JP7163274B2 - How to obtain iodine-based substances - Google Patents

Description

The present invention relates to a method for obtaining iodine-based substances from natural brackish water.

Natural gas is roughly classified into structural gas and water-soluble gas. Of these, water-soluble natural gas is dissolved in underground brines buried in underground aquifers. The underground brine that remains after water-soluble natural gas is pumped to the surface by a pumping well buried underground and vaporized contains salt components such as sodium chloride, potassium chloride, calcium chloride, magnesium sulfate, etc., similar to those found in seawater salts. May contain significant concentrations of iodide salts. It is known that underground brine containing a high concentration of iodide salt can be obtained in some areas of Japan, oil drilling areas in the United States and Russia.

Various methods are known for industrially extracting iodine from underground brine. (Patent Documents 1 to 3)
There is also an invention of a method for desalinating seawater or brackish water by multistage dialysis. (Patent Document 4)

Japanese Patent Publication No. 28-6615 JP-A-51-106695 JP-A-57-100901 JP-A-53-16374

The inventions described in Patent Documents 1 to 3 are methods for extracting iodine by directly treating underground brine. However, when these methods are applied industrially, it is not possible to convert all iodide ions into molecular iodine due to the occurrence of side reactions. A certain amount of contained iodide ions cannot be collected. More specifically, in a method such as the blowing-out method, in which an oxidizing agent is injected into underground brine to collect free iodine, about 8 to 15 mg/L of iodine atoms are not collected in the wastewater after iodine extraction. inevitably remain. That is, in the method of adding an oxidizing agent to underground brine, the amount of iodine that can be collected relative to the total amount of iodide ions contained is relatively low, and it is desired to improve the acquisition rate of iodine, which is a natural resource.

In addition, the invention described in Patent Document 4 is intended to industrially perform an operation for removing salt from seawater or underground brine, and concentration of dissolved components in underground brine is not taken into consideration. No attention has been paid to the recovery of iodide ions in groundwater.

An object of the present invention is to provide a method for efficiently obtaining an iodine-based substance from underground brine.

Such objects are achieved by the present invention described below.
The method for obtaining an iodine-based substance of the present invention is a method for obtaining an iodine-based substance from underground brine containing iodide ions without adding an oxidizing agent ,
a concentration step of obtaining concentrated brine containing a high concentration of iodide ions from the underground brine;
an iodine-based substance obtaining step of obtaining an iodine-based substance from the concentrated brine;
including
The concentration step is a step of obtaining the concentrated brine by electrodialyzing the subterranean brine using an electrodialysis apparatus comprising at least one electrodialysis tank .

Moreover, in the present invention, the electrodialysis apparatus is preferably a multi-stage electrodialysis apparatus comprising two or more electrodialysis tanks connected to each other.

An object of the present invention is to provide a method for obtaining an iodine-based substance that can efficiently obtain an iodine-based substance from brackish water.

In particular, by using concentrated brine in which the concentration of iodide ions contained is increased by the concentration step, it is possible to increase the acquisition rate of iodine-based substances in the subsequent iodine-based substance acquisition step. In addition, by reducing the total amount of brackish water in the concentration step, it is possible to reduce the amount of acid and oxidizing agent used in the iodine-based substance acquisition step.

Conventionally, when an attempt was made to obtain an iodine-based substance from brackish water with a low iodide ion concentration, the yield tended to be low. In the method, the concentration of iodide ions in brackish water can be efficiently increased, and an iodine-based substance can be obtained at a high yield in the step of obtaining an iodine-based substance.

FIG. 1 is a schematic diagram showing an example of a demineralized water circulation type multi-stage electrodialysis apparatus that can be used in the concentration step of the method for obtaining an iodine-based substance of the present invention. FIG. 2 is a schematic diagram showing an example of a concentrated water circulation type multi-stage electrodialysis apparatus that can be used in the concentration step of the method for obtaining an iodine-based substance of the present invention. FIG. 3 is a schematic diagram showing an example of a combined demineralized water circulation-concentrated water circulation multi-stage electrodialysis apparatus that can be used in the concentration step of the method for obtaining an iodine-based substance of the present invention. FIG. 4 is a schematic diagram showing a countercurrent supply method in an electrodialysis cell. FIG. 5 is a schematic diagram showing a co-current supply method in an electrodialysis cell.

Preferred embodiments of the present invention are described in detail below.
A method for obtaining an iodine-based substance according to the present invention is a method for obtaining an iodine-based substance from underground brine containing iodide ions, in which concentrated brine containing a high concentration of iodide ions is obtained from the underground brine. It includes a concentration step and an iodine-based substance obtaining step of obtaining an iodine-based substance from the concentrated brine.

Accordingly, it is possible to provide a method for obtaining an iodine-based substance that can efficiently obtain an iodine-based substance from underground brine. In particular, in the past, when trying to obtain iodine-based substances from underground brine with a relatively low iodide ion concentration, the yield tended to be low. In the present invention, the iodide ion concentration in the underground brine can be efficiently increased in the process of obtaining the iodine-based substance, and the iodine-based substance can be obtained at a high yield.

In the present invention, the iodine-based substance is composed of an element, a compound, or an ionic substance containing iodine, and may contain two or more components containing iodine. Examples of the element containing iodine include molecular iodine (I ₂ ), examples of compounds containing iodine include hydroiodic acid, and examples of ionic substances containing iodine include , iodide salts, iodates, and the like.

The concentration step may be a step of obtaining concentrated brine containing a high concentration of iodide ions from underground brine, but by electrodialyzing the underground brine using an electrodialyzer equipped with at least one electrodialyzer. The step of obtaining concentrated brine is preferred.

As a result, the subterranean brine can be efficiently concentrated, and the iodide ions in the concentrated brine obtained in this step can be increased more favorably. In addition, impurities such as organic substances contained in the underground brine, which is the raw material, can be preferably removed, and the subsequent iodine-based substance acquisition step can be performed more efficiently.

[1] Subterranean brine In the present invention, subterranean brine containing iodide ions is used as a raw material. Specifically, for example, underground brackish water that remains after extracting water-soluble natural gas from brackish water pumped from an underground brackish aquifer can be used. In addition, subsurface brines with varying iodide ion concentrations, oxidant concentrations, and pH values, such as mixed brines collected from multiple wells from time to time, can also be used in the present invention.

The iodide ion content of the underground brine used is not particularly limited, but is preferably 10 mg/L or more, more preferably 20 mg/L or more. Compared to the conventional method of directly adding an oxidizing agent to brackish water, the advantage of the present invention is remarkably exhibited for brackish water having a low iodide ion concentration of 80 mg/L or less, especially 50 mg/L or less. The present invention also enables the use of brackish water with an iodide ion content of 30 mg/L or less, which has hitherto not been economically available.

[2] Pretreatment For subterranean brine, before performing each step described in detail later, for example, to prevent clogging of the flow path in the electrodialyzer, It is preferable to perform a pretreatment to remove contaminants such as substances and microorganisms. The pretreatment can be performed, for example, by a coagulation sedimentation process, a sand filtration process, a porous filtration membrane process, or the like, singly or in combination.

As the filtering material, for example, particles such as sand, coal, activated carbon, inorganic oxides or resins, or porous filtration membranes such as microfiltration membranes or ultrafiltration membranes can be used. Although the average pore diameter of the porous filtration membrane is not particularly limited, it is preferably 0.01 μm or more and 1 μm or less in terms of the balance between the removal performance and the amount of permeated water.

