JP2020099841A - Crystal manufacturing method and crystal manufacturing device - Google Patents

Abstract

To provide a crystal manufacturing method and a crystal manufacturing device, that allow crystal of a desired particle size to be efficiently manufactured.SOLUTION: There is provided a method for manufacturing crystal including: a crystallization process in which at least two kinds of raw material compounds having high solubility to a prescribed solute are supplied to a reaction vessel in a state that at least one kind of the raw material compounds is dissolved in the solute, in order to cause a reaction of the raw material compounds in a mixture and crystallize crystalline compounds having poor solubility to the solute; a classification process in which crystal of the crystalline compounds in the mixture obtained in the crystallization process are classified into crystal of a large particle size side or crystal of a small particle size side, according to precipitation separation; and a condensation process in which the mixture containing crystal of the small particle size side, that are obtained in the classification process, is filtered by an ultrafiltration membrane, and condensed by removing the solute in the mixture. In the method for manufacturing crystal, the mixture containing crystal of the large particle size side that are obtained in the classification process, and the condensed mixture containing crystal of the small particle size side that are obtained in the condensation process, are mixed with the mixture of the crystallization process.SELECTED DRAWING: Figure 1

Description

The present invention relates to a crystal manufacturing method and a crystal manufacturing apparatus.

Conventionally, a crystalline compound is produced in a predetermined reaction solution and crystallized in the solution, and then the crystal is grown to a desired particle size, and the obtained crystal is used as a product or a raw material of the product. May be used.
For example, in a lithium-ion secondary battery, an oxide containing a cobalt atom, a lithium atom, etc. is used as a positive electrode active material, and in the production of the oxide, a hydroxide containing a nickel atom, a cobalt atom, a manganese atom is used. It is known that a crystal of a substance is used as a precursor (Patent Document 1). Then, in the production of crystals of the hydroxide, nickel, cobalt, in the mixed solution obtained by adding sodium hydroxide to the sulfate of at least one element selected from the group consisting of manganese, The compound is reacted to crystallize a hydroxide of the element which is poorly soluble in water, and then the crystal is grown to a desired particle size to obtain a desired hydroxide crystal. It has gained.

JP, 2018-22568, A

Here, in a conventional crystal production method for obtaining crystals having a desired grain size, two or more kinds of raw material compounds having good solubility in a predetermined solute are used, and at least one kind of the raw material compound is used. It is supplied to a reaction tank in a state of being dissolved in a solute, and the raw material compound is reacted in a mixed liquid containing the raw material compound and the solute to give an ion-bonding crystalline compound that is poorly soluble in the solute. Is crystallized. Then, in order to grow crystals of the crystals, the mixed solution containing the crystallized crystals is filtered by a filter to remove the solute (and by-products) in the mixed solution, and then concentrated, and then the concentrated mixture is added. The liquid was returned to the reaction tank. By allowing the solute in the mixed solution to circulate while removing the solute while reacting in the reaction tank in this way, the poorly soluble crystalline compound obtained by reacting the raw material compound in the reaction tank is added to the mixed solution. It is possible to grow a crystal that has already been crystallized as a seed crystal while suppressing crystallization as a new crystal. Then, by continuing the supply and circulation of the raw material compound, the seed crystal can be grown to a desired grain size.
However, the above-mentioned conventional crystal manufacturing method has not been able to efficiently manufacture a crystal having a desired grain size. That is, there was a problem that the initial crystals just formed by crystallization were too fine for the filter membrane of the filter and passed through the filter membrane, resulting in loss of crystals. Furthermore, when the crystal grows to the pore size of the filtration membrane, the filtration membrane is clogged with the crystal and the concentration efficiency of the mixed solution decreases, and the filtration membrane must be replaced during the crystal production. was there.

Therefore, an object of the present invention is to provide a crystal manufacturing method capable of efficiently manufacturing a crystal having a desired particle size, and a crystal manufacturing apparatus capable of efficiently manufacturing a crystal having a desired particle size. To do.

