JP2004075418A - Method for producing titanium tetrachloride - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for producing titanium tetrachloride by which cooling and temperature control for gaseous titanium tetrachloride, and drying for titanium tetrachloride slurry can simultaneously and efficiently be performed. <P>SOLUTION: Titanium ore is chlorinated in a chlorination furnace, and is thereafter subjected to a cooling stage, a condensation stage and a distillation stage to produce titanium tetrachloride. In the cooling stage, titanium tetrachloride slurry consisting of solid impurities, liquid impurities and liquid titanium tetrachloride is brought into contact with gaseous titanium tetrachloride produced in the chlorination furnace. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a method for producing titanium tetrachloride, in particular, a method for producing titanium tetrachloride by cooling titanium tetrachloride gas generated in a chloride furnace and drying slurry of titanium tetrachloride at the same time. The present invention relates to a method for producing titanium chloride.
[0002]
[Prior art]
Purified titanium tetrachloride is produced through the following production steps. First, titanium tetrachloride gas is generated by reacting rutile or ilmenite, which is a titanium ore, and coke with a chlorine-containing gas in a chloride furnace heated to about 1000 ° C.
[0003]
The titanium tetrachloride gas produced in the chloride furnace is guided to a cooling device and cooled to a predetermined temperature, after most of the impurities are condensed and removed, and then cooled to a boiling point of titanium tetrachloride or lower in a condensation step, Liquid titanium tetrachloride is recovered. Since the recovered liquid titanium tetrachloride contains ore or coke carried over from the chloride furnace, or impurities such as iron, aluminum, and vanadium, the titanium tetrachloride is referred to as crude titanium tetrachloride. Impurities dissolved or mixed in the crude titanium tetrachloride are removed in the distillation step to become purified titanium tetrachloride.
[0004]
[Problems to be solved by the invention]
The crude titanium tetrachloride is purified through a distillation step. In this step, titanium tetrachloride in which solid and liquid impurities are concentrated (hereinafter sometimes referred to as “titanium tetrachloride slurry”) is distilled. Residual accumulation in The titanium tetrachloride slurry remaining and accumulated in the distillation step has been discharged out of the system and treated with water.
[0005]
In the production of the titanium tetrachloride, cooling of titanium tetrachloride gas and drying of the titanium tetrachloride slurry are performed in order to improve the production efficiency and appropriately perform the treatment of the titanium tetrachloride slurry produced as a by-product in the production process. There has been a demand for a technology capable of performing the process efficiently and stably.
[0006]
An object of the present invention is to provide a method for producing titanium tetrachloride that can simultaneously and efficiently perform cooling and temperature control of titanium tetrachloride gas and drying of titanium tetrachloride slurry in production of titanium tetrachloride. It is in.
[0007]
[Means for Solving the Problems]
In the present invention, the inventors have intensively studied to solve the above-mentioned problems, and in the cooling step in the production of titanium tetrachloride, the titanium tetrachloride slurry is brought into contact with the titanium tetrachloride gas generated in the chloride furnace, whereby titanium tetrachloride is produced. The inventors have found that the drying of the titanium chloride slurry and the cooling of the titanium tetrachloride gas can be performed simultaneously, efficiently and stably, and have completed the present invention.
[0008]
That is, according to the method for producing titanium tetrachloride according to claim 1 of the present invention, after chlorinating titanium ore in a chloride furnace, the titanium ore is cooled, condensed, and distilled. The manufacturing method is solved by providing a step of contacting a titanium tetrachloride slurry comprising solid impurities, liquid impurities, and liquid titanium tetrachloride with titanium tetrachloride gas generated in the chloride furnace in the cooling step.
[0009]
By performing such an operation, solid impurities and / or liquid impurities in the titanium tetrachloride slurry can be efficiently dried by condensing and solidifying the impurities. In addition, by cooling the titanium tetrachloride gas to a predetermined temperature, The impurity gas component contained in the titanium tetrachloride gas can also be selectively condensed and dried to be separated and removed from the titanium tetrachloride gas.