In the present invention, the subterranean brine pumped from the underground aquifer is preferably treated in a non-oxidizing state without being exposed to air. For that purpose, the brackish water derived from the underground should be handled in a non-oxidizing atmosphere, such as a nitrogen gas atmosphere, without exposing it to light, and by adding no oxidizing substances, the non-oxidizing It is preferable to handle it in a sexual state. Subterranean brine in a non-oxidizing state is brine that does not have oxidizing properties, and has an oxidation-reduction potential of 0 mV or less, preferably 0 to -50 mV, at a platinum electrode potential. When the subterranean brine is treated in a non-oxidizing state, the transition metal components such as iron ions contained in the subterranean brine are not oxidized, so precipitation of insoluble oxides in equipment and piping can be prevented.

[3] Concentration step By using an electrodialyser in the concentration step, the iodide ion concentration in the underground brine can be efficiently increased, and organic matter can be removed. As a result, the effect of the additive agent can be enhanced in the step of obtaining the iodine-based substance. Furthermore, since there is no loss associated with by-production of the organic iodine compound, the yield of the iodine-based substance can be increased.

Since the salt contained in the dilution water hardly affects the apparent transfer rate of iodide ions permeating the ion exchange membrane, the concentration of salt does not matter in the concentration process.

By electrodialyzing underground brine through an electrodialyser, concentrated brine, which is an aqueous solution containing a higher concentration of iodide salt, and desalted water, which is an aqueous solution with a reduced concentration of iodide salt, are obtained. The concentration of iodide ions in the concentrated brine is preferably 100 mg/L or higher, more preferably 500 mg/L or higher, even more preferably 1000 mg/L or higher. The ratio of the iodide ion concentration in the concentrated brine to the iodide ion concentration in the raw material underground brine is preferably 10 to 5000 times, more preferably 50 to 2000 times.

An electrodialyzer, which constitutes an electrodialyzer, comprises one or more demineralization compartments and concentration compartments. Each electrodialyzer has a plurality of anion-exchange membranes and cation-exchange membranes alternately arranged to form a desalting compartment and a concentration compartment between the membranes, and an anode and a cathode are provided on both outer sides. consists of A chamber partitioned by an anion-exchange membrane on the anode side and a cation-exchange membrane on the cathode side is a desalting chamber, and a chamber partitioned by a cation-exchange membrane on the anode side and an anion-exchange membrane on the cathode side is a concentration chamber. In each electrodialysis tank, a plurality of sets of two membranes, an anion exchange membrane and a cation exchange membrane, are repeatedly arranged. The number of sets of the anion exchange membrane and the cation exchange membrane is preferably 1 or more and 2500 or less, more preferably 10 or more and 1000 or less.

In each electrodialysis cell, a direct current is applied between the cathode and the anode, and the demineralization chamber is supplied with subterranean brine or raw water, which is concentrated water from the preceding electrodialysis cell. The ions in the supplied raw material water are separated by an ion exchange membrane so that concentrated water containing a relatively high concentration of iodide salt is discharged from the concentration chamber and demineralized water having a relatively low concentration of iodide salt is discharged from the desalting chamber. , respectively. The ratio of the iodide ion concentration in the concentrated water to the iodide ion concentration in the desalted water obtained in each stage of the electrodialysis tank is preferably 3:1 to 20:1 in the sequential circulation type described later. In the case of the concentrated water circulation type described later, the ratio is preferably 5:1 to 100:1.

In the present invention, the flow rate of the dilution water in each electrodialysis tank is preferably smaller than the flow rate of the raw water, but it is not necessary to excessively increase the flow ratio of the raw water and the dilution water to be supplied. The volume ratio of the raw material water to the dilution water to be supplied is preferably 1:1 to 30:1. By maintaining an appropriate flow rate ratio between the raw material water and the dilution water to be supplied, the ion exchange membrane can be maintained without damage even after long-term operation.

In each electrodialysis tank, the voltage of the direct current applied between the cathode and the anode is preferably 3 V or less, more preferably 2 V or less per set of anion exchange membrane and cation exchange membrane. preferable. In each electrodialysis cell, the current density of the direct current applied between the cathode and the anode is preferably 3 A/dm ² or less per effective area of the ion exchange membrane.

As the anion exchange membrane used in the electrodialysis apparatus, a membrane with enhanced anion selective permeability can be preferably used.

Anions such as chloride ions and iodide ions contained in underground brine selectively permeate the anion exchange membrane and move from the desalination compartment to the concentration compartment. Non-ionizing inorganic compounds and polymeric organic compounds such as fulvic acid remain in the desalting chamber without permeating the anion exchange membrane, and are contained in the desalted water and discharged.

As the anion exchange membrane, for example, Selemion ASV-N membrane, Selemion AMV-N membrane (both manufactured by AGC Corporation), Neosepta ASE membrane (manufactured by Astom Corporation) and the like can be used.

As the cation exchange membrane used in the electrodialysis apparatus, a monovalent ion selective permeable cation exchange membrane, which is a membrane with enhanced selective permeability for monovalent cations, can be preferably used.

Concentrated brackish water from which polyvalent ions such as transition metal ions, calcium ions, magnesium ions, etc., and organic matter are removed from brackish water by using a combination of monovalent ion permselective cation exchange membranes and anion exchange membranes is obtained. Therefore, in the step of obtaining the iodine-based substance, precipitation due to transition metal oxides does not occur, and an effect is obtained that crystals of calcium carbonate and magnesium carbonate do not precipitate. This facilitates the acquisition of the iodine-based substance from the underground brine in the iodine-based substance acquisition step.

Monovalent cations such as sodium ions and potassium ions contained in underground brine selectively permeate the monovalent ion selective permeable cation exchange membrane and move from the desalination compartment to the concentration compartment. On the other hand, polyvalent cations such as calcium ions, magnesium ions, transition metal ions, non-ionizing inorganic compounds, and macromolecular organic compounds such as fulvic acid contained in groundwater do not permeate the cation exchange membrane. remains in the desalting chamber, is contained in the desalted water, is discharged, and is removed from the concentrate.

Since the concentrated brackish water obtained through an electrodialyser using a monovalent ion selective permeable cation exchange membrane does not substantially contain transition metal ions, in the subsequent step of obtaining iodine-based substances, insoluble due to oxidation of transition metal ions The formation of oxides is effectively prevented.

As the monovalent ion permselective cation exchange membrane, for example, a strongly acidic styrene-divinylbenzene-based homogeneous cation exchange membrane or the like is used. A CIMS film (manufactured by Astom Co., Ltd.) or the like can be used.

In the electrodialysis tank that constitutes the electrodialysis apparatus, it is preferable to use a combination of a monovalent ion permselective cation exchange membrane and an anion exchange membrane.

Subterranean brine mined from the ground usually contains a large amount of transition metal ions, unlike seawater. Typically, the iron ion content is 5 mg/L or more and 20 mg/L or less, and the manganese ion content is 0.1 mg/L or more and 0.3 mg/L or less. Therefore, in the concentration process, the use of a monovalent ion-selective cation exchange membrane to remove the transition metal ions from the underground brine is essential for the smooth operation of subsequent processes and the iodine-based substance obtained by the present invention. It is preferable to make the quality of the product more stable and excellent. The transition metal ion concentration in the concentrated brine after the concentration step is preferably 0.1 mg/L or less for iron ions, more preferably 0.05 mg/L or less, and 0.05 mg/L or less for manganese ions. It is preferably 02 mg/L or less, more preferably 0.01 mg/L or less.