The present invention is as follows.
[1] Two or more raw material compounds having good solubility in a predetermined solute are supplied to a reaction tank in a state where at least one raw material compound is dissolved in the solute, In a mixed solution containing a raw material compound and the solute, the raw material compound is reacted to crystallize a crystalline compound that is poorly soluble in the solute, a crystallization step,
Crystals of the crystalline compound in the mixed solution obtained in the crystallization step, the large particle size crystals and the small particle size crystals, a classification step of classifying by sedimentation separation,
A mixed solution containing crystals on the small particle size side of the crystalline compound obtained in the classification step is filtered with an ultrafiltration membrane to concentrate solutes in the mixed solution, and a concentration step,
Have
A mixed solution containing crystals on the large particle size side of the crystalline compound obtained in the classification step, and a concentrated mixed solution containing crystals on the small particle size side of the crystalline compound obtained in the concentration step, A method for producing a crystal, which comprises mixing with the mixed solution in the crystallization step.
[2] A mixed solution containing crystals on the small particle size side of the crystalline compound obtained in the classifying step, which is obtained by separating at least a part of the concentrated mixed solution obtained in the concentrating step and before filtering in the concentrating step. The method for producing a crystal according to [1] above, further comprising an intermediate storage step of temporarily storing the mixed solution and supplying the stored mixed solution to the ultrafiltration membrane.
[3] When the crystals of the mixed solution containing the crystals of the crystalline compound obtained by the classification step on the large particle size side have a predetermined particle size or more, the large particles of the crystalline compound obtained by the classification step The method for producing a crystal according to [1] or [2] above, which has a recovery step of recovering at least a part of a mixed solution containing crystals on the radial side.
[4] The solute is water,
The raw material compound is a metal salt of at least one element selected from the group consisting of nickel, cobalt, and manganese, and a hydroxide of an alkali metal or an alkaline earth metal,
The method for producing a crystal according to any one of [1] to [3] above, wherein the crystalline compound is a hydroxide of a metal element of a metal salt in the raw material compound.
[5] The solute is water,
The raw material compound is a sulfated product of at least one element selected from the group consisting of nickel, cobalt, and manganese, and sodium hydroxide,
The method for producing a crystal according to any one of [1] to [4] above, wherein the crystalline compound is a hydroxide of a metal element of a sulfate compound in the raw material compound.
[6] The method for producing a crystal according to any one of the above [1] to [5], wherein in the classification step, classification is performed by a liquid cyclone.
[7] A reaction tank having a raw material supply section for supplying a raw material compound,
Classifying the crystals in the mixed solution containing crystals, small particle size discharge part where the mixed solution containing crystals on the small particle size side is discharged, and large particle discharging the mixed solution containing crystals on the large particle size side A settling separator having a diameter discharge part,
A first line connecting the reaction tank and the sedimentation separator;
While having an ultrafiltration membrane, having a concentrated solution discharge part for discharging a mixed solution containing crystals on the small particle size side, which is concentrated by the ultrafiltration membrane, and a filter,
A second line connecting the small particle size discharge part of the sedimentation separator and the filter;
A third line connecting the large particle size discharge part of the sedimentation separator and the reaction tank;
A fourth line connecting the concentrated liquid discharge part of the filter and the reaction tank,
An apparatus for producing crystals, comprising:
[8] The crystal manufacturing apparatus according to the above [7], which has an intermediate tank provided in the middle of the second line and connected to a fifth line branched from the fourth line in the middle of the fourth line.
[9] The crystal manufacturing apparatus according to the above [7] or [8], which has a recovery line provided in the middle of the third line and capable of recovering a mixed solution of crystals on the large grain size side.

According to the present invention, it is possible to provide a crystal manufacturing method capable of efficiently manufacturing a crystal having a desired particle size and a crystal manufacturing apparatus capable of efficiently manufacturing a crystal having a desired particle size.

It is a schematic diagram showing an example of a crystal manufacturing device concerning a 1st embodiment of the present invention. It is a schematic diagram showing an example of a crystal manufacturing device concerning a 2nd embodiment of the present invention.

<Crystal production method>
The crystal manufacturing method according to the first embodiment of the present invention will be exemplified and described with reference to FIG. 1. FIG. 1 shows a crystal manufacturing apparatus suitable for use in the crystal manufacturing method according to the first embodiment.

In the crystal production method of the present embodiment, two or more raw material compounds having good solubility in a predetermined solute are supplied to the reaction tank 1 in a state where at least one raw material compound is dissolved in the solute. A crystallization step of reacting the raw material compound in a mixed liquid containing the raw material compound and the solute in the reaction tank 1 to crystallize a crystalline compound that is poorly soluble in the solute. ,
Crystals of the crystalline compound in the mixed solution obtained in the crystallization step, the large particle size crystals and the small particle size crystals, a classification step of classifying by sedimentation separation,
A mixed solution containing crystals on the small particle size side of the crystalline compound obtained in the classification step is filtered with an ultrafiltration membrane to concentrate solutes in the mixed solution, and a concentration step,
Have
A mixed solution containing crystals on the large particle size side of the crystalline compound obtained in the classification step, and a concentrated mixed solution containing crystals on the small particle size side of the crystalline compound obtained in the concentration step, It is characterized in that it is mixed with the mixed solution in the crystallization step.
By doing so, it is possible to efficiently produce crystals having a desired grain size.
Specifically, in the conventional crystal manufacturing method, there is a problem that the crystals in the initial stage of manufacturing, which have just been crystallized and crystallized, are too fine with respect to the filter membrane of the filter and pass through the filter membrane, resulting in crystal loss. It was Furthermore, when the crystal grows to the pore size of the filtration membrane, the filtration membrane is clogged with the crystal and the concentration efficiency of the mixed solution decreases, and the filtration membrane must be replaced during the crystal production. was there. However, in the present embodiment, even extremely minute crystals at the initial stage of production do not pass through the ultrafiltration membrane, so that the solute of the mixed solution can be removed and concentrated without loss of crystals. .. Further, when the crystals grow to some extent, if the mixed solution containing the grown crystals is supplied to the ultrafiltration membrane, the filtration efficiency (concentration efficiency) may decrease, but in the present embodiment, the concentration is increased. It has a classification step before the step, and classifies the crystals on the relatively large particle size side in the mixed solution containing crystals so that the mixed solution supplied to the concentration step does not contain it. Therefore, it is possible to avoid a decrease in filtration efficiency (concentration efficiency) in the concentration step. Therefore, it is possible to efficiently grow crystals from the initial stage of production until crystals having a desired grain size are obtained.

-Crystallization step-
In the crystallization step of the present embodiment, two or more raw material compounds having good solubility in a predetermined solute are supplied to the reaction tank 1 in a state where at least one raw material compound is dissolved in the solute. The raw material compound is reacted in a mixed liquid containing the raw material compound and the solute in the reaction tank 1 to crystallize a crystalline compound that is poorly soluble in the solute. By this step, the crystallized compound can be crystallized in the reaction vessel 1 to obtain a crystal grown.
More specifically, in the crystallization step of the present embodiment, a reaction tank 1 having a raw material supply unit 11 that supplies two or more raw material compounds in a state in which at least one raw material compound is dissolved in the solute. Can be used, and the raw material compound is continuously supplied from the raw material supply unit 11. Then, the supplied raw material compounds react while being stirred in the reaction tank 1 to crystallize a crystalline compound that is poorly soluble in the solute.