[0010]
The method for producing titanium tetrachloride according to claim 2 of the present invention is a method for producing titanium tetrachloride through a cooling step, a condensation step, and a distillation step after chlorinating titanium ore in a chloride furnace. In the step, a titanium tetrachloride slurry composed of solid impurities and liquid impurities and liquid titanium tetrachloride is brought into contact with titanium tetrachloride gas generated in the chloride furnace, and the solid impurities in the titanium tetrachloride slurry are dried and the titanium tetrachloride is dried. It is characterized in that the gas is cooled at the same time. In the cooling step, impurity components contained in the titanium tetrachloride gas are condensed and dried to be separated.
[0011]
More specifically, in the step of bringing the titanium tetrachloride gas into contact with the titanium tetrachloride slurry, the titanium tetrachloride gas is flowed vertically downward from above, and the titanium tetrachloride slurry is moved upward. Spray downward from. In this way, by bringing the titanium tetrachloride gas and the titanium tetrachloride slurry into countercurrent contact, the titanium tetrachloride gas and the titanium tetrachloride slurry are efficiently contacted, and the drying of the titanium tetrachloride slurry and the cooling of the titanium tetrachloride gas are performed. It is possible to perform it sufficiently.
[0012]
Further, in the step of contacting the titanium tetrachloride gas with the titanium tetrachloride slurry, the titanium tetrachloride gas is flowed vertically downward from above, and the titanium tetrachloride slurry is sprayed downward from above. You may do it. In this way, by bringing the titanium tetrachloride gas and the titanium tetrachloride slurry into parallel contact, a solid substance in the titanium tetrachloride slurry and a fine solid residue precipitated during cooling of the titanium tetrachloride gas are efficiently collected. be able to.
[0013]
In addition, by drying the titanium tetrachloride slurry under high pressure to form fine droplets and contacting the titanium tetrachloride gas, the titanium tetrachloride slurry can be efficiently dried.
[0014]
Specifically, the four spray pressure of titanium chloride slurry is ^{5Kg / cm 2 G~30Kg / cm 2} G, by setting such a spray pressure, volume median diameter of the sprayed cooling process the droplets Can be set to 400 μm or less.
[0015]
It is also preferable that the temperature of the titanium tetrachloride gas at the outlet of the cooling step is set to be equal to or higher than the boiling point of titanium tetrachloride and equal to or lower than 250 ° C. This is for drying the titanium tetrachloride slurry by increasing the temperature of the titanium tetrachloride to a boiling point or higher and 250 ° C. or lower, without increasing the amount of niobium or aluminum chloride contained in the titanium tetrachloride gas. This is because a sufficient temperature can be maintained.
[0016]
Further, it is preferable that the titanium tetrachloride gas and the titanium tetrachloride slurry are efficiently brought into contact with each other by supplying the titanium tetrachloride gas flowing in the cooling step while swirling.
[0017]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of the present invention will be described below with reference to the drawings. In the embodiment described below, in the present invention, titanium tetrachloride gas generated in a chlorination furnace flows vertically downward from above, while titanium tetrachloride slurry flows downward from above. The present invention relates to a mode in which both are brought into countercurrent contact.
[0018]
The members, arrangements, and the like described below do not limit the present invention, but can be variously modified within the scope of the present invention.
[0019]
1 and 2 show an embodiment of the present invention. FIG. 1 is an explanatory view showing a method for producing titanium tetrachloride of the present invention, and FIG. 2 shows an example of a production apparatus used for producing titanium tetrachloride. FIG.
[0020]
The method for producing titanium tetrachloride includes a step of generating titanium tetrachloride gas in the chlorine furnace 1, a step of cooling titanium tetrachloride gas in the cooling tower 3, and a step of condensing the titanium tetrachloride gas in the condensing tower 7. And a distillation step of purifying the liquid titanium tetrachloride to obtain purified titanium tetrachloride.