By increasing the concentration of iodide ions contained in the brine by the concentration step, it is possible to increase the yield of the iodine-based substance in the subsequent step of obtaining the iodine-based substance. In addition, since the concentration process removes the organic substances contained in the raw material underground brine, it is possible to prevent the by-production of organic iodine compounds and organic halides in the iodine-based substance acquisition process, and the organic substances contained in the raw material underground brine can be prevented. iodide ions are efficiently captured. Furthermore, since the underground brine is reduced in the concentration step and the amount of the material to be treated in the iodine-based substance acquisition step is reduced, chemicals such as acids and alkalis for pH adjustment added in the iodine-based substance acquisition step, The amount of solvent used in the absorption method can be significantly reduced.

When the concentration step is performed using an electrodialyzer, the electrodialyzer can obtain concentrated water with an increased iodide ion concentration using a single-stage electrodialyzer. However, as electrodialysis progresses and the difference between the ion concentration in the concentration compartment and the ion concentration in the demineralization compartment increases, the reverse migration of the migrated ions becomes unignorable, and the apparent migration of the ions slows down. effect is reduced. Therefore, from the point of view of electrical efficiency, it is preferable to use a multi-stage electrodialysis apparatus comprising two or more electrodialysis tanks connected to each other.

By using a multi-stage electrodialysis device to sequentially increase the iodide ion concentration each time the concentrated water passes through each electrodialysis tank, it is possible to obtain concentrated brackish water with high concentration and few impurities at high electrical efficiency. can.

The number of electrodialysis cells in the multistage electrodialysis apparatus is not limited, but is preferably 2 or more and 6 or less, more preferably 3 or more and 5 or less.

In the following description, when the underground brine is electrodialyzed using an electrodialyser in the concentration step, in particular, the electrodialysis is performed using a multi-stage electrodialyzer having two or more electrodialyzers connected to each other. Although the description will focus on the case of dialysis, the use of a single-stage electrodialysis apparatus is not excluded.

In the present invention, the concentrated water containing a higher concentration of iodide ions, which is obtained from the concentrating chamber of each electrodialysis tank constituting the multi-stage electrodialysis apparatus, is simply referred to as "concentrated water". , the concentrated water finally obtained by the concentration process is called "concentrated brine". The demineralized water with reduced concentration of iodide ions obtained from the demineralization compartment of each electrodialysis cell is simply referred to as "demineralized water".

Regarding a plurality of electrodialysis tanks connected by a flow of concentrated water, the electrodialysis tank upstream of a specific electrodialysis tank with respect to the flow direction of the concentrated water is referred to as the "previous" electrodialysis tank, or the specific electrodialysis tank. A downstream electrodialysis cell is referred to as a "later stage" electrodialysis cell. In addition, regarding a plurality of electrodialysis tanks connected by the flow of desalted water, the electrodialysis tank upstream of a specific electrodialysis tank with respect to the flow direction of the desalted water is the "upper" electrodialysis tank, the specific electrodialysis tank An electrodialysis cell downstream of the cell is referred to as a "lower stage" electrodialysis cell.

In each electrodialyzer that constitutes the electrodialyzer, subterranean brine or concentrated water from the preceding electrodialyzer is supplied as raw water to the demineralizing chamber, and diluted water is supplied to the concentrated chamber, and deionized from the demineralizing chamber. A brine is obtained and a concentrated water is obtained from the concentration chamber. Concentrated water obtained in each electrodialysis tank constituting the electrodialysis apparatus is sequentially supplied to the subsequent electrodialysis tank immediately after, to obtain concentrated brine, which is an aqueous solution containing a higher concentration of iodide salt.

At least part of the demineralized water obtained in each stage of the electrodialysis tanks constituting the multistage electrodialysis apparatus is transferred to the preceding electrodialysis tank, i. Feed the tank. The desalted water obtained in the first-stage electrodialysis tank and the desalted water not supplied to the preceding-stage electrodialysis tank can be discharged, for example, to rivers, oceans, or the ground from which subterranean brine is mined.

By using a multi-stage electrodialyzer, it is possible to remove impurities and enhance the concentration and recovery of iodide ions to efficiently obtain concentrated brackish water containing a higher concentration of iodide ions. can. That is, it is possible to economically achieve both high concentration and high yield in concentrating iodide ions.

In the present invention, a multi-stage electrodialyzer comprising two or more electrodialyzers connected to each other is used, and at least part of the demineralized water obtained in at least one electrodialyzer constituting the electrodialyzer is It is preferable to supply dilution water to the electrodialysis tank or to the concentration chamber of the electrodialysis tank preceding the electrodialysis tank with respect to the flow direction of the concentrated water.

By this operation, the iodide ions remaining in the desalted water can be recovered, and the acquisition rate (yield) of the iodine-based substance from the underground brine can be improved. Also, the amount of replenishing water used can be suppressed.

In the present invention, a multi-stage electrodialyzer comprising two or more electrodialyzers connected to each other is also used, and at least part of the demineralized water obtained in at least one electrodialyzer constituting the electrodialyzer is It is preferable to add to the subterranean brine or concentrated water supplied to the demineralization chamber of the preceding electrodialysis tank with respect to the direction of flow of the concentrated water from the electrodialysis tank.

By this operation, electrodialysis of desalted water can be repeated, iodide ions remaining in desalted water are recovered in concentrated water, and the acquisition rate (yield) of iodine-based substances from underground brine can be improved. can be done.

In the present invention, as in these examples, the electrodialysis operation of supplying at least part of the desalted water obtained in the electrodialysis tank to the electrodialysis tank or the preceding or upper electrodialysis tank is a desalted water circulation type electrodialysis. called.

The demineralized water circulation type electrodialysis will be described below with reference to FIG.
FIG. 1 is a schematic diagram showing an example of a demineralized water circulation type multi-stage electrodialysis apparatus that can be used in the concentration step of the method for obtaining an iodine-based substance of the present invention.

FIG. 1 shows an electrodialysis apparatus comprising three electrodialysis cells connected in series: a first electrodialysis cell 111 , a second electrodialysis cell 112 and a third electrodialysis cell 113 .

Each electrodialysis tank is energized, and the raw material, underground brine 120 , is passed through the first electrodialysis tank 111 . The first concentrated water 121 obtained from the first electrodialysis tank 111 is passed through the latter second electrodialysis tank 112 . The first desalted water 131 obtained from the first electrodialysis tank 111 is used as underground return water 135 .

The second concentrated water 122 obtained from the second electrodialysis tank 112 is passed through the third electrodialysis tank 113 in the subsequent stage. Part of the second desalted water 132 obtained from the second electrodialysis tank 112 is added to the underground return water 135, and the remainder is combined with the first replenishment water 161 to form the first dilution water 141 in the first electrodialysis tank. 111 is passed through.

The third concentrated water 123 obtained from the third electrodialysis tank 113 is supplied to the iodine-based substance acquisition device 151 . Part of the third desalted water 133 obtained from the third electrodialysis tank 113 is added to the underground return water 135, and the remainder is combined with the second replenishment water 162 to form the second dilution water 142 in the second electrodialysis tank 112. permeate the At least part of the third desalted water 133 obtained in the third electrodialysis tank 113 may be combined with the first replenishing water 161 and passed through the first electrodialysis tank 111 as the first dilution water 141 .

An iodine-based substance is obtained in the iodine-based substance obtaining device 151 . After the iodine-based substance acquisition step, part of the desalted water separated from the iodine-based substance is combined with the third replenishment water 163 and passed through the third electrodialysis tank 113 as the third dilution water 143, and the iodine-based substance Waste water 152 remaining after acquisition is discharged. In each electrodialysis tank, the addition of replenishing water and the addition of demineralized water to underground return water are optional.

