JP2019163185A - Method for producing TiCl4 or sponge titanium - Google Patents

Abstract

To provide a method for producing TiClthat is capable of further enhancing the purity of TiClafter purified by distillation.SOLUTION: A method for producing TiClwith high purity is provided which comprises a step of generating TiClin a chlorination reaction furnace, a step of distilling the generated TiCl, and a step of separating the distilled TiClby sedimentation in order to separate and remove ZrCl, which is a main impurity.SELECTED DRAWING: Figure 2

Description

The present invention relates to a method for producing TiCl ₄ or sponge titanium. More specifically, the present invention relates to a method for producing TiCl ₄ or titanium sponge with improved purity.

TiCl ₄ is widely used as a material for titanium metal, titanium oxide, or a raw material for electronic materials. TiCl ₄ is produced by putting titanium mineral, coke, and chlorine gas into a reaction furnace. The crude TiCl ₄ obtained at this stage contains other impurities. Therefore, the impurity component is removed by sending it to a distillation purification facility. Patent Document 1 discloses that sedimentation of undissolved impurities is promoted in a stationary state while crude TiCl ₄ is temporarily stored in a storage tank before being sent to a distillation purification facility.

After distillation purification, it is shipped as liquid TiCl ₄ and can be used as a raw material for titanium oxide, sponge titanium and the like. Sponge titanium is further processed into a titanium ingot or the like, and further processed into a sputtering target or the like, which can be used for manufacturing semiconductor components.

JP 2009-46337 A

When producing titanium sponge, 4 t of TiCl ₄ is required to obtain 1 t of sponge titanium. Therefore, when the entire amount of impurities contained in TiCl ₄ is taken into titanium sponge, it is concentrated four times. Therefore, reduction of impurities contained in TiCl ₄ is indispensable for improving the quality of sponge titanium. Therefore, it is desirable to reduce impurities as much as possible at the stage of manufacturing TiCl ₄ . Since ZrCl ₄ and TiCl ₄ have different boiling points, the content of ZrCl ₄ can be reduced by the distillation purification.

However, a small amount of ZrCl ₄ still remains after distillation purification. Particularly in the field of semiconductors, higher purity is required. Therefore, it is necessary to further reduce ZrCl ₄ . On the other hand, if the existing equipment is changed significantly, the initial cost will be increased. Therefore, an object of the present invention is to provide a method for further reducing ZrCl ₄ by a simple method in TiCl ₄ after distillation purification.

The present inventors have studied intensively, when the temperature of the tank that stores the TiCl ₄ after distillation is in the specific temperature range, at the bottom of the tank, found that the sediment occurs. When the sediment was analyzed for components, it contained ZrCl ₄ . Therefore, a way that sedimentation of ZrCl ₄ from TiCl _4, when it is possible to further reduce the inventors thought.

Based on the above findings, the present invention includes the following inventions.
(Invention 1)
A method for producing TiCl ₄ , comprising:
Producing TiCl ₄ in a chlorination reactor;
Distilling the produced TiCl ₄ ;
Settling and separating the distilled TiCl ₄ and settling impurities;
Manufacturing method of TiCl _4, including.
(Invention 2)
A method for producing TiCl _{4 according} to invention 1, comprising:
The impurities include at least ZrCl ₄ ;
ZrCl ₄ concentration before after distillation and sedimentation is 10 mass ppb~200 mass ppb, ZrCl ₄ concentration after sedimentation is less than 7 mass ppb, a manufacturing method of TiCl _4.
(Invention 3)
A method for producing TiCl _{4 according} to any one of inventions 1 and 2,
The method for producing TiCl ₄ , wherein the settling step includes maintaining the temperature of the settling tank at −10 ° C. to 30 ° C.
(Invention 4)
A method for producing TiCl _{4 according} to any one of inventions 1 to 3,
Position of the outlet of the sedimentation tank is 5cm above the bottom of the settling tank, a manufacturing method of TiCl _4.
(Invention 5)
A method for producing sponge titanium comprising the method of producing TiCl _{4 according} to any one of inventions 1 to 4 as a step,
A method for producing sponge titanium, further comprising the step of reducing the TiCl ₄ with magnesium to obtain sponge titanium.

In one aspect, the present invention performs sedimentation separation after the distillation step. Thereby, the purity of TiCl ₄ after the distillation step can be further increased.

1 shows an installation for carrying out the method of the invention in one embodiment. 1 shows a settling tank for carrying out the method of the invention in one embodiment.

  Hereinafter, specific embodiments for carrying out the present invention will be described. The following description is intended to facilitate an understanding of the present invention. That is, it is not intended to limit the scope of the present invention.

1. Method for Producing TiCl _{4 In} one embodiment, the present invention provides a method for producing TiCl ₄ . The method includes at least the following steps:
(A) producing TiCl _{4 in a} chlorination reactor;
(B) a step of distilling the generated TiCl ₄ ;
(C) A step of precipitating and separating the distilled TiCl ₄ to precipitate impurities.
Hereinafter, each step will be specifically described.

