RU2379365C1 - Method of titanium-bearing raw material processing - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: method includes preparation of charge, its loading into chlorinator with melt of metals chlorides, chlorination by feeding of chlorine-containing agent through 4 chlorine lead-in into melt of metals chlorides with continuous innovation of melt with receiving of gas-vapor mixture, containing titanium tetrachloride. Then it is implemented saline cleaning of gas-vapor mixture by saline melt of alkaline metals chlorides and cleaning in spray scrubber with condensation of admixtures chlorides in pulp of liquid titanium tetrachloride, used in the capacity of reflux liquid in scrubber, circulation of formed pulp in circuit of spray scrubber in circuit of chlorinator, extraction of titanium tetrachloride by condensation in direct-contact condenser. Additionally chlorination is implemented with usage in the capacity of chlorine-containing agent of chlorine gas and/or anodic chlorine-gas, pulp at first is contact to waste from chlorinator by gas-vapor mixture, and then with melt mirror by metal chlorides. Saline cleaning of gas-vapor mixture is implemented by means of contacting of gas-vapor mixture contact, escaping from chlorinator with surface of melt of alkaline metals chlorides at keeping of melt temperature 350-400°C, concentration of free alkaline metals chlorides 0.5-3.0 wt % and with processing of surface coating of melt by gas stream of inert gas at a rate of feeding 40-120 m³/hour.

EFFECT: intensification of reprocessing.

2 cl, 2 ex

Description

The invention relates to the metallurgy of titanium and can be used in the processing of titanium-containing raw materials by the chlorine method to produce titanium tetrachloride.

A known method of processing titanium-containing raw materials by chlorination by sparging a chlorinating agent through a molten salt containing carbon, iron, aluminum and alkali metal chlorides at a temperature of 500-700 ° C with further condensation of titanium tetrachloride.

To separate gaseous and solid chlorination products during their formation, alkali metal chlorides (KCl, NaCl) are continuously charged onto the surface of the chloride melt at a molar ratio of impurities formed of chlorides of (1.2 ÷ 1.6): 1. Titanium tetrachloride is condensed from the resulting vapor-gas mixture in series-connected irrigation condensers. Condensed titanium tetrachloride from irrigation condensers contains 20-30 g of solid suspensions per 1 liter of titanium tetrachloride. To obtain the final product - technical titanium tetrachloride with a suspension content of less than 1-2 g / l, the condensed titanium tetrachloride of one of the irrigation condensers is subjected to evaporation or filtration, from which solid impurities in the form of pulp are returned to the chlorinator. (Aut. St. USSR No. 361213, C22B 34/12, publ. 03/23/1970).

The disadvantage of this method is to carry out complex operations of evaporation or filtration of condensed titanium tetrachloride, which significantly complicates the hardware design of the chlorination process of the feedstock and leads to an increase in the cost of the final product, and the return of solid impurities to the chlorinator unproductively increases the mass of circulating chlorides and, thereby, reduces the productivity of the process in whole and increases the concentration of chloride impurities in the melt.

There is also a method of processing titanium raw materials by chlorination of the latter in a melt of chloride salts. ("Titan" under the editorship of V.M. Garmat. - M .: Metallurgy, 1983, p. 273-300).

This method involves the production of titanium tetrachloride and includes the steps of: grinding titanium slag and a carbon reducing agent; mixing these components and loading the mixture into a chlorinator on a mirror of a melt of alkali and alkaline earth metal chlorides; chlorination with gaseous chlorine or anode chlorine gas at a temperature of 750-800 ° C and continuous updating of the melt.

As a result of chlorination of the feed, a vapor-gas mixture is formed, consisting of titanium tetrachloride and impurity chlorides, as well as an unchlorinated residue, which is removed from the chlorinator with the spent melt of alkali metal chlorides.

The gas-vapor mixture containing titanium tetrachloride is sequentially purified from solid impurities. The purification is carried out first from higher boiling solid and liquid chlorides, then solid chlorides are separated from the gaseous salts by salt cleaning and the chlorides are condensed in an irrigation scrubber and irrigation condensers for the final recovery of titanium tetrachloride.