In a demineralized water circulation type multi-stage electrodialysis apparatus, it is possible to obtain concentrated water with a higher iodide ion recovery rate.

In the demineralized water circulation type multi-stage electrodialysis, the dilution water can be supplied countercurrently to the flow direction of the raw material water in each electrodialysis tank (111, 112, 113 in FIG. 1). This is called a countercurrent feeding method, and details thereof will be described later. In demineralized water circulating electrodialysis, a co-current supply method is possible, but a counter-current supply method is preferred in order to increase the yield of iodide ions.

In addition, in the present invention, a multi-stage electrodialyzer comprising two or more electrodialyzers connected to each other is used, and part of the concentrated water obtained in at least one of the electrodialyzers constituting the electrodialyzer is preferably circulated as diluent water to the concentration chamber of the electrodialysis tank, and the remainder is obtained as concentrated water.

When the concentrated water obtained from the electrodialysis tank is circulated through the concentration chamber of the electrodialysis tank, the iodide ions separated from the brackish water are accumulated in the concentrated water along with the circulation of the concentrated water, resulting in a high concentration of iodide ions. A concentrated water is obtained. At this time, the movement of water due to the difference in osmotic pressure accompanying the difference in concentration occurs at the same time, and the amount of concentrated water increases, so the increased amount can be obtained as concentrated water.

In the present invention, a part of the concentrated water obtained in the electrodialysis tank is circulated to the concentration chamber of the electrodialysis tank as dilution water, and the remaining concentrated water is obtained as the concentrated water of the electrodialysis tank. This is called water circulation type electrodialysis.

Such an operation makes it possible to obtain concentrated water containing a high concentration of iodide ions. The configuration and operation of the electrodialyzer are also simple. Also, the amount of replenishing water used can be reduced.

Concentrated water circulation type electrodialysis will be described below with reference to FIG.
FIG. 2 is a schematic diagram showing an example of a concentrated water circulation type multi-stage electrodialysis apparatus that can be used in the concentration step of the method for obtaining an iodine-based substance of the present invention.

FIG. 2 shows an electrodialysis apparatus comprising three electrodialysis cells connected in series: a first electrodialysis cell 211 , a second electrodialysis cell 212 and a third electrodialysis cell 213 .

Each electrodialysis tank is energized, and the raw material, underground brine 220 , is passed through the first electrodialysis tank 211 . Part of the first concentrated water 221 obtained from the first electrodialysis tank 211 is passed through the second electrodialysis tank 212 in the latter stage, and the rest is combined with the first replenishment water 261 to form the first dilution water 241. circulates to the first electrodialysis tank 211 as The first desalted water 231 obtained from the first electrodialysis tank 211 is used as underground return water 235 .

Part of the second concentrated water 222 obtained from the second electrodialysis tank 212 is passed through the third electrodialysis tank 213 in the latter stage, and the remainder is combined with the second replenishment water 262 to form the second dilution water 242. circulates to the second electrodialysis tank 212 as Part of the second desalted water 232 obtained from the second electrodialysis tank 212 is mixed with the underground brine 220 and supplied to the first electrodialysis tank 211, and the rest is returned to the underground water 235 as the first circulating water 271. Add.

Part of the third concentrated water 223 obtained from the third electrodialysis tank 213 is supplied to the iodine-based substance acquisition device 251, and the remainder is combined with the third replenishing water 263 to form the third diluted water 243. It circulates in the electrodialysis tank 213 . Part of the third desalted water 233 obtained from the third electrodialysis tank 213 is mixed with the first concentrated water 221 and supplied to the second electrodialysis tank 212, and the remainder is used as the second circulating water 272 and returned to the ground. Add to 235.

An iodine-based substance is obtained in the iodine-based substance obtaining device 251 . After obtaining the iodine-based substance, the remaining wastewater 252 is discharged.

Concentrated water with a higher iodide ion concentration can be obtained in the concentrated water circulation type multi-stage electrodialysis. In addition, since the volume of the concentrated water can be reduced, there is an advantage that the device size of the electrodialysis tank and the iodine-based substance acquisition device 251 in the second and subsequent stages can be reduced. In each electrodialysis tank, the addition of replenishing water and the addition of demineralized water to underground return water are optional.

In concentrated water circulation type electrodialysis, dilution water can be supplied in parallel with the flow direction of raw water in each electrodialysis tank (211, 212, 213 in FIG. 2). This is called a cocurrent supply method, and the details will be described later. In concentrated water circulation type electrodialysis, both the cocurrent supply method and the above-described countercurrent supply method can be used.

In the concentration step of the present invention, it is also preferable to use a combined demineralized water circulation-concentrated water circulation multi-stage electrodialysis apparatus in which a demineralized water circulation type electrodialysis cell and a concentrated water circulation type electrodialysis cell are combined. That is, using such a multistage electrodialysis apparatus, part of the concentrated water obtained in at least one electrodialysis tank that constitutes the electrodialysis apparatus is circulated to the electrodialysis tank as dilution water, and the concentrated water is is obtained as concentrated water in the electrodialysis tank, and at least part of the desalinated water obtained in the electrodialysis tank is electrodialyzed in the lower electrodialysis tank in the direction of flow of the desalinated water, At least part of the concentrate obtained in the electrodialysis tank can be circulated through said electrodialysis tank. When circulating the concentrated water obtained in the lower-stage electrodialysis tank, it is preferable to add the concentrated water to the concentrated water in the preceding-stage electrodialysis tank with respect to the flow direction of the concentrated water.

As a result, the iodide ions in the demineralized water are recovered by desalted water circulation type electrodialysis, and the concentrated water is concentrated by the concentrated water circulation type electrodialysis. can be obtained on a regular basis.

Furthermore, at least part of the desalted water obtained in the lower electrodialysis tank can be circulated as dilution water to the same lower electrodialysis tank. Also, at least part of the desalted water obtained in the lower electrodialysis tank can be supplied from the electrodialysis tank to the preceding electrodialysis tank in the flow direction of the concentrated water as dilution water. In either case, the recovery rate of iodide ions can be increased.

The demineralized water circulation/concentrated water circulation combined type electrodialysis will be described below with reference to FIG.

FIG. 3 is a schematic diagram showing an example of a combined demineralized water circulation-concentrated water circulation multi-stage electrodialysis apparatus that can be used in the concentration step of the method for obtaining an iodine-based substance of the present invention.

FIG. 3 shows an electrodialysis apparatus comprising three electrodialysis cells, namely a first electrodialysis cell 311, a second electrodialysis cell 312 and a third electrodialysis cell 313, which are interconnected.

Each electrodialysis tank is energized, and the raw material underground brine 320 is passed through the first electrodialysis tank 311 . All of the first desalted water discharged from the first electrodialysis tank 311 is used as underground return water 335 . The first concentrated water 321 obtained from the first electrodialysis tank 311 is passed through the subsequent second electrodialysis tank 312 . The second desalted water 322 discharged from the second electrodialysis tank 312 is passed through the third electrodialysis tank 313 . Part of the third desalted water 333 discharged from the third electrodialysis tank 313 is mixed with the first replenishment water 361 as the dilution water 341 of the first electrodialysis tank 311 and passed in countercurrent. Note that the first replenishing water 361 may not be added. Part of the third desalted water 333 is passed as third dilution water. The remaining third desalted water 333 is used as underground return water 335 . All of the third concentrated water 323 obtained from the third electrodialysis tank 313 is mixed with the first concentrated water 321 and passed through the second electrodialysis tank 312 to the second concentrated water 322 obtained from the second electrodialysis tank 312. adds an appropriate amount of replenishing water 362 and circulates it as the second dilution water 342 . Since the volume of the second concentrated water 322 increases during circulation, the increased amount is fractionated and supplied to the iodine-based substance acquisition device 351 as concentrated brine. Waste water 352 remaining after the iodine substance acquisition is discharged. In each electrodialysis tank, the addition of replenishing water and the addition of demineralized water to underground return water are optional.