The crystal produced by the production method of the present embodiment is composed of a crystalline compound, but the crystal is a mixture of two or more raw material compounds and a crystalline compound produced from the raw material compound with respect to a predetermined solute. It can be obtained by utilizing the difference in solubility. Specifically, in the mixed solution in the reaction tank 1, the raw material compound has good solubility in the solute, and thus a predetermined amount is dissolved, while the crystalline compound is poorly soluble in the solute. Since it exhibits the property, it cannot be dissolved up to the above predetermined amount and is crystallized (saturated with respect to the solute and crystallized). Therefore, in the present embodiment, “good solubility” of the raw material compound and “poor solubility” of the crystalline compound mean relative solubility of the raw material compound and the crystalline compound in a predetermined solute. ..

In the present embodiment, the reaction conditions in the crystallization step are not particularly limited, but for example, reaction conditions (temperature and concentration) such that the raw material compound is dissolved in the solute and the crystalline compound is crystallized are selected. Preferably. Further, when two or more kinds of raw material compounds react with each other to form a compound (a by-product) other than the crystalline compound, the by-product also has good solubility in the solute used. It is preferable that the reaction conditions in the crystallization step are selected such that the by-products also dissolve in the solute.
Further, the solute can be arbitrarily selected depending on the kinds of the raw material compound and the crystalline compound.

Further, the specific two or more kinds of the raw material compound, the crystalline compound, and the solute can be arbitrarily selected without particular limitation. For example, when the solute is water, the raw material compound and the crystalline Examples of the combination of compounds include the following combinations. That is, as a combination, the raw material compound is a metal salt of at least one element selected from the group consisting of nickel, cobalt, and manganese, and a hydroxide of an alkali metal or an alkaline earth metal, and the crystalline A combination in which the compound is a hydroxide of a metal element of a metal salt in the raw material compound (when the raw material compounds are 2 and 3, the crystalline compound is a mixture of hydroxides containing one element). Or a hydroxide containing a plurality of elements); a combination in which the raw material compounds are calcium hydroxide and carbon dioxide and the crystalline compound is calcium carbonate; the raw material compound is barium hydroxide A combination of sulfuric acid and a crystalline compound of barium sulfate; a combination of raw material compounds of sodium hydroxide and hydrogen chloride and a crystalline compound of sodium chloride; and the like. Also, among the above, as a combination, the raw material compound is a metal salt of at least one element selected from the group consisting of nickel, cobalt, and manganese, and a hydroxide of an alkali metal or an alkaline earth metal. And the crystalline compound is preferably a hydroxide of a metal element of a metal salt in the raw material compound, and more preferably, the raw material compound is at least one selected from the group consisting of nickel, cobalt, and manganese. Is a combination of a sulfated compound of the element and sodium hydroxide, and the crystalline compound is a hydroxide of the metal element of the sulfated compound in the raw material compound. This is because the crystal manufacturing method of the present embodiment can be suitably applied.
The crystalline compound is preferably an ionic bond compound.

In the present embodiment, the supply of the raw material compound into the reaction tank 1 is not particularly limited, but can be performed, for example, via the raw material supply unit 11 for the raw material compound, which is provided in the reaction tank 1. The raw material supply unit 11 may be provided in the same number as the types.
Further, the raw material compound to be supplied is supplied in a state (solution) in which at least one kind of raw material compound is dissolved in the solute, whereby, for example, unreacted raw material compound remains in the system without being dissolved. You can avoid that.
The raw material compound is a metal salt of at least one element selected from the group consisting of nickel, cobalt, and manganese, and an alkali metal or alkaline earth metal hydroxide, and the crystalline compound is a raw material. When the hydroxide of the metal element of the metal salt in the compound is used, the metal salt of at least one element selected from the group consisting of nickel, cobalt, and manganese is supplied to the reaction tank 1 as an aqueous solution. Is preferred.

In the present embodiment, in the crystallization step, when the number of crystals of the crystalline compound in the mixed solution in the reaction tank 1 is relatively small (when there are many solutes in the reaction system), the crystalline compound is a new one. Crystallization occurs so that crystals are formed, and it becomes difficult to crystallize on the seed crystal of the crystalline compound, and it becomes difficult to appropriately grow the crystal. Therefore, in the crystallization step, it is preferable that the amounts of the raw material compound and the solute to be supplied and the amount of the filtrate discharged in the concentration step to be described later do not significantly differ. The amount of the filtrate discharged in the concentration step with respect to the amount is preferably controlled within ±10%, more preferably within ±5%.
If the amount of the filtrate discharged in the concentration step is too large with respect to the amounts of the raw material compound and the solute, the classification efficiency in the classification step and the concentration efficiency in the concentration step may decrease.

-Classification process-
In the classification step of the present embodiment, the crystals of the crystalline compound in the mixed solution obtained in the crystallization step are separated by sedimentation, and the crystals of the crystalline compound present in the mixed solution are referred to as crystals on the large particle size side. Classify into crystals with smaller particle size. Due to this step, after the middle stage of the production in which the crystal of the crystalline compound has grown to some extent, the classification step prevents the crystal having a relatively large particle diameter in the mixed solution containing the crystal from being included in the mixed solution in the concentration step. Therefore, it is possible to avoid a decrease in filtration efficiency (concentration efficiency) in the concentration step. It should be noted that, since the crystals in the mixed solution as a whole are minute at the initial stage of production, the crystals on the large grain size side may not be sufficiently classified at the initial stage of production.