(1) Process of producing TiCl ₄ in a chlorination reactor Titanium materials are generally produced by a crawl method. As shown in FIG. 1, in the crawl method, titanium ore, coke (130), and chlorine gas (140) are introduced into a chlorination reactor (100) to produce crude TiCl ₄ . As described above, since TiCl ₄ has a low boiling point, crude TiCl ₄ is in a gaseous state in the chlorination reactor. The vaporized crude TiCl ₄ rides on the air current and is sent to the condenser (110) and the like.

The crude TiCl ₄ sent to the condenser or the like is once cooled and becomes a liquid state. As a cooling means, heat of the crude TiCl ₄ gas may be transferred to the heat transfer fluid using a heat transfer fluid and a heat exchanger.

In addition to the vaporized crude TiCl ₄ , other chlorides (for example, ZrCl ₄ ), fine coke powder, and the like ride on the airflow and are sent together to the capacitor. Therefore, at this time, a large amount of impurities is contained. The crude TiCl _{4 in} a liquid state can be stored once in a storage tank.

(2) Step of distilling TiCl _{4 The} stored crude TiCl ₄ can be sent to the distillation column (120) for the purpose of improving the purity. Although it does not specifically limit as a means to send to a distillation tower, You may utilize a pump and piping. After being sent to the distillation column, heating is performed at an appropriate temperature according to the boiling point of TiCl ₄ , and vaporized TiCl ₄ can be recovered. The recovered TiCl ₄ can be cooled and liquefied. The distillation step may be performed only once or multiple times.

(3) Step of settling and separating TiCl _{4 In} one embodiment, the present invention may include the step of settling and separating TiCl ₄ after the distillation step. Sedimentation separation is a technique that relies on the phenomenon that particles fall gradually due to the action of gravity when solid particles with a specific gravity greater than the specific gravity of the liquid are dispersed in the fluid.

In a further embodiment, it is possible to utilize the fact that ZrCl ₄ precipitates from TiCl ₄ to become a solid and settles in a state where the liquid temperature of TiCl ₄ is controlled within a specific temperature range.

Through the distillation process, impurities contained in TiCl ₄ are reduced to the mass ppb level. Therefore, conventionally, it has not been considered that impurities can be precipitated as a solid and settled and separated in a situation where the mass has already been reduced to the ppb level.

(3-1) Structure and Condition of Sedimentation Separation Tank FIG. 2 shows the structure of a tank (200) that performs sedimentation separation in one embodiment. The TiCl ₄ liquid can be introduced into the tank through the introduction port (240).

The temperature in the tank (or the temperature of the TiCl ₄ liquid) is not particularly limited, but may be adjusted to −10 ° C. to 30 ° C. (more preferably 5 ° C. or less). When the temperature is lower than −10 ° C., the temperature becomes close to the melting point (−24 ° C.) of TiCl ₄ , and the viscosity increases and handling becomes difficult. On the other hand, if it exceeds 30 ° C., the amount of ZrCl ₄ deposited may decrease, and as a result, the amount of ZrCl ₄ precipitated may decrease.

The position (210) of the delivery port of the settling tank (200) is preferably 5 cm or more from the bottom of the settling tank. This is because if the thickness is less than 5 cm, the precipitated impurities (230) may be delivered together with TiCl ₄ . The upper limit of the position of the delivery port is not particularly limited, but a position at least below the liquid surface of TiCl ₄ is more preferable.

About the liquid feeding amount from a sedimentation tank, 1-20 L / min is preferable. Within this range, highly pure TiCl ₄ can be fed more efficiently. If it is less than 1 L / min, the efficiency of liquid feeding tends to be insufficient. On the other hand, if it exceeds 20 L / min, the settled impurities may be sent out together with TiCl ₄ .

Also, as sending the TiCl ₄ from sedimentation tank, the position of the liquid surface of TiCl ₄ (220) will decrease. However, the liquid level in the settling tank is preferably maintained at 50 cm or more from the bottom of the settling tank. This is because if it is less than 50 cm, the precipitated impurities are likely to be mixed. Although it does not specifically limit about an upper limit, Typically, it is less than the height of a sedimentation tank.

(3-2) Effect of sedimentation separation The sedimentation separation described above can further reduce the amount of impurities mixed in TiCl ₄ . For example, when the impurity is ZrCl ₄ , the ZrCl ₄ concentration after distillation and before sedimentation separation is 10 mass ppb to 200 mass ppb, while the ZrCl ₄ concentration after sedimentation separation is reduced to 7 mass ppb or less. Can do.

2. In one embodiment, the present invention provides a method for producing sponge titanium.
The method includes the following steps.
(A) producing TiCl ₄ in a chlorination reactor;
(B) distilling the generated TiCl ₄ ;
(C) settling and separating the distilled TiCl ₄ and settling impurities;
(D) A step of reducing the TiCl ₄ with magnesium to obtain sponge titanium.

  Said (a)-(c) can each be implemented by the same or similar method as (A)-(C) mentioned above.