[0021]
In the method for producing titanium tetrachloride of the present example, in the cooling step, titanium tetrachloride gas is brought into countercurrent contact with titanium tetrachloride slurry composed of liquid titanium tetrachloride and a solid containing solid and liquid impurities. Thus, the cooling of the titanium tetrachloride gas and the drying of the titanium tetrachloride slurry can be performed simultaneously.
[0022]
In the process of generating titanium tetrachloride gas, titanium ore and coke in a fluidized state in the chlorine furnace 1 heated to around 1000 ° C. react while flowing and contacting chlorine gas supplied from the bottom of the chlorine furnace. Titanium tetrachloride gas is generated. Titanium tetrachloride gas (including impurity gas and solid impurities, but may be simply referred to as titanium tetrachloride gas hereinafter) generated in the chlorination furnace 1 is guided to the cooling tower 3 via the connecting conduit 2. I will
[0023]
In the cooling tower 3, a step of countercurrent contact between the titanium tetrachloride gas and the titanium tetrachloride slurry is performed. In this step, the titanium tetrachloride gas is cooled, and at the same time, impurities contained in the titanium tetrachloride slurry are dried. .
[0024]
The titanium tetrachloride gas guided from the chlorination furnace 1 to the cooling tower 3 is counter-currently contacted with the titanium tetrachloride slurry sprayed from the top of the cooling tower 3 and cooled to around 200 ° C. The cooled titanium tetrachloride gas is then led to the condensation tower 7.
[0025]
The solid residue in the titanium tetrachloride slurry sprayed from the top of the cooling tower 3 is dried by contact with the high-temperature titanium tetrachloride gas introduced from the chlorination furnace 1 and deposited on the bottom of the cooling tower 3 by gravity. I do.
[0026]
The liquid titanium tetrachloride in the titanium tetrachloride slurry evaporates to titanium tetrachloride gas, and is led to the condensing tower 7 together with the titanium tetrachloride gas introduced from the chlorination furnace 1.
[0027]
It is preferable that the outlet temperature of the titanium tetrachloride gas cooled in the cooling tower 3 is controlled in a range from the boiling point of titanium tetrachloride to 250 ° C. Preferably, the temperature is controlled in the range of 150 ° C to 200 ° C.
[0028]
This is because, when the outlet temperature of the titanium tetrachloride gas exceeds 200 ° C., the amount of niobium and aluminum chlorides contained in the titanium tetrachloride gas brought into the condensing tower 7 increases, and condensing in the process. This is because the concentration of niobium or aluminum in the recovered titanium tetrachloride increases, which is not preferable.
[0029]
Further, if the temperature of the titanium tetrachloride gas at the outlet of the cooling tower 3 is controlled to 150 ° C. or less, the drying of the titanium tetrachloride slurry in the cooling tower 3 becomes insufficient, and the white smoke generated when the dried residue is treated with water. Cause
[0030]
For this reason, as described above, it is preferable to control the outlet temperature of the titanium tetrachloride gas to be in a temperature range of 150 ° C. to 200 ° C., and it is preferable to control the outlet temperature to be as constant as possible.
[0031]
In order to control the outlet temperature of the titanium tetrachloride gas to be constant, a facility that continuously detects the outlet temperature of the cooling tower 3 and automatically controls the spray amount of the titanium tetrachloride slurry supplied to the cooling tower 3 This can be achieved by using specifications.
[0032]
In order to adjust the spray amount of the titanium tetrachloride slurry, the titanium tetrachloride slurry supply device 9 may be configured, for example, as described below. Hereinafter, the titanium tetrachloride slurry supply device 9 provided in the cooling tower 3 will be described. The titanium tetrachloride slurry supply device 9 includes a supply pipe (not shown) and a spray nozzle connected to the supply pipe. The titanium tetrachloride slurry is supplied to the supply pipe from the distillation step via a pump as a transfer means and a transfer pipe.