Specifically, in the classifying step, as shown in FIG. 1, the mixed solution obtained in the crystallization step is supplied to the settling separator 2 through the first line L1, and the settling separator 2 removes the mixed solution from the mixed solution. Crystals of the crystalline compound are separated by settling. The sedimentation separation is not particularly limited as long as the crystals in the mixed solution can be classified by a predetermined classification point.For example, it can be carried out by utilizing centrifugal force or gravity in the liquid, preferably by using centrifugal force. It is a hydrocyclone that performs classification. In addition, as the classification using gravity in a liquid, there is a hydrostatic method, and specifically, an upright tubular wet classifier can be used. By using the liquid cyclone, crystals can be efficiently classified.

By the way, the crystal in the present embodiment is a particle (group) having a particle size distribution in which the particle size has a certain spread, and the crystals on the large particle size side and the crystals on the small particle size side that have been classified in the classification step Similarly, each is a particle (group) having a particle size distribution with a certain spread. Specifically, the crystals on the large particle size side have a first particle size distribution on the relatively large particle size side, and the crystals on the small particle size side have a relatively small particle size relative to the first particle size distribution. It has a second particle size distribution on the diameter side, and these particles have respective particle size distributions by being classified at a predetermined classification point. In the classification step of the present embodiment, if the first particle size distribution and the second particle size distribution have relatively large and small distributions, a part of the distribution may have an overlapping range. , It is not necessary to be strictly separated at a predetermined classification point (specific particle size).

Further, in the classification step of the present embodiment, when classifying by a liquid cyclone, the classification point is the flow rate of the mixed solution supplied to the liquid cyclone, the mixed solution containing crystals on the small particle size side that are classified and discharged from the liquid cyclone. And the discharge amount of the mixed liquid containing crystals on the large grain size side can be adjusted and set. Further, when the solid content concentration of the mixed solution changes due to the manufacturing process, it is preferable to adjust the above respective amounts according to the solid content concentration of the crystal of the crystalline compound in the mixed solution obtained in the crystallization step. .. Furthermore, by adjusting the amount of each, the classification point can be adjusted depending on the initial stage, middle stage, and late stage of the production, which can facilitate efficient concentration in the concentration step.

The mixed liquid containing crystals on the large particle size side of the crystalline compound, obtained in the classification step, is discharged by the large particle size discharge part 22 of the settling separator 2 and supplied to the reaction tank 1 through the third line L3. It Further, the mixed solution containing crystals of the crystalline compound having a small particle size obtained in the classification step is discharged at the small particle size discharging portion of the settling separator 2 and supplied to the filter 3 through the second line L2. It

-Concentration step-
In the concentration step of the present embodiment, a mixed solution containing crystals of the crystalline compound on the small particle size side obtained in the classification step is filtered through an ultrafiltration membrane to remove the solute in the mixed solution and concentrate the solution. By this step, the solute in the reaction system in the reaction tank 1 can be prevented from becoming too large, and the crystalline compound crystallized in the reaction tank 1 can be appropriately crystal-grown.

Specifically, in the concentration step, as shown in FIG. 1, the mixed liquid containing the crystals of the crystalline compound having a small particle size obtained in the classification step is supplied to the filter 3 through the second line L2 and mixed. By filtering the liquid through the ultrafiltration membrane, solutes and the like pass through the ultrafiltration membrane and crystals of the crystalline compound do not pass through the ultrafiltration membrane, so that the mixed liquid is concentrated and discharged. The concentrated mixed liquid is discharged from the concentrated liquid discharge portion 31 of the filter 3 and supplied to the reaction tank 1 through the fourth line L4.

The ultrafiltration membrane used in the present embodiment may be a cross flow type or a dead end type (total amount filtration type), but the cross flow type is preferable from the viewpoint of effective concentration. Further, the ultrafiltration is preferably internal pressure filtration from the same viewpoint.

The blocking pore size of the ultrafiltration membrane is preferably 3,000 to 1,000,000, more preferably 6,000 to 100,000 in terms of molecular weight cutoff. As the ultrafiltration membrane, for example, "Microza UF" (manufactured by Asahi Kasei Corporation) or the like can be used.

In the concentration step, the filtrate obtained by filtering with an ultrafiltration membrane includes those other than the crystals of the crystalline compound that are not filtered by the ultrafiltration membrane, such as the solute in the mixed solution and the solute. Compounds and the like other than the crystalline compound produced by the reaction of the raw material compound in the state of being dissolved in
For example, when the crystalline compound is a hydroxide such as nickel, an aqueous solution containing the raw material compound and SO ₄ ²⁻ ions can be obtained as a filtrate.

-Mixed liquid after classification step and concentration step-
In the present embodiment, a mixed solution containing crystals on the large particle size side of the crystalline compound obtained in the classification step, and a concentrated mixed solution containing crystals on the small particle size side of the crystalline compound obtained in the concentration step , Are mixed with the mixed solution (reaction system) in the crystallization step. More specifically, the mixed liquid containing crystals of the crystalline compound on the large particle size side obtained in the classification step is discharged in the large particle size discharging part 22 of the settling separator 2 and passes through the third line L3. The concentrated mixed liquid supplied to the reaction tank 1 and obtained in the concentration step is discharged from the concentrated liquid discharge part 31 of the filter 3 and supplied to the reaction tank 1 through the fourth line L4, whereby the reaction It is mixed with the mixed liquid in the tank 1.
By doing so, the crystal of the crystalline compound after the classification step and the concentration step is used as a seed crystal, and the crystalline compound that can be continuously generated in the crystallization step is crystallized on the seed crystal to allow crystal growth. Can be made.