In the multi-stage electrodialysis apparatus of demineralized water circulation-concentrated water circulation combined type as shown in FIG. Therefore, the iodide ions discharged in the underground return water 335 are reduced and the iodide ion yield is increased. Furthermore, by performing concentrated water circulation type electrodialysis in the second electrodialysis tank 312, the concentration rate of iodide ions in the concentrated brine can be increased.

The countercurrent feeding method is illustrated by the example of FIG. In the desalting compartments 1, 3 and the concentration compartments 2, 4 provided between the cation exchange membranes 11, 13, 15 and the anion exchange membranes 12, 14, raw water 21 supplied to the desalting compartments 1, 3 , 23 and the diluting water 31, 33 supplied to the concentrating chambers 2, 4 face each other across the ion exchange membrane. Desalted waters 22, 24 are obtained from the desalting compartments 1, 3 and concentrated waters 32, 34 are obtained from the concentrating compartments 2, 4 by electrodialysis.

The countercurrent feeding method has the advantage of efficient concentration of iodide ions with relatively low power consumption.

The co-current feeding method will be explained with the example of FIG. In the desalting compartments 1, 3 and the concentration compartments 2, 4 provided between the cation exchange membranes 11, 13, 15 and the anion exchange membranes 12, 14, raw water 21 supplied to the desalting compartments 1, 3 , 23 and the diluting water 31, 33 supplied to the concentrating chambers 2, 4 are made to flow in the same direction across the ion exchange membrane. Desalted waters 22, 24 are obtained from the desalting compartments 1, 3 and concentrated waters 32, 34 are obtained from the concentrating compartments 2, 4 by electrodialysis.
The co-current supply method has the advantage that the configuration of the electrodialyzer is simple and the operation thereof is simple.

The demineralized water discharged from each electrodialyzer of the electrodialyzer may have different salt concentrations. In that case, it is also possible to generate electricity by salinity difference using the difference in salt concentration between each desalinated water before mixing the desalted water discharged from each electrodialysis tank as underground return water, etc. and injecting it underground. is. As a result, for example, the generated power can be used to obtain iodine-based substances from underground brine, more specifically, to operate an electrodialysis apparatus, and the energy efficiency in obtaining iodine-based substances can be improved. can be excellent.

According to the concentration process by electrodialysis, not only is it possible to obtain concentrated brackish water containing a high concentration of iodide ions, but it is also possible to efficiently remove organic substances and polyvalent ions such as calcium and transition metal ions contained in the underground cans. can be removed. In other words, the concentrated brine obtained in the concentration process by electrodialysis contains a high concentration of iodide ions and a low content of unfavorable components such as organic substances and polyvalent ions such as calcium and transition metal ions. Become. Therefore, it is possible to more effectively prevent contamination and generation of insoluble matter in the subsequent iodine-based substance acquisition step. In particular, it is preferable to treat the desalted water in a non-oxidized state, because it is possible to prevent transition metal ions contained in the desalted water from being converted into oxides and rendered insoluble.

In particular, the desalted water produced in the concentration process in the present invention does not contain an oxidizing agent such as chlorine and has no oxidizing properties. Dissolved transition metal ions are not oxidized to form insoluble oxides, preventing flow blockage of subterranean brine. Therefore, the desalinated water discharged from the concentration process can be satisfactorily reduced and injected into an underground brine aquifer, particularly an underground brine aquifer from which underground brine has been pumped up, without causing flow obstruction. In addition, since the desalted water generated in the concentration process does not contain an oxidizing agent, it can be easily used for aquaculture, culture, and the like.

Demineralized water generated in the concentration step is preferably treated in a non-oxidized state. For this purpose, desalted water is handled in a non-oxidizing atmosphere such as nitrogen without exposing it to light, and oxidizing substances such as oxygen gas are excluded. The desalted water in a non-oxidizing state is a low-concentration salt water that does not have oxidizing properties, and has an oxidation-reduction potential of 0 mV or less, preferably 0 to -50 mV, in platinum electrode potential.

[4] Iodine-Based Substance Obtaining Step The iodine-based substance obtaining step is a step of obtaining an iodine-based substance from concentrated brine containing a high concentration of iodide salt.

Since the concentrated brine obtained using the electrodialyzer does not substantially contain organic substances such as fulvic acid, the iodide ions contained in the brine in the iodine-based substance acquisition process do not cause side reactions with these organic substances. This improves the acquisition rate of iodine-based substances.

In the present invention, in particular, molecular iodine (I ₂ ) can be obtained as molecular iodine from underground brine using an iodine-based substance obtaining apparatus. Since the concentrated brine in the present invention contains a high concentration of iodide ions, the yield of iodine relative to the iodide ions contained in the raw material underground brine is improved in the iodine-based substance acquisition step.

As a method for industrially producing iodine from concentrated brine containing a high concentration of iodine, known methods such as blowing-out method, resin adsorption method, absorption method, etc. can be used, and blowing-out method or absorption method is preferable. available for

The blowing-out method consists of an oxidation process in which an oxidizing agent such as chlorine or sodium hypochlorite is mixed with the concentrated brine obtained in the concentration process to generate molecular iodine, and air is blown into the concentrated brine after the oxidation process. A stripping step for vaporizing iodine, an absorption step for recovering iodine by bringing water containing a reducing agent such as sodium sulfite into contact with the air emitted from the stripping tower, and an oxidizing agent added to the resulting absorbent to deposit iodine. and a crystallization step for obtaining high-purity iodine. The oxidation by mixing with an oxidizing agent in the blowing-out method is carried out at a pH of concentrated brine near neutral, specifically pH 4 or more and 10 or less, preferably pH 5 or more and 9 or less, more preferably pH 5 or more and 8 or less. At least part of the wastewater discharged from the stripping column can be used as dilution water in electrodialysis in the concentration step.

In the resin adsorption method, the concentrated brine obtained in the concentration process is mixed with an oxidizing agent such as chlorine or sodium hypochlorite in an oxidation process to generate polyiodine ions such as I ₃ ^- , and the concentrated brine after the oxidation process is mixed. An adsorption step in which polyiodine ions are adsorbed by introducing them into a fluidized bed adsorption tower packed with anion exchange resin, and polyiodine ions adsorbed by the anion exchange resin are reduced with a reducing agent such as sodium sulfite to obtain diluted hydrochloric acid. An elution step of eluting iodine by contacting it with an appropriate eluent such as or saline, an oxidative concentration step of precipitating crude iodine by adding an oxidizing agent to the eluent, and a purification step of purifying crude iodine iodine production process. Oxidation with an oxidizing agent in the resin adsorption method is carried out at a pH of concentrated brine near neutral, specifically pH 4 or more and 10 or less, preferably pH 5 or more and 9 or less, more preferably pH 5 or more and 8 or less. At least part of the wastewater discharged from the adsorption tower can be used as dilution water in electrodialysis in the concentration step.

The absorption method takes advantage of the fact that molecular iodine is soluble in organic solvents, oxidizes iodide ions to generate molecular iodine, absorbs the generated iodine into the organic solvent, and removes it from the brine. It is a method of separation. Specifically, the pH of the concentrated brine obtained by the concentration process is adjusted to 4 or more and 8 or less, an oxidizing agent such as chlorine is added to generate molecular iodine, and an organic solvent is added to extract iodine into the organic layer. Then, an aqueous solution containing a reducing agent is added to re-extract iodine from the organic layer to the aqueous layer, and an oxidizing agent is added to precipitate iodine to obtain highly pure iodine.