The titanium tetrachloride pulp obtained after the irrigation scrubber is fed to the steam-gas mixture in the irrigation scrubber circuit and in the chlorinator circuit.

The method has the following disadvantages:

- cleaning dust of solid chlorides in hollow capacitors leads to the formation of lumpy smoking sublimates, which complicates their further processing;

- circulation of the pulp from the irrigation scrubber to the irrigation scrubber circuit and to the chlorinator circuit carries out heat removal, but does not allow it to be regulated depending on the performance of the chlorinator.

These shortcomings reduce the efficiency and technical and economic indicators of the process.

Closest to the claimed method of processing titanium-containing raw materials is a method of processing titanium slag by chlorination, which is carried out as follows. The initial titanium slag and carbon reducing agent are crushed and mixed in the required proportion. Then the resulting mixture is loaded into a chlorinator and chlorination is carried out at a temperature not exceeding 750 ° C with a linear velocity of chlorine in the chlorinator of 20-30 m / s and the ratio of chlorine to slag (1.48 ÷ 2.62): 1. The concentration of titanium dioxide and a reducing agent in the chloride melt is maintained at the level of 1 ÷ 4 and 3 ÷ 5%, respectively.

The gas-vapor mixture leaving the chlorinator and consisting of titanium tetrachloride, iron chlorides, aluminum and solid particles enters the salt scrubber. Salt cleaning is carried out by irrigation of a gas-vapor mixture with a molten salt of alkali metal chlorides at a temperature of 550-700 ° C. After the salt melt is saturated with chlorides of impurities, the chloride melt is sent to a chlorinator.

The purified titanium tetrachloride and gaseous products (CO ₂ , Na) are then transferred to an irrigation scrubber, where, using irrigation pulp, consisting of liquid titanium tetrachloride and solid suspensions, the process of condensation of titanium tetrachloride proceeds. Pulp consumption is 80-100 t / t TiCl ₄ . The pulp formed in the irrigation scrubber circulates in the circuit of the irrigation scrubber itself. The main part of titanium tetrachloride is condensed in irrigation condensers using titanium tetrachloride with a temperature of 90-105 ° С, 25-40 ° С and 0 - (- 15 ° С) as an irrigation liquid.

To stabilize the temperature regime of the process of chlorination of raw materials and prevent the temperature from rising above 750 ° C, the exhaust steam-gas mixture is subjected to irrigation by pulp from an irrigation scrubber. Pulp consumption - 2.0-3.0 tons per ton of titanium tetrachloride.

Salt purification of a gas-vapor mixture is carried out in salt scrubbers operating when the gas-vapor mixture passes through a layer of salt melt circulating from the bottom up, which is supplied by a pump or airlift. In this case, the gas-vapor mixture is fed into the scrubber perpendicular to the salt melt flowing from top to bottom along the volume of the scrubber. (See RF patent No. 2136772, C22B 34/12). The method adopted for the prototype.

The disadvantages of the method are:

- the temperature limit of 750 ° C inhibits the possibility of increasing the productivity of the chlorinator, since the process temperature is a determining factor in increasing the rate of chlorination of raw materials;

- irrigation of the gas-vapor mixture of the chlorinator with pulp of an irrigation scrubber in an amount of 2.0-3.0 tons per ton of titanium tetrachloride does not provide uniform removal (removal) of heat and a high degree of capture of chloride impurities and solid particles, resulting in the formation of a crust of chloride impurities on the arch and in the flue of the chlorinator. This leads to an increase in resistance at the outlet of the gas-vapor mixture from the chlorinator gas duct, and also worsens the conditions of heat transfer through the arch and gas duct of the chlorinator. These shortcomings worsen the operation of the chlorinator, which is accompanied by a decrease in the period of its continuous operation and a decrease in the efficiency of the process of condensation of chlorides;

- when steam-gas mixture is irrigated with pulp from an irrigation scrubber, concentration of solid particles (carbon, slag particles), iron, aluminum chlorides in a salt scrubber occurs; This phenomenon is accompanied by the formation of growths from these components, which leads to a significant increase in the resistance of the salt scrubber, a violation of the temperature regime of the latter and requires the operation of cleaning it, which negatively affects the operation of the entire process chain, and also reduces the efficiency of the subsequent stages - the operation of the condensation system apparatuses.