-Collection process-
In the present embodiment, when the crystals of the mixed solution containing the crystals on the large particle size side of the crystalline compound obtained by the classification step have a predetermined particle size or more, the large amount of the crystalline compound obtained by the classification step is obtained. It is preferable to have a recovery step of recovering at least a part of the mixed solution containing crystals on the particle size side. By this step, when the crystal on the large particle size side of the crystalline compound obtained by the classification step has the particle size required for production, it can be recovered without stopping production (ie, crystal production Can be done continuously).

Specifically, the mixed liquid containing crystals on the large particle size side of the crystalline compound obtained in the classification step is discharged by the large particle size discharge part 22 of the settling separator 2 and reacted through the third line L3. Although supplied to the tank 1, a recovery line L7 is provided in the middle of the third line L3, and the mixed liquid can be recovered by the recovery line L7 in the above-described predetermined case.

The particle size of the crystals of the mixed solution containing crystals on the large particle size side of the crystalline compound obtained by the classifying step means the average particle size of the crystals present in the mixed solution, for example, the classifying step. The measurement can be performed by sampling the mixed solution obtained by the method in the middle of the line. Alternatively, in the middle of the line for feeding the mixed solution, a measuring instrument for measuring the solid content concentration in-line is installed, and from the obtained solid content concentration, a calibration curve prepared in advance for the relationship between the solid content concentration and the particle size. The particle size can be determined by using

-Crystal production end process-
In the present embodiment, when the particles of the mixed solution in the reaction tank 1 are equal to or larger than a predetermined particle size, the supply of the raw material compound and each step are stopped, and the mixed solution existing in the system is recovered and filtered. By doing so, it is possible to obtain a crystal grown from the crystalline compound.

-Physical properties of mixed liquid-
In the present embodiment, the raw material compound, the crystalline compound, and the solute can be variously selected as described above, but the raw material compound is a sulfated product of at least one element selected from the group consisting of nickel, cobalt, and manganese. , Sodium hydroxide, and the crystalline compound is a hydroxide of the element of the sulfate compound in the raw material compound (hereinafter, this case is also referred to as “when the crystalline compound is a hydroxide such as nickel”). The crystal production method of the present embodiment can be preferably used for the purpose.

In the above crystallization step, the temperature of addition of the raw material compound is preferably 32° C. or higher, more preferably 40° C. or higher, from the viewpoint of suppressing crystallization of sodium sulfate, which is a by-product generated as a result of the reaction. is there.
In the crystal manufacturing method of the present embodiment, the temperature of the mixed solution containing sodium sulfate is preferably 32°C or higher.

Hydroxide in the crystal production method of the present embodiment, the resulting hydroxide is represented by _{Ni x Co y Mn z (OH} ) 2 ( wherein, x, y, z are satisfy x + y + z = 1) Is preferred. The above-mentioned x may be 0≦x<1, preferably 0.2≦x≦0.9, and more preferably 0.5≦x≦0.8. The above y may be 0≦y≦1 and preferably 0≦y≦0.4. Further, y is preferably smaller than x. The above z may be 0≦z<1, and preferably 0≦z≦0.4.

The hydroxide obtained by the crystal production method of the present embodiment can be used as, for example, a raw material for a positive electrode active material of a lithium ion battery.

When the crystalline compound is a hydroxide such as nickel, the number of crystals of the crystalline compound in the mixed solution in the reaction vessel 1 may be adjusted to 1×10 ⁹ to 10×10 ⁹ /L. It is more preferably 3×10 ⁹ to 8×10 ⁹ pieces/L, and further preferably 5×10 ^{9 to} 6×10 ⁹ pieces/L. Within such a range, the grain size distribution of the crystal of the crystalline compound does not become too large, and the crystal quality of the crystalline compound obtained by crystal growth can be improved. The number of the crystals can be adjusted by controlling the amount of solute supplied in the crystallization process and the amount of solute discharged in the concentration process described below so that they do not largely deviate from each other.

The grain size of the crystal grown crystal of the crystalline compound (finally obtained grain size) obtained by the crystal production method of the present embodiment is preferably 1 to 30 μm, more preferably 2 to 30 μm. It is 20 μm, and more preferably 3 to 10 μm.
Further, the crystal-grown crystal of the crystalline compound (finally obtained crystal, in the case of a crystal having a density of about 4 g/cm ³ ) may exist in the state of a mixed solution containing a solute. The solid content concentration of the mixed liquid is preferably 10 to 100% by mass, more preferably 20 to 75% by mass, and further preferably 30 to 50% by mass.

In the present embodiment, the grain size of the crystal of the crystalline compound is about 0.2 μm at the initial stage of production, but when the grain size is 0.2 μm, the solid content concentration of the mixed solution in the reaction tank 1 is 0. It is preferably 1 to 10% by mass, more preferably 0.2 to 5% by mass, and further preferably 0.5 to 2% by mass. This is because by setting it in such a range, it becomes easy to appropriately grow the crystal of the crystalline compound.
Further, when the crystal grain size is about 0.2 μm, it is difficult to sufficiently perform classification in the classification step. Therefore, when the crystal grain size is about 0.2 μm, the flow rate of the mixed liquid containing the crystals on the small grain size side of the crystalline compound obtained in the classification step and the large grain size of the crystalline compound obtained in the classification step The ratio with the flow rate of the mixed solution containing crystals on the side may be about 9:1 to 19:1.

In the present embodiment, when the crystal grain size is about 0.2 μm, the solid content concentration of the mixed liquid containing the crystal of the crystalline compound obtained in the concentration step is preferably 0.1 to 10 mass %. , More preferably 0.2 to 5% by mass, still more preferably 0.5 to 2% by mass. This is because by setting it in such a range, it becomes easy to appropriately grow the crystal of the crystalline compound.