Examples of organic solvents used as extraction solvents include hydrocarbons exemplified by hexane and heptane, ethers exemplified by diethyl ether and dibutyl ether, esters exemplified by butyl acetate, chloroform, carbon tetrachloride, and tetrachloroethylene. Examples thereof include halogenated hydrocarbons, carbon disulfide and the like. The organic solvent remaining after re-extracting the iodine can be reused as an extraction solvent. At least part of the waste water discharged from the extraction column can be used as dilution water in electrodialysis in the concentration step.

In the iodine-based substance obtaining step, hydroiodic acid can be obtained as the iodine-based substance from the concentrated brine. For example, using an electrodialysis tank, a cation exchange membrane partitions the anolyte supplied from the positive electrode side to the electrode chamber between a pair of positive electrode side and negative electrode side electrode chambers, followed by the first The anion exchange membrane, the first cation exchange membrane, the second anion exchange membrane, and the second cation exchange membrane are alternately and repeatedly provided, and the first anion exchange membrane and the first cation exchange membrane are alternately provided. The first anion-exchange membrane and the first cation-exchange membrane of an electrodialysis cell alternately partitioned into four sample chambers by an exchange membrane, a second anion-exchange membrane, and a second cation-exchange membrane. Concentrated brine is supplied to either between and between the second anion exchange membrane and the second cation exchange membrane, and the other is supplied with an acid solution that is an aqueous solution containing chlorine ions, A monovalent anion selective permeable membrane is used as an anion exchange membrane in contact with the concentrated brine, and hydroiodic acid is produced from iodide ions in the concentrated brine and hydrogen ions in the acid solution by double displacement electrodialysis. can be appropriately purified to produce hydroiodic acid.

Wastewater, which is brackish water remaining in the process of obtaining iodine-based substances, can be discharged into a river or the like after being subjected to environmental safety treatment as necessary. Moreover, at least part of the wastewater can be used as dilution water in electrodialysis in the concentration step.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited to these. For example, modifications such as changing conditions or adding other steps may be made within the scope of the gist of the present invention.

EXAMPLES The present invention will be described in more detail below using examples.
In the analysis, the sample was diluted with pure water, passed through a cation exchange resin column, and then ion chromatograph ("883 Professional" manufactured by Metrohm, with suppressor, Asap5 column 150 mm, Na ₂ CO ₃ (3 .2 mM) NaHCO ₃ (3.2 mM) mixture eluent).

(Example 1)
<Raw material brine>
Subterranean brine (sodium chloride content: 24 g/L, iodide ion content: 40 mg/L) pumped up from the ground at a depth of 1000m is stored as raw brine in a tank in a nitrogen atmosphere, and sand is made without exposing it to air. Filtration was performed using a filtration device.

<Concentration process>
Electrodialysis was carried out using a demineralized water circulation type electrodialysis apparatus equipped with three electrodialysis tanks connected in series as shown in FIG. Each electrodialysis tank has one electrode as an anode ⁽ positive electrode) and the other electrode as a cathode (negative electrode). 50 sets of ion-exchange membranes were arranged in the first electrodialysis tank 111, 10 sets in the second electrodialysis tank 112, and 3 sets in the third electrodialysis tank 113, respectively. The anion exchange membrane uses Selemion AMV-N (manufactured by AGC Co., Ltd.), which is an anion permselective membrane, and the cation exchange membrane is Selemion CSO (manufactured by AGC Co., Ltd.), which is a monovalent cation permselective membrane. ) was used. These ion-exchange membranes partitioned the inside of the electrodialyzer into a concentrating compartment and a desalting compartment.

A direct current of 42 V is applied to the first electrodialysis tank 111, 10 V to the second electrodialysis tank 112, and 5 V to the third electrodialysis tank 113 between the cathode and the anode of each electrodialysis tank. 111 was fed with the filtered underground brine 120 at a rate of 4000 cm ³ per minute. Ion-exchanged water was used as replenishing water.

First concentrated water 121 (sodium chloride content: 180 g/L, iodide ion content: 138 mg/L) obtained from first electrodialysis tank 111 is passed through second electrodialysis tank 112 at a rate of 1120 cm ³ per minute. did. The first demineralized water 131 (sodium chloride content: 8 g/L, iodide ion content: 3.6 mg/L) obtained from the first electrodialysis tank 111 at 3680 cm ³ /min was used as underground return water 135 .

The second concentrated water 122 (sodium chloride content: 180 g/L, iodide ion content: 608 mg/L) obtained from the second electrodialysis tank 112 is passed through the latter third electrodialysis tank 113 at 240 cm ³ per minute. did. Part of the second desalted water 132 (sodium chloride content 180 g/L, iodide ion content 10 mg/L) obtained from the second electrodialysis tank 112 is added to the underground return water 135 at 300 cm ³ per minute, The remainder was used as the first dilution water 141 and passed through the first electrodialysis tank 111 in a countercurrent flow at 800 cm ³ per minute.

The third concentrated water 123 obtained from the third electrodialysis tank 113 was supplied to the iodine-based substance acquisition device 151 at 50 cm ³ per minute. Part of the third demineralized water 133 (sodium chloride content 180 g/L, iodide ion content 10 mg/L) obtained from the third electrodialysis tank 113 is added to the underground return water 135 at 20 cm ³ per minute, The remainder was passed through the second electrodialysis tank 112 as the second dilution water 142 at a flow rate of 220 cm ³ per minute in a countercurrent flow.

The third concentrated water 123 (concentrated brine) supplied to the iodine-based substance acquisition device 151 has a sodium chloride content of 180 g/L, an iodide ion content of 2738 mg/L, and an iron ion content of less than 0.01 mg/L. , the manganese ion content was less than 0.01 mg/L, and the TOC, which is an index of organic matter concentration, was 3 mg/L.

<Iodine-based substance acquisition process>
A small amount of an aqueous solution of sulfuric acid was added to the concentrated brine obtained as described above to adjust the pH to 6, sodium hypochlorite was added, and the mixture was sprayed in the iodine diffusion tower, and at the same time, a large amount of air was blown thereinto. The air discharged from the upper part of the stripping tower was sent to the absorption tower and sufficiently brought into contact with the absorption liquid composed of sodium sulfite aqueous solution to obtain iodine (I ₂ ). The yield of iodine relative to the iodide ions contained in the raw material underground brine was 85%.

Part of the wastewater after iodine acquisition (sodium chloride content: 180 g/L, iodide ion content: 5 mg/L) was collected at 45 cm ³ per minute and combined with the third replenishing water 163 at 5 cm ³ per minute to obtain the third dilution water 143. The third electrodialysis tank 113 was flowed countercurrently, and the remaining waste water 152 was discharged at 5 cm ³ per minute.

(Example 2)
<Concentration process>
As in Example 1, filtered subterranean brine was used, and as shown in FIG. Electrodialysis was performed with the liquid flow in the bath being cocurrent. The configuration of the ion-exchange membranes is the same as in Example 1, but the number of sets of ion-exchange membranes is 50 in the first electrodialysis tank 111, 12 in the second electrodialysis tank 112, and 12 in the third electrodialysis tank 113. We made 3 groups.

A direct current of 42 V was applied to the first electrodialysis tank 111, 10 V to the second electrodialysis tank 112, and 5 V to the third electrodialysis tank 113 between the cathode and the anode of each electrodialysis tank. Ion-exchanged water was used as replenishing water.