About said (d), it can implement by a well-known method. For example, molten magnesium may be charged into the reduction reaction vessel (150), and TiCl ₄ may be further charged. Thereby, chlorine on the TiCl ₄ side can react with Mg to form MgCl ₂ . On the other hand, sponge titanium is produced in the reduction reaction vessel by removing chlorine from TiCl ₄ . Sponge titanium is collected and can be shipped as a product after removing the periphery with many impurities. The sponge titanium may be further pulverized and cast into a titanium ingot or the like.

(Example 1) (Relationship between ZrCl ₄ concentration before and after sedimentation separation and temperature of TiCl ₄ liquid)
The TiCl ₄ solution that had undergone the chlorination reaction and the distillation step was stored in a tank. Then, a TiCl ₄ liquid having a height of about 1 cm was recovered from the bottom of the tank. The recovered TiCl ₄ liquid was subjected to sedimentation at temperatures of −10 ° C. (Invention Example 1), 5 ° C. (Invention Example 2), 30 ° C. (Invention Example 3), and 40 ° C. (Invention Example 4).
Then, before and after settling, the Zr concentration in the TiCl ₄ solution in the sedimentation tank was measured (and, in terms of ZrCl ₄ concentration). For the measurement of the Zr concentration, ICP-MS (manufacturer name: Hitachi High-Tech Science Co., Ltd., model number: SPQ9700) was employed. The results are shown in Table 1.

Before the sedimentation separation, the concentration of ZrCl ₄ contained in the TiCl ₄ liquid was at least 50 mass ppb. Subsequently, ZrCl ₄ could be reduced by sedimentation at an appropriate temperature. In particular, when the temperature was 30 ° C. or lower, the ZrCl ₄ concentration could be significantly reduced.

(Example 2) (Chemical analysis of sediment)
The sediment obtained in Invention Example 2 of Example 1 was subjected to chemical analysis.
More specifically, the sediment was collected, filtered and subjected to chemical analysis. As an analysis method, ICP-OES (Hitachi High-Tech Science Model SPS3000) was adopted. After calculating content about each element, it converted into content of the specific compound. The analysis results are shown below.

As shown in the above table, most of the sediment was occupied by ZrCl ₄ . Therefore, it shows that ZrCl ₄ as an impurity could be separated from the TiCl ₄ liquid.

(Example 3) (Relationship between ZrCl ₄ concentration after sedimentation and height of delivery port)
The TiCl ₄ liquid was settled and separated at 5 ° C., and the TiCl ₄ liquid was pumped out from the outlet of the settling tank. At this time, the distance from the bottom of the tank to the delivery port was changed. The distance was 5 cm (Invention Example 5), 10 cm (Invention Example 6), and 20 cm (Invention Example 7). Then, the Zr concentration contained in the TiCl ₄ liquid recovered through the delivery port was measured (and converted to the ZrCl ₄ concentration). For the measurement of the Zr concentration, the same analytical method and analytical instrument as in Example 1 were used. The results are shown in Table 3.

When the distance from the bottom of the tank to the delivery port was at least 5 cm or more, the ZrCl ₄ concentration of the TiCl ₄ solution recovered via the delivery port was 7 mass ppb or less.

  The specific embodiments of the present invention have been described above. The said embodiment is only a specific example of this invention, and this invention is not limited to the said embodiment. For example, the technical features disclosed in one of the above embodiments can be provided in other embodiments. Moreover, about a specific method, it is also possible to replace a part process with the order of another process, and you may add an additional process between two specific processes. The scope of the invention is defined by the claims.

100 chloride reactor 110 capacitor 120 distillation tower 130 titanium ore and coke 140 Chlorine gas 150 reduction reactor 200 liquid level 230 precipitated impurities 240 settling tank inlet settling tank 210 feed port 220 TiCl ₄

Claims (5)

A method for producing TiCl ₄ , comprising:
Producing TiCl ₄ in a chlorination reactor;
Distilling the produced TiCl ₄ ;
Settling and separating the distilled TiCl ₄ and settling impurities;
Manufacturing method of TiCl _4, including. A method for producing TiCl _{4 according} to claim 1,
The impurities include at least ZrCl ₄ ;
ZrCl ₄ concentration before after distillation and sedimentation is 10 mass ppb~200 mass ppb, ZrCl ₄ concentration after sedimentation is less than 7 mass ppb, a manufacturing method of TiCl _4. A TiCl ₄ production method according to any one of claims 1-2,
The method for producing TiCl ₄ , wherein the settling step includes maintaining the temperature of the settling tank at −10 ° C. to 30 ° C. A TiCl ₄ production method according to any one of claims 1 to 3,
Position of the outlet of the sedimentation tank is 5cm above the bottom of the settling tank, a manufacturing method of TiCl _4. A method for producing titanium sponge, comprising the method for producing TiCl _{4 according} to claim 1 as a process,
A method for producing sponge titanium, further comprising the step of reducing the TiCl ₄ with magnesium to obtain sponge titanium.