In the present embodiment, the crystal grain size of the crystalline compound is about 4 μm in the middle stage of production, but when the grain size is 4 μm, the solid content concentration of the mixed liquid in the reaction tank 1 is 20 to 75% by mass. It is preferably in the range of 30 to 50% by mass, and more preferably 35 to 45% by mass. This is because by setting it in such a range, it becomes easy to appropriately grow the crystal of the crystalline compound.
Further, when the crystal particle size is 4 μm, the solid content concentration of the mixed liquid containing the crystal on the small particle size side of the crystalline compound obtained in the classification step is preferably 0.1 to 10 mass %, It is more preferably 0.2 to 5% by mass, and even more preferably 0.5 to 2% by mass. Further, the solid content concentration of the mixed liquid containing the crystals on the large particle size side of the crystalline compound obtained in the classification step is preferably 40 to 140% by mass, more preferably 50 to 100% by mass, It is preferably 60 to 70% by mass. This is because by setting it in such a range, it becomes easy to appropriately grow the crystal of the crystalline compound.
Further, when the crystal grain size is 4 μm, the flow rate of the mixed liquid containing the crystals of the crystalline compound obtained in the classification step on the small grain size side and the crystals of the crystalline compound obtained in the classification step on the large grain side The ratio with respect to the flow rate of the mixed liquid containing is preferably 4:1 to 19:1, and more preferably 8:1 to 9:1. This is because by setting it in such a range, it becomes easy to appropriately grow the crystal of the crystalline compound.

Next, the crystal manufacturing method according to the second embodiment will be described as an example with reference to FIG. FIG. 2 shows a crystal manufacturing apparatus suitable for use in the crystal manufacturing method according to the second embodiment. It should be noted that the same reference numerals are given to common constituent elements in FIGS. 1 and 2. Further, in the crystal manufacturing methods of the first embodiment and the second embodiment, description of common configurations will be omitted.

-Intermediate storage process-
The crystal manufacturing method of the second embodiment further includes an intermediate storage step in addition to the crystal manufacturing method of the first embodiment.
In the present embodiment, in the intermediate storage step, at least a part of the concentrated mixed solution obtained in the concentration step is separated, and before the filtration in the concentration step, the small particle size side of the crystalline compound obtained in the classification step Is temporarily stored together with the mixed solution containing the crystals of and the stored mixed solution is supplied to the ultrafiltration membrane. The mixed solution concentrated in the concentration step is stored together with the mixed solution containing the crystals on the small particle size side of the crystalline compound obtained in the classification step and then supplied to the ultrafiltration membrane, so that it is concentrated in the concentration step. Concentration can be further performed before the mixed liquid is supplied to the reaction tank 1, and the crystal growth of the crystalline compound can be efficiently performed.

Specifically, in the intermediate storage step, as shown in FIG. 2, the concentrated mixed liquid obtained in the concentration step passes through the fifth line L5 branched in the middle of the fourth line L4 and the second line L2. Is temporarily stored in an intermediate tank 4 provided in the middle of the process together with a mixed liquid containing crystals of the crystalline compound obtained in the classification step on the small particle size side. Then, the mixed liquid in the intermediate tank 4 is supplied to the filter 3 through the second line L2 (second line latter half L2'), and the above-described concentration step is performed. In this way, by the intermediate storage step, the mixed liquid can be circulated in the intermediate tank 4, the second line L2 (second line second half L2′), the filter 3, the fourth line L4, and the fifth line L5, Further concentration can be performed in the concentration step. Further, for example, if the mixture is circulated at a supply amount larger than the supply amount of the mixed liquid after the classifying step or the supply amount of the mixed liquid when entering the reaction tank 1 after the concentration step, the concentration can be more efficiently performed. However, this is effective in the early stage of production when the mixed liquid contains many fine crystals of the crystalline compound.

Next, the crystal manufacturing apparatus according to the first embodiment of the present invention will be described as an example with reference to FIG. FIG. 1 is a schematic diagram showing an example of a crystal production apparatus according to the first embodiment, and is a crystal production apparatus that can be suitably used in the above-described crystal production method of the present invention. It should be noted that the same reference numerals are given to common constituent elements in FIGS. 1 and 2. Further, in the crystal manufacturing apparatus of the first embodiment and the second embodiment, the description of the common configuration will be omitted.
The crystal manufacturing apparatus according to the first embodiment has a reaction tank 1 having a raw material supply unit 11 for supplying a raw material compound, and classifies crystals in a mixed solution containing crystals, and mixes crystals containing crystals on the small particle size side. A settling separator 2 having a small particle size discharging part 21 for discharging a liquid and a large particle size discharging part 22 for discharging a mixed liquid containing crystals on the large particle size side, the reaction tank 1 and the sedimentation device. A concentrated liquid discharge unit that has a first line L1 that connects the separator 2 and an ultrafiltration membrane, and that discharges a mixed liquid containing crystals on the small particle size side that is concentrated by the ultrafiltration membrane. A second line L2 connecting the filter 3 and the small particle size discharge part 21 of the settling separator 2 with the filter 3, and the large particle size discharge of the settling separator 2. And a third line L3 connecting the part 22 and the reaction tank 1, and a fourth line L4 connecting the concentrated liquid discharge part 31 of the filter 3 and the reaction tank 1. Is characterized by.
By having such a configuration, it is suitable to use, for example, the crystal manufacturing method according to the first embodiment of the present invention described above, and it is possible to manufacture a crystal in which the crystal has grown well.