The disadvantage of salt cleaning in the prototype is the rapid overgrowth of the salt filter gas ducts, which requires stopping and cleaning the apparatus. ^*)

*) A description of the work of a salt scrubber, see “Rare and Scattered Elements” by S. S. Korovin, D. V. Drobot et al., M., MISiS, 1999, p. 339).

These shortcomings hold back the possibility of increasing the efficiency of the process as a whole and do not allow for smooth and reliable regulation of it.

The technical result of the claimed invention is to intensify the process of chlorination of raw materials and increase the efficiency of the process of salt purification of gas-vapor mixture.

The technical result is achieved by the fact that in the method of processing titanium-containing raw materials to produce titanium tetrachloride, which includes preparing the charge, loading it into a chlorinator with a metal chloride melt, chlorination by supplying a chlorine-containing agent through chlorine feeds to a metal chloride melt with continuous updating of the melt to obtain a vapor-gas mixture containing tetrachloride titanium, subsequent salt cleaning of the gas-vapor mixture with a molten salt of alkali metal chlorides and cleaning in an irrigation scrubber with condensation impurity chlorides in the pulp of liquid titanium tetrachloride used as an irrigation liquid in the scrubber, circulation of the formed pulp in the irrigation scrubber circuit and the chlorinator circuit, titanium tetrachloride is isolated by condensation in an irrigation condenser, according to the invention, chlorination is carried out using chlorine gas and / or as a chlorine-containing agent anode chlorine gas when feeding at a linear speed of 70-140 m / s in each chlorine supply, the pulp is fed from the irrigation scrubber into the chlorine circuit t with a pulp temperature of 70-110 ° C, while the pulp is first contacted with the vapor-gas mixture leaving the chlorinator, and then with the mirror of the metal chloride melt at a density of irrigation of the melt surface of 1.5-4.5 t / m ² surface per hour, salt purification of the gas-vapor mixture is carried out by contacting the gas-vapor mixture stream leaving the chlorinator with the surface of the alkali metal chloride melt at a linear gas-gas mixture flow rate above the melt 25-100 cm / s and maintaining the melt temperature 350-400 ° C, free chlorine concentration s of alkali metals and 0.5-3.0 wt% with the treatment of the surface layer of the melt by the gas flow of inert gas at a flow rate of 40-120 m ³ / hr.; after salt purification of the steam-gas mixture, the spent melt is dissolved in a weakly acid hydrochloric acid solution, the resulting pulp is filtered, the filtrate containing iron and aluminum chlorides is neutralized to pH 3-5, the obtained precipitate of the mixture of iron and aluminum hydroxides is dried to obtain a marketable product - a highly dispersed coagulant.

The essence of the method is as follows.

Chlorination of the feedstock in a melt of chloride salts with the supply of a chlorinating agent with a linear velocity in the range of 70-140 m / s makes it possible to intensify the process, since this parameter leads to efficient fragmentation of the chlorine bubble with a corresponding significant increase in the surface of interaction of the reacting phases.

To stabilize the temperature of the chlorination process in a given temperature range and the efficiency of the process of cleaning the vapor-gas mixture from impurities, the pulp from the irrigation scrubber is fed to the chloride melt mirror with a feed density of 1.5-4.5 t / m ² · h and with a temperature of 70-110 ° C .