[0033]
The titanium tetrachloride slurry is sprayed from the spray nozzle of the titanium tetrachloride slurry supply device 9 toward the flow of the titanium tetrachloride gas rising in the cooling tower 3. A plurality of titanium tetrachloride slurry supply devices 9 are provided, and titanium tetrachloride slurry is sprayed from spray nozzles of each titanium tetrachloride slurry supply device 9.
[0034]
Since the optimum flow rate for each spray nozzle is configured to be different from each other, the spray amount of the titanium tetrachloride slurry is selected by selecting the optimum spray nozzle according to the titanium tetrachloride gas flow rate guided from the chlorination furnace 1. It can be adjusted suitably.
[0035]
For example, during nighttime when the amount of titanium tetrachloride gas generated is large, each titanium tetrachloride slurry supply device 9 equipped with a spray nozzle capable of supplying a large flow rate of titanium tetrachloride slurry is used, and the amount of titanium tetrachloride gas generated is reduced. In a small daytime, each titanium tetrachloride slurry supply device 9 provided with a spray nozzle for supplying a small flow rate of titanium tetrachloride slurry is selectively used.
[0036]
The selection and switching of the spray nozzle are performed manually or automatically. In the case of performing the automatic operation, for example, it is achieved by disposing a control device between the titanium tetrachloride slurry accumulating portion and each titanium tetrachloride slurry supply device 9.
[0037]
The control device is equipped with a control unit and a program for executing a process of adjusting the supply amount of titanium tetrachloride slurry to each titanium tetrachloride slurry supply device 9 according to the outlet temperature of the titanium tetrachloride gas. Then, according to the program, the presence or absence of the slurry supply to each titanium tetrachloride slurry supply device 9 and the supply amount are adjusted. In addition, in addition to the outlet temperature of the titanium tetrachloride gas, the spray nozzle is selected in advance according to the amount of the titanium tetrachloride gas generated in the chlorine furnace 1 and a predetermined time zone, and the titanium tetrachloride slurry is prepared. The supply amount may be adjusted.
[0038]
In this way, an appropriate amount of titanium tetrachloride slurry is sprayed on the cooling tower 3 in accordance with the amount of titanium tetrachloride gas discharged from the chloride furnace 1, cooling the titanium tetrachloride gas and drying the titanium tetrachloride slurry. Is performed in a well-balanced manner, and the outlet temperature of the titanium tetrachloride gas is kept constant.
[0039]
If the unused titanium tetrachloride slurry supply device 9 is exposed to a high-temperature titanium tetrachloride gas in the cooling tower 3 as it is, solids contained in the titanium tetrachloride slurry remaining in the spray nozzle or the supply pipe are obtained. In some cases, the slurry may be dried and the spray nozzle or the supply pipe may be blocked and slurry spraying may not be resumed.
[0040]
For this reason, it is preferable that an inert gas such as a nitrogen gas is always passed through the unused titanium tetrachloride slurry supply device 9. Thereby, the blockage of the spray nozzle and the supply pipe can be prevented.
[0041]
Alternatively, after spraying the titanium tetrachloride slurry, purified titanium tetrachloride formed through the distillation step may be supplied in a short time to wash the spray nozzle and the supply pipe. Alternatively, a drain removal unit may be provided in the supply pipe to periodically remove the stagnation in the supply pipe.
[0042]
Further, when the titanium tetrachloride slurry is not being supplied, the titanium tetrachloride slurry supply device 9 may be retracted out of the cooling tower 3, which is one of effective means for preventing nozzle blockage. is there. In this case, it is preferable to provide a storage section for the titanium tetrachloride slurry supply device 9 and to position the titanium tetrachloride slurry when the titanium tetrachloride slurry is not supplied.
[0043]
When retracting the titanium tetrachloride slurry supply device 9 to the storage section, external air may enter the cooling tower 3 with the movement of the titanium tetrachloride slurry supply device 9 using a gate valve or a seal member. Alternatively, it is preferable to prevent the titanium tetrachloride gas in the cooling tower 3 from leaking to the outside. In addition, by adopting such a configuration, the spray nozzle is prevented from coming into contact with the high-temperature titanium tetrachloride gas, which is also effective in preventing the spray nozzle from being blocked.
