parallel to the ionic aluminum formation, a pair of copper electrodes to form the reaction: Cu ° * -K3Cu '+ 2e- The nitrate is captured from the medium on the basis of the following reactions: Cu -2 + 2: 103 .-, hCu (NO2): Cu + OH-. ~ Cu (OH), Thus and in the radiofrequency and field anterior medium, the following reaction is formed: 4Cu + 2.103 + 20H-s-F, tt`, e ~ Cu (. 'VOa) 2 3Cu (OH) Chlorides, sulphates, phosphates and nitrates have been precipitated. Anion removal involves the removal of aluminum, copper and calcium. Each precipitate formed has a high adsorption capacity of heavy metals. These insolubles usually formed are micro-precipitates that need to grow. To promote growth it is necessary to induce flocculation by adding polymer and then separating it by decantation and then filtration. The following table shows the operating and dosing conditions used for the sea-water experiment in San Antonio, v. Region. 10 15 20 Order Description Value Unit 1 Intensity aluminum 5 Amperes 2 Intensity copper 0.1 Amps 3 Voltage 0.62 Volts 4 Time 60 Minutes Mass of Al 1 679 mg 6 Mass of Cu 119 mg 7 Dose of air 1.5 L / min 8 Dose lime 17.5 g / L 9 Radio frequency 1.5 MHz Pulse applied Buffered Sawtooth wave 11 Sample volume 0.75 L 12 Dose alumina 4.85 g / L 13 Energy total 3.1 Watts-h 4.13 KWh / m3 The following table shows the salt removal efficiency of seawater. The table shows the raw column that indicates the quality of the seawater. The treated column indicates the value obtained after flocculation and filtration of sand and coal. The% elimination column shows the validity obtained. Element Unit Raw Untreated% of elimination Chloride mg / L 19,500 2,650 86.4% Sulfates mg / L 2,850 327 88,5% Nitrates mg / L 220 25 88,6% Phosphates mg / L 78 5 93,6 EXAMPLE 2 Another example of salt precipitation application is the insolubilization of mineral water sulfates. For this purpose, a sample of Collahuasi mineral water with an initial content of 200 mg / L of sulphates was used.

The complex used corresponds to the precipitation in the form of sodium jarosite. The element M may be sodium or potassium. For this, the following mechanism was used. First, it is necessary to apply a mixture of air that passes through photons, and it is applied directly to the seawater. The reactions that occur are as follows: Ki, hv-A E ° : S2AE0 2 + H201-) 20H ° ùe20H- The anterior reaction is applied up to pH> 9.8. The electric field is applied through aluminum electrodes, producing a second electrolytic reaction which is: ## STR2 ## Aluminum reacts with the OH- ions, forming the first nucleation based on the following reaction: At equilibrium, aluminum hydroxide cores are formed and in the medium with radiofrequency and electric field precipitation occurs in the form of of jarosite. K, RED E. ~ ^ + 2A1 (OH) + 250, + ry:) !. 1 [.413 (504) (OH) 6] The operating conditions are as follows: Order Description Value Unit 1 Intensity aluminum 6 Amps 2 Voltage 1,18 Volts 3 Time 55 minutes 4 Mass of Al 1,847 mg Dose of air 1,5 L / min 6 Radiofrequency 1,5 MHz 7 Impulse applied Cushioned Wave of sawtooth 8 Volume of sample 0.75 L 9 Total energy 6.49 Watts-h 8.65 KWh / m3 The results obtained are: Element Raw Unit Processed% Removal Sulfates mg / L 6 820 870 87.2% 5 Thus, It is possible to configure different insoluble elements with which it is possible to reduce salts. Of course, the invention is not limited to the embodiments described above and shown, from which we can provide other modes and other embodiments, without departing from the scope of the invention. .