These parameters, linking the amount of pulp with the unit area of the melt and with the feed rate, ensure greater uniformity of the irrigation of the vapor-gas mixture formed by the chlorination process with the pulp. This allows you to smoothly control and maintain the temperature regime of chlorination, as efficiently as possible at this stage to clean the vapor-gas mixture from solid particles of the charge, to efficiently carry out heat removal and prevent the formation of a skull (growths) on the walls and flue of the chlorinator.

Further purification of the vapor-gas mixture from impurities is carried out by contacting it with a salt bath, which is a melt of alkali metal, iron and aluminum chlorides. The composition of the salt bath contains unbound alkali metal chloride in an amount of 0.5-3.0% by weight of the chloride melt. The temperature in the salt bath is maintained within 350-400 ° C, and nitrogen in the amount of 40-120 m ³ / h is supplied to the surface layer of the chloride melt, and the gas-vapor mixture is passed over the surface of the chloride salt bath with a linear velocity of 25-100 cm / s.

The claimed interval of the linear transmission rate of the vapor-gas mixture in combination with its supply in a plane parallel to the surface of the melt and the content in the melt of chloride of unbound alkali metal chloride of 0.5-3.0 wt.% Significantly increases the efficiency of cleaning the vapor-gas mixture from iron and aluminum chlorides and the degree of capture of dust particles of the chlorinated charge, and the claimed low temperature range of the bath of chloride chloride (350-400 ° C) significantly reduces the probability of impurities going to the stage of titanium tetrachloride condensation in rositelnyh capacitors.

The supply of nitrogen to the bath of chloride chloride in the declared amount creates the conditions of a gushing regime (foaming of the surface layer) with an increase in the interaction surface of the gas-vapor mixture with the chloride chloride. This increases the efficiency of the deposition of impurities and improves the conditions of mass-heat transfer between the reacting phases.

After saturation of the bath of chloride melt with chloride impurities, the chloride melt is partially drained and transferred for processing with the receipt of an additional commercial product - powdered coagulant.

The vapor-gas mixture after contact with the surface of the salt bath of chlorides enters the stage of condensation of tetrachloride in the irrigation scrubber and then in the irrigation condensers. The gas-vapor mixture entering the irrigation scrubber is irrigated with pulp circulating in the irrigation scrubber circuit, the temperature of which is maintained in the range of 70-110 ° C. A certain part of the pulp is fed to the stage of chlorination of raw materials to stabilize the temperature regime. The claimed temperature range supplied to the pulp chlorinator circuit, and its density in the chlorinator on the melt mirror allow more gentle and accurate support of the chlorination parameters of the feedstock in the required technological mode.

The stepwise condensation of titanium tetrachloride in irrigation condensers, which is carried out in the same way as in the prototype using titanium tetrachloride as an irrigation liquid with a temperature from 90-105 ° С to 0 - (- 15) ° С, provides the condensation efficiency of the pre-purified steam-gas mixture with the receipt of the final product of the process of chlorination of titanium-containing raw materials - titanium tetrachloride, containing not more than 0.8 ÷ 1.1 g / l of solid impurities.

Justification of the parameters.

Chlorination of the feedstock in a molten chloride salt is carried out with the supply of a chlorinating agent with a linear velocity in the range of 70-140 m / s.

When a chlorinating agent is supplied with a linear velocity below 70 m / s, the speed and completeness of chlorination decreases, therefore, the productivity of the chlorination process decreases. In addition, a larger amount of waste is formed, and the extraction into the final product, titanium tetrachloride, drops.

When a chlorinating agent is supplied with a linear velocity above 140 m / s, the degree of assimilation of chlorine decreases and its slip into the gas-vapor mixture increases, the consumption of chlorine unproductively increases, and sanitary working conditions deteriorate.

For the chlorination process, a pulp with a temperature of 70-110 ° C is supplied from the irrigation scrubber to the chlorinator circuit.

When pulp is fed with a temperature below 70 ° C, a sharp decrease in the temperature of the vapor-gas mixture is observed and flue gas overgrowth occurs, resulting in a decrease in the performance of the chlorination process due to stopping the chlorinator and cleaning the flue gas.