More specifically, the reaction tank 1 of the crystal production apparatus of the present embodiment has a raw material supply section 11 to which a raw material supply line L6 for feeding two or more raw material compounds is connected, and a stirrer is provided. The crystals of the crystalline compound which are formed by the reaction can be sufficiently stirred. Further, a first line L1 in which a pump P1 is provided on the line as shown in the figure for supplying the mixed liquid obtained in the crystallization step described below to the classification step, and the crystalline compound obtained in the classification step described below A third line L3 for returning to the reaction tank 1 a mixed solution containing crystals on the large particle size side, and a fourth line L4 for returning the concentrated mixed solution obtained in the concentration step described below to the reaction tank 1. Are connected. The reaction tank 1 can have a sampling unit for measuring the solid content concentration of the mixed liquid in the reaction tank 1, or a measuring device capable of measuring the solid content concentration in-line.

When the settling separator 2 of the crystal production apparatus of the present embodiment is a liquid cyclone, the flow rate of the mixed liquid to the liquid cyclone is adjusted by the pump P1, or the second line L2 and the third line L3. By adjusting a valve not shown above, the liquid cyclone classification point, the amount of the mixed liquid containing the crystals of the small particle size that are classified and discharged, and the discharge of the mixed liquid containing the crystals of the large particle size are discharged. Each of the quantities can be adjusted.

Further, in this crystal manufacturing apparatus, a recovery line L7, which is provided in the middle of the third line L3 and is capable of recovering a mixed liquid of crystals on the large grain size side, can be provided. As a result, when the crystal has a particle size required for production, the crystal can be recovered without stopping the production (that is, the crystal production can be continuously performed).

Next, the crystal manufacturing apparatus according to the second embodiment of the present invention is further provided in the middle of the second line L2 with respect to the crystal manufacturing apparatus of the first embodiment, and in the middle of the fourth line L4. It has an intermediate tank 4 to which a fifth line L5 branched from four lines L4 is connected. With such a structure, it is suitable to use, for example, the crystal manufacturing method according to the second embodiment of the present invention described above, and it is possible to manufacture a crystal that has been favorably grown.
Moreover, in the crystal manufacturing apparatus of the second embodiment, the pump P2 is provided in the second line L2 (second half of the second line L2′) from the intermediate tank 4 to the filter 3, and the intermediate tank 4 and the second line are provided. When the mixed liquid is circulated through L2, the filter 3, the fourth line L4, and the fifth line L5, it can be circulated at a large flow rate.

Although the embodiments of the present invention have been described with reference to the drawings, the crystal manufacturing method and the crystal manufacturing apparatus of the present invention are not limited to the above examples, and can be appropriately modified.

Hereinafter, the present invention will be described in more detail with reference to Examples, but the present invention is not limited to the following Examples.

(Example 1)
Crystals were manufactured using a manufacturing apparatus as shown in FIG. Specifically, an aqueous solution prepared by mixing an aqueous solution of cobalt sulfate, an aqueous solution of nickel sulfate, and an aqueous solution of manganese sulfate in a molar ratio of 1:1:1 is supplied to a reaction tank (capacity 1000 L) at 40 L/hr, and at the same time. A 0.2 N sodium hydroxide aqueous solution was supplied to the same reaction tank (capacity 1000 L) at 40 L/hr, and stirred to react with Ni _x Co _y Mn _z (OH) ₂ (ternary hydroxide). The crystallized Ni _x Co _y Mn _z (OH) ₂ mixed solution (slurry) was supplied to a liquid cyclone at 310 L/hr for classification. The mixture containing the crystals on the small particle size side after being classified is concentrated with an ultrafiltration membrane (Microsa UF, manufactured by Asahi Kasei Corporation) to obtain a Ni _x Co _y Mn _z (OH) ₂ concentrate (exhaust liquid). It was separated into a filtered sodium sulfate solution (filtrate). The concentrated mixed solution and a mixed solution containing crystals on the large particle size side classified by a liquid cyclone were supplied to and mixed with a reaction tank, and a reaction was performed while circulating the mixed solution. The filtrate filtered by concentration was 80 L/hr. Was carried out the above reaction for 120 hours, the particle size _{10μm Ni x Co y Mn z (} OH) 2 crystals could be obtained 88 kg (92% yield).

(Example 2)
Crystals were manufactured using a manufacturing apparatus as shown in FIG. Specifically, a cobalt sulfate aqueous solution, a nickel sulfate aqueous solution, and a manganese sulfate aqueous solution are mixed in a reaction tank (volume: 1000 L) so that the molar ratio becomes 1:1:1, and then sodium hydroxide (0.2 N) is added. Was added and reacted with Ni _x Co _y Mn _z (OH) ₂ (ternary hydroxide). The crystallized Ni _x Co _y Mn _z (OH) ₂ mixed solution (slurry) was supplied to a liquid cyclone at 310 L/hr for classification. The mixture containing the crystals on the small particle size side after being classified is concentrated with an ultrafiltration membrane (Microsa UF, manufactured by Asahi Kasei Corporation) to obtain a Ni _x Co _y Mn _z (OH) ₂ concentrate (exhaust liquid). It was separated into a filtered sodium sulfate solution (filtrate). The concentrated mixed solution and a mixed solution containing crystals on the large particle size side classified by a liquid cyclone were supplied to and mixed with a reaction tank, and a reaction was performed while circulating the mixed solution. The supply rate of the cobalt sulfate aqueous solution, the nickel sulfate aqueous solution, and the manganese sulfate aqueous solution was 180 L/hr, and an intermediate tank was added to the manufacturing apparatus to supply the mixed solution containing crystals on the small particle size side after the liquid cyclone. The reaction was carried out while circulating the mixed solution in the same manner as in Example 1 except that the intermediate tank and the filter were circulated at a supply amount larger than the supply amount of the mixed liquid when entering the reaction tank after the concentration step. Was carried out the above reaction for 120 hours, the particle size _{14μm Ni x Co y Mn z (} OH) 2 crystals could be obtained 92 kg (96% yield).