[0044]
Various types of spray nozzles can be used as the spray nozzle of the titanium tetrachloride slurry supply device 9. However, from the viewpoint of sufficiently drying the titanium tetrachloride slurry, fine droplets can be obtained as much as possible, and furthermore, clogging is prevented. It is desirable to select a suitable spray nozzle.
[0045]
Further, it is preferable to select a spray nozzle having a characteristic that the particle diameter of the spray droplets is hard to change regardless of the supply amount of the titanium tetrachloride slurry. Further, it is preferable to use a spray nozzle in which the sprayed titanium tetrachloride slurry has fine droplets and can secure a high flow rate.
[0046]
The titanium tetrachloride slurry sprayed from the spray nozzle has a spray angle of 30 ° to 100 °, preferably 50 ° to 90 °, so that the titanium tetrachloride slurry collides with the inner wall of the cooling tower 3. It is also suitable for preventing solid matter from adhering to the inner surface of the cooling tower.
[0047]
The droplets of the titanium tetrachloride slurry sprayed from the top of the cooling tower 3 are preferably made finer from the viewpoint of sufficient drying, to increase the specific surface area, and to increase the contact area with the high-temperature gas. . Specifically, the volume median diameter is preferably 400 μm or less, more preferably 300 μm or less. However, it is necessary to reduce the diameter of the spray nozzle in order to generate excessively fine droplets, which may result in blockage of the nozzle. Therefore, it is better to select a nozzle having a lower limit of about several tens μm. Realistic. A general spray nozzle for spray drying can be used as the spray nozzle, but it is preferable to select a material having abrasion resistance in order to use a solid slurry as a spray medium.
[0048]
In order to spray the slurry of the fine droplets, it is important to select an appropriate back pressure in addition to reducing the diameter of the spray nozzle. In the present invention, it is preferable that the back pressure and ^{5Kg / cm 2 G~30Kg / cm 2} G or so. By selecting such a back pressure, fine droplets of the titanium tetrachloride slurry as described above can be generated.
[0049]
On the other hand, while the titanium tetrachloride gas guided from the chlorination furnace 1 to the cooling tower 3 is cooled, chloride gas components such as iron, aluminum, niobium or manganese contained in the titanium tetrachloride gas are also condensed and dried. And settles at the bottom of the cooling tower 3. Fine particles such as ore and coke contained in the titanium tetrachloride gas discharged from the chlorination furnace 1 are simultaneously settled and separated.
[0050]
The dried residue deposited on the bottom of the cooling tower 3 is extracted out of the system, and then treated with water in the solid residue treatment equipment 8. The dried residue is intermittently extracted from the system by a powder cutting device (not shown) provided at the bottom of the cooling tower 3.
[0051]
When the titanium tetrachloride gas is introduced into the cooling tower 3, the titanium tetrachloride gas is introduced in a direction obliquely perpendicular to the circumference of the cooling tower 3 to form a swirling upward flow in the cooling tower 3. You may do it.
[0052]
As described above, by swirling the titanium tetrachloride gas, the titanium tetrachloride gas and the liquid titanium tetrachloride slurry can be more uniformly heat-exchanged when the titanium tetrachloride slurry is sprayed. The cooling of the gas and the drying of the titanium tetrachloride slurry can be suitably performed simultaneously.
[0053]
Further, by forming such a swirling flow, it is also possible to suppress the residue in the titanium tetrachloride gas from growing on the inner wall of the cooling tower 3.
[0054]
In order to more efficiently cool the titanium tetrachloride gas, a jacket is provided around the cooling tower 3, a cooling gas is flowed there, the outer wall temperature is maintained at 200 ° C. to 400 ° C., and the cooling tower 3 is cooled. Cooling from the surroundings may be promoted.