When pulp is fed with a temperature above 110 ° C, the load on all devices of the condensation system (salt scrubber, irrigation condenser) increases sharply, since a preliminary decrease in the temperature of the vapor-gas mixture is insignificant and the efficiency of the salt cleaning process decreases.

The density of the irrigation of the surface of the melt by pulp is 1.5-4.5 tons per 1 m ² surface per hour.

When the density of irrigation is less than 1.5 t / m ² surface per hour, the efficiency of cleaning chlorides from impurities (iron, aluminum) is not achieved.

With an irrigation density of more than 4.5 t / m ^{2 of} surface per hour, the contact time of the pulp with the vapor-gas mixture necessary for effective cleaning decreases, the degree of cleaning decreases, and the load on the condensation system increases sharply.

Salt cleaning is carried out by contacting the vapor-gas mixture stream leaving the chlorinator with the surface of the salt filter melt at a linear vapor-gas mixture flow rate above the melt 25-100 cm / s and maintaining the melt temperature of 350-400 ° C, the concentration of free alkali metal chloride 0.5 -3.0 wt.% And with the processing of the surface layer of the melt by a stream of inert gas, for example nitrogen, with a feed rate of 40-120 m ³ / h

With a linear vapor-gas mixture flow rate above the melt below 25 cm / s and maintaining the melt temperature below 350 ° C, the performance of the salt filter decreases and the efficiency of trapping solid chlorides and unreacted raw materials decreases.

At a linear vapor-gas mixture flow rate above the melt above 100 cm / s and maintaining the melt temperature above 400 ° C, the cleaning efficiency of solid chlorides decreases, the leakage of chlorine into the vapor-gas mixture increases, and the load on the irrigation condenser increases.

Free alkali metal chlorides provide the binding of impurity chlorides to high-boiling complex compounds, for example, NaFeCl ₄ .

When the concentration of free alkali metal chloride is below 0.5 wt.%, The degree of capture of chloride impurities and particles of unreacted raw materials is reduced.

When the concentration of free alkali metal chloride is higher than 3.0 wt.%, It is inappropriate to increase the consumption of alkaline reagents.

Processing the surface layer of the melt with an inert gas stream with a feed rate below 40 m ³ / h does not increase the contact surface of the gas-vapor mixture with the melt and reduces the cleaning efficiency.

Processing the surface layer of the melt with an inert gas stream with a feed rate above 120 m ³ / h unproductive increases the inert gas flow rate and worsens the contact of the vapor-gas mixture with the melt.

The method is illustrated by examples.

Example 1

The titanium slag containing TiO ₂ 87-88 wt.% Was chlorinated. Titanium slag was crushed and mixed with coke to obtain a charge. Chlorination was carried out at a temperature of 720-730 ° C in a melt of salts of alkali metal chlorides and iron chlorides at a concentration of titanium dioxide of 2.0-2.5 wt.% And a reducing agent of 4.0-4.5 wt.% At a molar ratio of potassium chlorides and sodium to the sum of iron and aluminum chlorides is more than 1.0. Anodic chlorine gas was supplied to the chlorinator in 4 chlorine inlets with a linear feed rate of 85-90 m / s in each with a ratio of chlorine and slag (1.5-1.6): 1.

The resulting vaporous chlorides in the form of a vapor-gas mixture (ASG) containing titanium tetrachloride, chloride of iron, aluminum, potassium and sodium and solid particles of the starting components (slag, coke) were irrigated with pulp coming from the irrigation scrubber. The pulp temperature is 85 ° C, the density of the PGS irrigation is 3.0-3.2 t / m ² · h, while the PGS is mainly purified from solid unreacted particles of the charge. After purification from impurities, PGS was sent for salt purification in a salt scrubber. The temperature of the salt bath of the scrubber is 370-375 ° С, the content of unbound alkali metal chlorides is 1.5-1.7% of the mass of the salt melt, and the linear velocity of the ASG flow over the surface of the salt bath of chlorides was 50-55 cm / s. The contacting of ASG with the surface of the molten salt bath was carried out simultaneously with the treatment of the surface layer of the melt with a nitrogen gas stream. The nitrogen flow rate was 65-70