(Comparative Example 1)
The reaction was carried out in the same manner as in Example 1 except that the cartridge type MF membrane was used instead of the Microuser UF as the filtration membrane. When the above reaction was carried out for 120 hours, 48 kg (yield 50%) of Ni _x Co _y Mn _z (OH) ₂ crystals having a particle size of 8 μm could be obtained.

(Comparative example 2)
The reaction was performed in the same manner as in Example 1 except that the liquid mixture supplied from the reaction tank was entirely supplied to the cartridge type MF membrane without using the liquid cyclone. When the above reaction was carried out, the cartridge type MF was clogged when the crystal grain size was about 2 to 3 μm after the reaction was initiated, so the reaction was stopped.

(Comparative example 3)
The reaction was performed in the same manner as in Example 1 except that the liquid mixture supplied from the reaction tank was entirely supplied to the Microuser UF without using the liquid cyclone. When the above reaction was carried out, after the reaction started, when the crystal grain size was about 10 μm, the filtration flux of the Microuser UF rapidly decreased, so the reaction was stopped.

According to the present invention, it is possible to provide a crystal manufacturing method capable of efficiently manufacturing a crystal having a desired particle size and a crystal manufacturing apparatus capable of efficiently manufacturing a crystal having a desired particle size.

1: Reaction tank 11: Raw material supply section 2: Sedimentation separator 21: Small particle size discharge section 22: Large particle size discharge section 3: Filter 31: Concentrated liquid discharge section 4: Intermediate tank L1: First line L2: No. 2nd line L2': 2nd half of second line L3: 3rd line L4: 4th line L5: 5th line L6: Raw material supply line L7: Recovery line P1, P2: Pump

Claims (9)

Two or more raw material compounds having good solubility in a predetermined solute are supplied to a reaction tank in a state where at least one kind of the raw material compound is dissolved in the solute, and the raw material compound in the reaction tank is supplied. In a mixed solution containing the solute, the raw material compound is reacted to crystallize a crystalline compound that is poorly soluble in the solute, a crystallization step,
Crystals of the crystalline compound in the mixed solution obtained in the crystallization step, the large particle size crystals and the small particle size crystals, a classification step of classifying by sedimentation separation,
A mixed solution containing crystals on the small particle size side of the crystalline compound obtained in the classification step is filtered with an ultrafiltration membrane to concentrate solutes in the mixed solution, and a concentration step,
Have
A mixed solution containing crystals on the large particle size side of the crystalline compound obtained in the classification step, and a concentrated mixed solution containing crystals on the small particle size side of the crystalline compound obtained in the concentration step, A method for producing a crystal, which comprises mixing with the mixed solution in the crystallization step. At least a part of the concentrated mixed solution obtained in the concentration step is separated, and temporarily filtered together with the mixed solution containing crystals on the small particle size side of the crystalline compound obtained in the classification step before being filtered in the concentration step. The method for producing a crystal according to claim 1, further comprising an intermediate storage step of storing the mixed solution in the ultrafiltration membrane and storing the mixed solution in the ultrafiltration membrane. When the crystals of the mixed liquid containing the crystals on the large particle size side of the crystalline compound obtained by the classification step have a predetermined particle size or more, the large particle size side of the crystalline compound obtained by the classification step The crystal manufacturing method according to claim 1, further comprising a recovery step of recovering at least a part of the mixed solution containing crystals. The solute is water,
The raw material compound is a metal salt of at least one element selected from the group consisting of nickel, cobalt, and manganese, and a hydroxide of an alkali metal or an alkaline earth metal,
The method for producing crystals according to claim 1, wherein the crystalline compound is a hydroxide of a metal element of a metal salt in the raw material compound. The solute is water,
The raw material compound is a sulfated product of at least one element selected from the group consisting of nickel, cobalt, and manganese, and sodium hydroxide,
The method for producing a crystal according to claim 1, wherein the crystalline compound is a hydroxide of a metal element of a sulfate compound in the raw material compound. The method for producing crystals according to claim 1, wherein in the classifying step, classification is performed by a liquid cyclone. A reaction tank having a raw material supply unit for supplying a raw material compound;
Classifying the crystals in the mixed solution containing crystals, small particle size discharge part where the mixed solution containing crystals on the small particle size side is discharged, and large particle discharging the mixed solution containing crystals on the large particle size side A settling separator having a diameter discharge part,
A first line connecting the reaction tank and the sedimentation separator;
While having an ultrafiltration membrane, having a concentrated solution discharge part for discharging a mixed solution containing crystals on the small particle size side, which is concentrated by the ultrafiltration membrane, and a filter,
A second line connecting the small particle size discharge part of the sedimentation separator and the filter;
A third line connecting the large particle size discharge part of the sedimentation separator and the reaction tank;
A fourth line connecting the concentrated liquid discharge part of the filter and the reaction tank,
An apparatus for producing crystals, comprising: The crystal production apparatus according to claim 7, further comprising an intermediate tank provided in the middle of the second line and connected to a fifth line branched from the fourth line in the middle of the fourth line. 9. The crystal manufacturing apparatus according to claim 7, further comprising a recovery line that is provided in the middle of the third line and that can recover a mixed liquid of crystals on the large grain size side.

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