Raw material subterranean brine 120 was passed through the first electrodialysis tank 111 at 4000 cm ³ /min, and first dilution water 141 (part of the second desalted water 132) was passed at 500 cm ³ /min. 900 cm ³ of first concentrated water 121 (sodium chloride content: 180 g/L, iodide ion content: 170 mg/L) was obtained from the first electrodialysis tank 111 . The first desalted water 131 (sodium chloride content 7 g/L, iodide ion content 5 mg/L) obtained from the first electrodialysis tank 111 at 3600 cm ³ /min was used as underground return water 235 .

The first concentrated water 121 was passed through the second electrodialysis tank 112 at 900 cm ³ /min, and the second diluted water 142 (part of the third desalted water 133) was passed at 110 cm ³ /min in parallel. 160 cm ³ of second concentrated water 122 (sodium chloride content 180 g/L, iodide ion content 1000 mg/L) were obtained. A portion of 500 cm ³ of the second desalted water 132 (sodium chloride content: 180 g/L, iodide ion content: 29 mg/L) obtained from the second electrodialysis tank 112 is used as first dilution water 141 for first electrodialysis. The remaining 350 ml of water after circulating in the tank 111 was used as the underground return water 135 .

The second concentrated water 122 was passed through the third electrodialysis tank 113 at 160 cm ³ /min, and the second diluted water 142 (part of the third desalted water 133) was passed at 110 cm 3 /min in cocurrent. 20 cm ³ of third concentrated water 123 (sodium chloride content 180 g/L, iodide ion content 6000 mg/L) were obtained. Part 110 cm ³ of the third desalted water 133 (sodium chloride content 180 g/L, iodide ion content 200 mg/L) obtained from the third electrodialysis tank 113 is used as the second dilution water 142 for the second electrodialysis. After circulating in the tank 112 , the remaining 50 ml was used as underground return water 135 .

The third concentrated water 223 (concentrated brine) supplied to the iodine-based substance acquisition device 251 has a sodium chloride content of 180 g/L, an iodide ion content of 6000 mg/L, and an iron ion content of less than 0.01 mg/L. , the manganese ion content was less than 0.01 mg/L, and the TOC, which is an index of organic matter concentration, was 3 mg/L.

<Iodine-based substance acquisition process>
A small amount of an aqueous solution of sulfuric acid was added to the concentrated brine obtained as described above to adjust the pH to 6, sodium hypochlorite was added, and the mixture was sprayed in the iodine diffusion tower, and at the same time, a large amount of air was blown thereinto. The air discharged from the upper part of the stripping tower was sent to the absorption tower and sufficiently brought into contact with the absorption liquid composed of sodium sulfite aqueous solution to obtain iodine (I ₂ ). The yield of iodine relative to the iodide ions contained in the raw material underground brine was 76%.

Part of the wastewater after iodine acquisition (sodium chloride content: 180 g/L, iodide ion content: 5 mg/L) was collected at 18 cm ³ per minute and combined with the third replenishing water 163 and 2 cm ³ per minute to obtain the third dilution water 143. The third electrodialysis tank 113 was cocurrently flowed, and the remaining waste water 152 was discharged at 2 cm ³ per minute.

(Example 3)
<Concentration process>
Using underground brine filtered in the same manner as in Example 1, electrodialysis was performed using a concentrated water circulation type electrodialysis apparatus equipped with three electrodialysis tanks connected in series as shown in FIG. The configuration of the ion-exchange membranes is the same as in Example 2, except that the number of ion-exchange membranes is 50 in the first electrodialysis tank 211, 5 in the second electrodialysis tank 212, and 1 in the third electrodialysis tank 213. is similar to

A direct current of 42 V is applied to the first electrodialysis tank 211, 6 V to the second electrodialysis tank 212, and 4 V to the third electrodialysis tank 213 between the cathode and the anode of each electrodialysis tank. Underground brine 220 as raw material was passed through 211 at 4000 cm ³ per minute. Ion-exchanged water was used as replenishing water.

A portion of the first concentrated water 221 (sodium chloride content: 180 g/L, iodide ion content: 400 mg/L) obtained from the first electrodialysis tank 211 is subjected to second electrodialysis at 390 cm ³ per minute. The brackish water was passed through the tank 212 and the remainder was circulated as the first dilution water 241 to the first electrodialysis tank 211 at 4000 cm ³ /min in a cocurrent flow. The first desalted water 231 (sodium chloride content: 240 g/L, iodide ion content: 8 mg/L) obtained from the first electrodialysis tank 211 at 4000 cm ³ /min was used as underground return water 235 .

A part of the second concentrated water 222 (sodium chloride content: 180 g/L, iodide ion content: 4000 mg/L) obtained from the second electrodialysis tank 212 is subjected to the third electrodialysis at 38 cm ³ per minute. The brackish water was passed through the tank 213, and the remainder was circulated as the second dilution water 242 to the second electrodialysis tank 212 at a rate of 390 cm ³ per minute in a cocurrent flow. Second demineralized water 232 (sodium chloride content: 180 g/L, iodide ion content: 80 mg/L) obtained from the second electrodialysis tank 212 at a rate of 390 cm ³ per minute is mixed with ground brine 220 to produce the first electric power. It was supplied to the dialysis tank 211 .

Of the third concentrated water 223 obtained from the third electrodialysis tank 213, 4 cm ³ /min is supplied to the iodine-based substance acquisition device 251, and the remainder is 38 cm ³ /min and the third replenishing water 263 4 cm /min. ³ and circulated as a third dilution water 243 in the third electrodialysis tank 213 in a cocurrent flow. A third demineralized water 233 (sodium chloride content: 180 g/L, iodide ion content: 800 mg/L) obtained from the third electrodialysis tank 213 at a rate of 38 cm ³ per minute is mixed with the first concentrated water 221 to obtain a third It was supplied to the secondary electrodialysis tank 212 as brackish water.

The third concentrated water 223 (concentrated brine) supplied to the iodine-based substance acquisition device 251 has a sodium chloride content of 180 g/L, an iodide ion content of 40000 mg/L, and an iron ion content of less than 0.01 mg/L. , the manganese ion content was less than 0.01 mg/L, and the TOC, which is an index of organic matter concentration, was 3 mg/L.

<Iodine-based substance acquisition process>
A small amount of an aqueous solution of sulfuric acid was added to the concentrated brine to adjust the pH to 6, sodium hypochlorite was added, and the mixture was sprayed in the iodine diffusion tower while blowing a large amount of air. The air exiting the upper part of the stripping tower was sent to the absorption tower and brought into sufficient contact with an absorption liquid consisting of an aqueous sodium sulfite solution to obtain molecular iodine. The yield of iodine relative to the iodide ions contained in the raw material underground brine was 76%.

Waste water 252 (sodium chloride content 180 g/L, iodide ion content 5 mg/L) after iodine acquisition was discharged at 4 cm ³ /min.

(Example 4)
<Concentration process>
Using underground brine filtered in the same manner as in Example 1, using an electrodialysis apparatus of demineralized water circulation-concentrated water circulation combination type equipped with three electrodialyzers branched and connected as shown in FIG. Electrodialysis was performed. The configuration of the ion-exchange membranes is the same as in Example 1, but the number of sets of ion-exchange membranes is 50 in the first electrodialysis tank 311, 14 in the second electrodialysis tank 312, and 14 in the third electrodialysis tank 313. 14 sets.

A direct current of 42 V was applied to the first electrodialysis tank 311, 14 V to the second electrodialysis tank 312, and 14 V to the third electrodialysis tank 313 between the cathode and the anode of each electrodialysis tank. Ion-exchanged water was used as replenishing water.