Claims (7)

REVENDICATIONS1. Device for the formation of insoluble chemical compounds from the salts contained in the liquid to be treated, characterized in that it comprises a reactor (1) which contains: a. a pair of electrodes (2, 3) of different configuration and different construction material, inserted by one side of the reactor (1), facing each other, connected to a power source and magnetic induction (4), placed outside the device; b. a second pair of electrodes (5, 6) of different configuration and different construction material, inserted inside the reactor (1), facing each other and next to the first pair of electrodes (2, 3), connected to a frequency generator (7) placed outside the reactor (1); c. a spiral-shaped conductive element (11), placed outside the reactor (1) and connected to a power source and magnetic induction source (4), which conductive element (11) is traversed by a generating current specific magnetic fields; d. a photonized air injection produced by a blower pump (9) and a photon emitter (10) which enters the reactor (1) via a capillary placed next to the electrode connected to the negative pole of the source feeding, so that the capillary is as close as possible to the bottom of the reactor (1); e. a generator of an electric and magnetic field, in addition to an adjustable frequency generator (7), placed outside the reactor (1); f. an adjustable speed blade stirring means placed in the center of the reactor (1). A device for the formation of insoluble chemical compounds, characterized in that the power supply and magnetic induction source generates the application of an ultrafiltered DC voltage, with a variable wave geometry of sinusoidal type, a a sawtooth damped pulse, a square wave pulse and an electromagnetic wave signal of the radio spectrum, which are applied through a pair of electrodes which, together or individually, succeed in promoting the precipitation reactions, said electrodes being contained in a device that connects to electric and magnetic field generators and frequency generators (7). Device for the formation of insoluble chemical compounds according to claim 1, characterized in that the reactions which form inside the reactor (1) occur in a complete range of the pH scale, preferably between pH 4 and pH 12, as a function of the equilibrium constant; followed by an isokinetic coagulation step of electrically assisted precipitated particles. 4. Device for the formation of insoluble chemical compounds according to claim 1, characterized in that the voltages applied correspond to electric and magnetic fields between 1 V and 100 V, and a current intensity between 10mA and 3A. Device for the formation of insoluble chemical compounds according to claim 1, characterized in that the electric and magnetic fields and / or the frequencies are transmitted through different types of electrode pairs which consist of one of the following elements: : lead, platinum, aluminum, copper, carbon, gold, tin, zinc, iron, titanium, boron, nickel, diamond; the first electrode operating in pairs with another electrode of the same element, with other electrodes mentioned above or alloys of any of them. 6. Device for the formation of insoluble chemical compounds according to claim 1, characterized in that all the processes inside the reactor (1) are carried out in a temperature range between 0 and 90 ° C and in a pressure range. between 1 and 10 bar. 7. A method of using a device for the formation of insoluble chemical compounds, characterized in that it consists of: a. providing in a leaching reactor (1) a pair of electrodes (2, 3) of different configuration and different construction material, inserted by one side of the reactor (1), facing each other; . providing a second pair of electrodes (5, 6) of different configuration and different construction material, inserted inside the reactor (1), facing each other and next to the first pair of electrodes; c. providing a power source (4) placed outside the reactor (1); 5 d. providing a frequency generator (7) placed outside the reactor (1); e. provide a photonized air injection system; f. providing an air pump (9) and a capillary placed next to the electrode connected to the negative pole of the power source; g. providing an electric and magnetic field generator and an adjustable frequency generator (7), placed outside the reactor (1); h. providing an adjustable speed blade stirring means in the center of the reactor (1); i. providing a spiral conductive element (11) which surrounds the reactor (1) on the outside; 15 days introducing into the reactor (1) a solution which contains insoluble chemical compounds; k. injecting air containing ozone and free radicals into the reactor (1), using the air pump (9), the photonised air injector and the capillary; 1. simultaneously applying a frequency or electromagnetic signal of the radio spectrum to the solution which contains insoluble chemical compounds in the reactor (1), using the frequency generator (7) and a pair of electrodes; m. simultaneously applying an electrical voltage which consists of pulsed direct current to the solution which contains insoluble chemical compounds in the reactor (1), using the power source and another pair of electrodes; N. simultaneously applying specific magnetic fields using the spiral conductive element; o. simultaneously agitating the solution which contains insoluble chemical compounds in the reactor (1) using the blade stirring means; p. simultaneously adding a chemical reagent which provides ions which are not present in the liquid but which are necessary to supplement the desired insoluble complexes, preferably lime; add a second supply of ions such as aluminum, calcium, iron, lead or tin to form new complexes with the salts in the liquid.