[0055]
The titanium tetrachloride gas from which the impurity components have been removed in the cooling tower 3 is led to the condensing tower 7 and cooled to a temperature lower than the boiling point of titanium tetrachloride to recover liquid titanium tetrachloride. The liquid titanium tetrachloride may be called crude titanium tetrachloride because it contains some solid impurities and liquid impurities.
[0056]
Cooled liquid titanium tetrachloride is sprayed from the top of the condensation tower 7. The titanium tetrachloride gas introduced into the condensing tower 7 is contacted with the cooled liquid titanium tetrachloride and heat-exchanged to obtain a liquid crude titanium tetrachloride.
[0057]
In the condensing tower 7, the titanium tetrachloride gas is cooled by spraying the liquid titanium tetrachloride as described above and by additionally providing a water cooling jacket or the like. The crude titanium tetrachloride condensed in the condensing tower 7 is sent to a distillation step. The remaining gas from which the titanium tetrachloride gas has been condensed and removed in the condensing tower 7 is guided to an exhaust gas treatment facility for treatment.
[0058]
The crude titanium tetrachloride sent to the distillation step is passed through a rectification column (not shown) to remove impurities and become purified titanium tetrachloride. On the other hand, impurities separated during purification are by-produced in the form of titanium tetrachloride slurry. This titanium tetrachloride slurry is returned to the cooling tower 3 and spray-dried as described above.
[0059]
In addition, a gas cyclone 5 may be interposed between the cooling tower 3 and the condensing tower 7 via the conduits 4 and 6. By providing the gas cyclone 5, it is possible to effectively remove solids and impurities contained in the titanium tetrachloride gas discharged from the cooling tower 3.
[0060]
That is, while passing through the cooling tower 3, most of the solids and impurities precipitated during cooling of the titanium tetrachloride gas generated in the chlorination furnace 1 are settled and separated. However, since the titanium tetrachloride gas flows upward from below in the cooling tower 3, when the resistance of the flow of the titanium tetrachloride gas is higher than the gravity, the precipitated impurities do not settle and the cooling tower 3 To the condensing tower 7 downstream of.
[0061]
The fine residue brought into the condensing tower 7 is led to a distillation step as crude titanium tetrachloride together with liquefied titanium tetrachloride and purified. In the distillation step, the fine residue is separated as a titanium tetrachloride slurry. Therefore, if the amount of the fine residue brought into the condensing tower 7 increases, the amount of the titanium tetrachloride slurry dried in the cooling tower 3 also increases. become. For this reason, it is preferable to discharge the above-mentioned fine particle residue outside the system as much as possible before entering the condensation tower 7.
[0062]
Interposing the gas cyclone 5 between the cooling tower 3 and the condensing tower 7 is effective for separating and removing fine particles contained in the titanium tetrachloride gas discharged from the cooling tower 3, and thereby, Since the amount of the residue circulating through the inside can be reduced, a favorable situation can be brought about in which the amount of the titanium tetrachloride slurry to be treated can also be reduced.
[0063]
In the case where the treatment of the titanium tetrachloride slurry is more problematic than the temperature control of the titanium tetrachloride gas due to variations in the type of ore and the process, the titanium tetrachloride gas generated in the chlorine furnace 1 is supplied to the cooling tower 3. It is preferable that the slurry flows downward from above and that the titanium tetrachloride slurry also flows downward from above and that the two be brought into parallel contact.
[0064]
That is, by contacting the high-temperature titanium tetrachloride gas and the titanium tetrachloride slurry in co-current, solids in the titanium tetrachloride slurry and fine solid residues precipitated during cooling of the titanium tetrachloride gas are removed from the cooling tower. 3 can be efficiently recovered at the bottom. Therefore, it is possible to suppress the fine particles from flowing to the condensing tower 7 located downstream of the cooling tower 3 and to suppress the amount of the residues remaining in the system.