m ³ / h

During salt cleaning in a melt of alkali metal chlorides, unreacted charge particles, solid iron and aluminum chlorides are transferred from ASO to the melt. After saturation of the melt, it was poured and processed in order to obtain coagulants. For this, the spent melt was dissolved in a weakly acidic solution of hydrochloric acid (hydrochloric acid concentration of 5-7 g / l) to obtain a pulp with T: W = 1: 3.

The pulp was filtered, the filtrate containing dissolved iron and aluminum chlorides was neutralized with an alkaline reagent, for example, NaOH solution, to pH 3-5, with precipitation of iron and aluminum hydroxides.

The hydroxide precipitate was washed, dried to obtain a free-flowing powder, which is a highly dispersed coagulant.

Partially purified ASG in a salt scrubber was sent to an irrigation scrubber, where further treatment of ASG from iron, aluminum and other high boiling chlorides (sodium and potassium) takes place. As the irrigation liquid, titanium tetrachloride pulp obtained in the process of condensation was used. In the irrigation scrubber, solid impurity chlorides are captured and the titanium tetrachloride is partially condensed to form pulp, which is circulated to the chlorinator circuit and to the circuit of the irrigation scrubber itself to cool the pulp. The pulp temperature in the irrigation scrubber was maintained at a level of 80-90 ° C.

Purified ASG was directed to stepwise condensation in irrigation condensers. The first stage of condensation was carried out at a temperature of 90-105 ° C, the second one at a temperature of 25-40 ° C and the final condensation of titanium tetrachloride was carried out at a temperature of 0 - (- 15) ° C.

The final product, liquid titanium tetrachloride, was removed from the irrigation condenser system.

The yield of titanium in the final product is 96.3%, the solids content in titanium tetrachloride is 0.8 g / l.

Example 2

The titanium slag containing TiO ₂ 87-88 wt.% Was chlorinated. Titanium slag was crushed and mixed with coke to obtain a charge. Chlorination was carried out at a temperature of 740-760 ° C in a melt of salts of alkali metal chlorides and iron chlorides at a concentration of titanium dioxide of 3.0-3.2 wt.% And a reducing agent of 5.0-5.1 wt.% At a molar ratio of potassium chlorides and sodium to the sum of iron and aluminum chlorides is more than 1.0. A gaseous mixture containing 70% anode chlorine gas and 30% chlorine gas was fed into the chlorinator, 4 chlorine inlets with a linear feed rate of 75-85 m / s in each at a ratio of chlorine to slag (1.5-1.6): 1.

The resulting vaporous chlorides in the form of a vapor-gas mixture (ASG) containing titanium tetrachloride, chloride of iron, aluminum, potassium and sodium and solid particles of the starting components (slag, coke) were irrigated with pulp coming from an irrigation scrubber. The pulp temperature is 90 ° C, the density of the PGS irrigation is 2.6-3.0 t / m ² · h, while the PGS is mainly cleaned of solid unreacted particles of the charge. After purification from impurities, PGS was sent for salt purification in a salt scrubber. The temperature of the salt bath of the scrubber is 370-375 ° С, the content of unbound alkali metal chlorides is 2.0-2.3% of the mass of the salt melt, and the linear velocity of the ASG flow over the surface of the salt bath of chlorides was 65-75 cm / s. The contacting of ASG with the surface of the molten salt bath was carried out simultaneously with the treatment of the surface layer of the melt with a nitrogen gas stream. The nitrogen flow rate was 50-60

m ³ / hour.

During salt cleaning in a melt of alkali metal chlorides, unreacted charge particles, solid iron and aluminum chlorides are transferred from ASO to the melt. After saturation of the melt, it was poured and processed in order to obtain coagulants. For this, the spent melt was dissolved in a weakly acidic solution of hydrochloric acid (hydrochloric acid concentration of 5-7 g / l) to obtain a pulp with T: W = 1: 3.