Raw material subterranean brine 320 was passed through the first electrodialysis tank 311 at 4000 cm ³ /min, and first dilution water 341 (part of the third demineralized water 333) was passed at 400 cm ³ /min in countercurrent. 800 cm ³ of first concentrated water 321 (sodium chloride content: 180 g/L, iodide ion content: 190 mg/L) was obtained from the first electrodialysis tank 311 . A first demineralized water 331 (sodium chloride content: 7 g/L, iodide ion content: 2.5 mg/L) obtained from the first electrodialysis tank 311 at 3600 cm ³ per minute was used as underground return water 335 .

A mixture of the first concentrated water 321 at 800 cm ³ per minute and the third concentrated water 323 at 300 cm ³ per minute was passed through the second electrodialysis tank 312 . The second replenishing water 362 was added to a part of the second concentrated water 322 at 25 cm ^{3 per minute, and 1125 cm 3 per} minute was circulated as the second dilution water 342 in a cocurrent flow. The remainder of the second concentrated water 322 was obtained as concentrated brine at 25 cm ³ per minute and supplied to the iodine-based substance acquisition device 351 . Second demineralized water 332 (sodium chloride content: 180 g/L, iodide ion content: 40 mg/L) obtained from second electrodialysis tank 312 was passed through third electrodialysis tank 313 at 1100 cm ³ per minute.

The second desalted water 332 is passed through the third electrodialysis tank 313 at 1100 cm ³ per minute, and part of the third desalted water 333 (sodium chloride content 160 g/L, iodide ion content 2.5 mg/L) 200 cm ³ per minute was returned to the third electrodialysis tank 313 in countercurrent as the third dilution water 343 . A portion of the third desalted water 333 of 400 cm ³ per minute was passed through the first electrodialysis tank in a countercurrent flow as the first dilution water 341 . The remaining 400 cm ³ per minute of the third demineralized water 333 was added to the underground return water 335 . Third concentrated water 323 (sodium chloride content 180 g/L, iodide ion content 140 mg/L) was obtained at 300 cm ³ per minute, mixed with first concentrated water 321 and passed through second electrodialysis tank 312. .

The second concentrated water 322, which is concentrated brine supplied to the iodine-based substance acquisition device 351, has a sodium chloride content of 180 g/L, an iodide ion content of 6000 mg/L, and an iron ion content of less than 0.01 mg/L. , the manganese ion content was less than 0.01 mg/L, and the TOC, which is an index of organic matter concentration, was 3 mg/L.

<Iodine-based substance acquisition process>
A small amount of an aqueous solution of sulfuric acid was added to the concentrated brine obtained as described above to adjust the pH to 6, sodium hypochlorite was added, and the mixture was sprayed in the iodine diffusion tower, and at the same time, a large amount of air was blown thereinto. The air discharged from the upper part of the stripping tower was sent to the absorption tower and sufficiently brought into contact with the absorption liquid composed of sodium sulfite aqueous solution to obtain iodine (I ₂ ). The yield of iodine relative to the iodide ions contained in the raw material underground brine was 93%.

Waste water 352 after iodine acquisition (sodium chloride content 180 g/L, iodide ion content 5 mg/L) was discharged at 25 cm ³ /min.

A method for obtaining an iodine-based substance according to the present invention is a method for obtaining an iodine-based substance from underground brine containing iodide ions, in which concentrated brine containing a high concentration of iodide ions is obtained from the underground brine. It includes a concentration step and an iodine-based substance obtaining step of obtaining an iodine-based substance from the concentrated brine.

According to the method for obtaining an iodine-based substance of the present invention, an iodine-based substance can be efficiently obtained by efficiently extracting iodide ions, which are valuable natural resources, from underground brine.
Therefore, the method for obtaining an iodine-based substance of the present invention has industrial applicability.

111,211,311 first electrodialysis tank 112,212,312 second electrodialysis tank 113,213,313 third electrodialysis tank 120,220,320 underground brine 121,221,321 first concentrated water 122,222, 322 Second concentrated water 123,223,323 Third concentrated water 131,231,331 First desalinated water 132,232,332 Second desalinated water 133,233,333 Third desalinated water 135,235,335 Underground return water 141 , 241, 341 First dilution water 142, 242, 342 Second dilution water 143, 243, 343 Third dilution water 161, 261, 361 First replenishment water 162, 262, 362 Second replenishment water 163, 263, 363 Three replenishing water 151, 251, 351 Iodine-based substance acquisition device 152, 252, 352 Waste water 271 First circulating water 272 Second circulating water 11, 13, 15 Cation exchange membrane 12, 14 Anion exchange membrane 1, 3 Desalination Chambers 2, 4 Concentration chambers 21, 23 Raw water in
22,24 demineralized water out
31,33 Dilution water in
32, 34 Concentrated water out
41, 42 electrode solution 51 negative electrode 52 positive electrode

Claims (7)

A method for obtaining an iodine-based substance from underground brine containing iodide ions without adding an oxidizing agent , comprising:
a concentration step of obtaining concentrated brine containing a high concentration of iodide ions from the underground brine;
an iodine-based substance obtaining step of obtaining an iodine-based substance from the concentrated brine;
including
A method for obtaining an iodine-based substance, wherein the concentration step is a step of obtaining the concentrated brine by electrodialyzing the underground brine using an electrodialysis apparatus having at least one electrodialysis tank . 2. The method for obtaining an iodine-based substance according to claim 1 , wherein said subterranean brine is treated in a non-oxidized state. 3. The method for obtaining an iodine-based substance according to claim 1 , wherein said electrodialysis apparatus is a multi-stage electrodialysis apparatus comprising two or more electrodialysis tanks connected to each other. In the concentration step, part of the desalted water obtained in at least one electrodialysis tank constituting the electrodialysis apparatus is transferred to the electrodialysis tank or an electrodialysis tank preceding the concentrated water flow direction relative to the electrodialysis tank. and the other part of the demineralized water is supplied to the demineralization chamber of the electrodialysis tank preceding the electrodialysis tank with respect to the flow direction of the concentrated water. The method for obtaining an iodine-based substance according to claim 3 , wherein the iodine-based substance is supplied by being added to water . In the concentration step, as the multistage electrodialysis device, a first electrodialysis tank for separating the subterranean brine as raw water into a first concentrated water and a first desalted water, and connected to the first electrodialysis tank a second electrodialysis tank for separating raw water containing the first concentrated water into a second concentrated water and a second desalted water; and a second electrodialysis tank connected to the second electrodialysis tank and serving as a raw material liquid using a device comprising a third electrodialysis cell for separating salt water into a third concentrated water and a third demineralized water,
The first concentrated water is combined with the third concentrated water to form raw water used in the second electrodialysis tank,
Part of the second concentrated water is combined with the second replenishing water to form the second dilution water used in the second electrodialysis tank,
supplying the other portion of the second concentrated water to an iodine-based substance acquisition device for acquiring the iodine-based substance;
Part of the third desalted water is combined with the first replenishment water to form the first dilution water used in the first electrodialysis tank,
5. The method for obtaining an iodine-based substance according to claim 3 or 4 , wherein the other part of said third desalted water is returned to underground water . 6. Acquisition of the iodine-based substance according to any one of claims 1 to 5 , wherein in the concentration step, a combination of a monovalent ion-selectively permeable cation exchange membrane and an anion exchange membrane is used in the electrodialysis tank. Method. The method for obtaining an iodine-based substance according to any one of claims 1 to 6 , wherein iodine is obtained in the iodine-based substance obtaining step.

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