[0065]
【Example】
According to the production method of the present invention, titanium tetrachloride was produced.
15000 L / min of chlorine gas was supplied to the chlorine furnace, and titanium tetrachloride slurry was sprayed from the top of the cooling tower in the cooling step. The spray amount of the titanium tetrachloride slurry was controlled automatically so that the cooling tower outlet temperature was kept constant at around 200 ° C.
[0066]
As a result, the temperature could be controlled within a range of ± 10 ° C. with respect to the target temperature. The residue collected at the bottom of the cooling tower was in a good dry state, and almost no white smoke was generated during the water treatment.
[0067]
【The invention's effect】
As described above, according to the method for producing titanium tetrachloride of the present invention, the titanium tetrachloride gas and the atomized titanium tetrachloride slurry are brought into countercurrent or cocurrent contact with each other in the cooling tower, whereby tetrachloride is produced. The cooling of the titanium gas and the drying of the titanium tetrachloride slurry can be performed simultaneously and stably.
[Brief description of the drawings]
FIG. 1 is an explanatory view showing a method for producing titanium tetrachloride of the present invention.
FIG. 2 is an explanatory view showing an example of a production apparatus used for producing titanium tetrachloride.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Chlorination furnace 2 Connection conduit 3 Cooling tower 4 Conduit 5 Gas cyclone 6 Conduit 7 Condensing tower 8 Solid residue treatment equipment 9 Titanium tetrachloride slurry supply equipment S Titanium tetrachloride production equipment

Claims (10)

In a method of producing titanium tetrachloride through chlorination of titanium ore in a chlorination furnace, followed by a cooling step, a condensation step, and a distillation step,
A step of contacting a titanium tetrachloride slurry composed of solid impurities, liquid impurities and liquid titanium tetrachloride with the titanium tetrachloride gas generated in the chloride furnace in the cooling step. . In a method of producing titanium tetrachloride through chlorination of titanium ore in a chlorination furnace, followed by a cooling step, a condensation step, and a distillation step,
In the cooling step, a titanium tetrachloride slurry composed of solid impurities, liquid impurities, and liquid titanium tetrachloride is brought into contact with titanium tetrachloride gas generated in the chloride furnace, and drying of the solid impurities in the titanium tetrachloride slurry is performed. A method for producing titanium tetrachloride, characterized by simultaneously cooling titanium chloride gas. 3. The method for producing titanium tetrachloride according to claim 1, wherein in the cooling step, an impurity component contained in the titanium tetrachloride gas is condensed and dried. In the step of contacting the titanium tetrachloride gas and the titanium tetrachloride slurry, flowing the titanium tetrachloride gas vertically downward from above and spraying the titanium tetrachloride slurry downward from above. The method for producing titanium tetrachloride according to claim 1 or 2, wherein In the step of contacting the titanium tetrachloride gas with the titanium tetrachloride slurry, flowing the titanium tetrachloride gas vertically downward from above and spraying the titanium tetrachloride slurry downward from above. The method for producing titanium tetrachloride according to claim 1 or 2, wherein The method for producing titanium tetrachloride according to any one of claims 1 to 5, wherein the titanium tetrachloride slurry is sprayed under high pressure and brought into contact with the titanium tetrachloride gas. The four manufacturing method of titanium tetrachloride according to any one of claims 1 to 6 the spray pressure of titanium chloride slurry, characterized in that a ^{5Kg / cm 2 G~30Kg / cm 2} G. The method for producing titanium tetrachloride according to any one of claims 1 to 7, wherein the volume median diameter of the droplets sprayed in the cooling step is 400 µm or less. The method for producing titanium tetrachloride according to any one of claims 1 to 8, wherein the temperature of the titanium tetrachloride gas at the outlet of the cooling step is set to be not less than the boiling point of titanium tetrachloride and not more than 250 ° C. 10. The method for producing titanium tetrachloride according to claim 1, wherein the titanium tetrachloride gas flowing in the cooling step is supplied while swirling.

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