The pulp was filtered, the filtrate containing dissolved iron and aluminum chlorides was neutralized with an alkaline reagent, for example, NaOH solution, to pH 3-5, with precipitation of iron and aluminum hydroxides. The hydroxide precipitate was washed, dried to obtain a free-flowing powder, which is a highly dispersed coagulant.

Partially purified ASG in a salt scrubber was sent to an irrigation scrubber, where further treatment of ASG from iron, aluminum and other high boiling chlorides (sodium and potassium) takes place. As the irrigation liquid, titanium tetrachloride pulp obtained in the process of condensation was used. In the irrigation scrubber, solid impurity chlorides are captured and the titanium tetrachloride is partially condensed to form pulp, which is circulated to the chlorinator circuit and to the circuit of the irrigation scrubber itself to cool the pulp. The pulp temperature in the irrigation scrubber was maintained at a level of 80-90 ° C.

Purified ASG was directed to stepwise condensation in irrigation condensers. The first stage of condensation was carried out at a temperature of 90-105 ° C, the second one at a temperature of 25-40 ° C and the final condensation of titanium tetrachloride was carried out at a temperature of 0 - (- 15) ° C.

The final product, liquid titanium tetrachloride, was removed from the irrigation condenser system.

The titanium yield in the final product is 96.3%, the solids content in titanium tetrachloride is 0.7 g / l.

Thus, the claimed invention allows:

- increase the productivity of the chlorination process;

- improve the quality of technical titanium tetrachloride by reducing the content of solid impurities;

- increase the service life of all equipment: chlorinator, salt scrubber, condensation system due to more efficient cleaning of gas-vapor mixture from solid impurities.

Claims (2)

1. A method of processing titanium-containing raw materials to produce titanium tetrachloride, including the preparation of a charge, loading it into a chlorinator with a metal chloride melt, chlorination by supplying a chlorine-containing agent through 4 chlorine feeds to a metal chloride melt with continuous updating of the melt to obtain a vapor-gas mixture containing titanium tetrachloride, followed by salt purification of a gas-vapor mixture with a molten salt of alkali metal chlorides and purification in an irrigation scrubber with condensation of impurity chlorides in a liquid tetrachl pulp titanium oxide used as an irrigation liquid in the scrubber, circulation of the formed pulp in the irrigation scrubber circuit and the chlorinator circuit, the isolation of titanium tetrachloride by condensation in an irrigation condenser, characterized in that the chlorination is carried out using gaseous chlorine and / or anode chlorine as a chlorine-containing agent feed at a linear speed of 70-140 m / s in each chlorine supply, pulp is fed from the irrigation scrubber to the chlorine circuit with a pulp temperature of 70-110 ° C, while bullets PU is first contacted with a gas-vapor mixture leaving the chlorinator, and then with a mirror of a metal chloride melt at a melt surface irrigation density of 1.5-4.5 t / m ^{2 of} surface per hour, salt cleaning of a gas-vapor mixture is carried out by contacting a gas-vapor mixture stream leaving chlorinator, with the surface of the melt of alkali metal chlorides at a linear flow rate of the vapor-gas mixture above the melt 25-100 cm / s and maintaining the temperature of the melt 350-400 ° C, the concentration of free alkali metal chlorides of 0.5-3.0 wt.% and with processing minutes of the surface layer of the melt by the gas flow of inert gas at a flow rate of 40-120 m ³ / h. 2. The method according to claim 1, characterized in that after saline cleaning of the vapor-gas mixture, the spent melt is dissolved in a weakly acid hydrochloric acid solution, the resulting pulp is filtered, the filtrate containing iron and aluminum chlorides is neutralized to pH 3-5, the resulting precipitate of a mixture of iron hydroxides and aluminum is dried to obtain a marketable product - a highly dispersed coagulant.