JPH06337A - Device for recovering metal ion from solution - Google Patents

Abstract

PURPOSE:To efficiently remove the concd. metal ion by concentrating metal ion from a large amt. of soln. contg. the scarce metal ion. CONSTITUTION:This metal ion recovery device is provided with a recovery chamber 1 in which a metal ion-contg. soln. 7 is demarcated by a molecular sieve membrane 2. A water-soluble chelating polymer is added to the chamber 1. The molecular sieve membrane 2 has a sieve opening permeable to the metal ion contained in the soln. 7 and impermeable to the chelating polymer. A metal ion recovery circulating passage consists of the chamber 1 and a circulating pump 3. The metal ion in the soln. 7 is passed through the membrane 2, combined with the chelating polymer in the chamber 1 and separated.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for separating and recovering metal ions dissolved in a solution. In particular, the present invention relates to a metal ion recovery device mainly used for removing harmful metal ions from factory wastewater or recovering effective metal ions from seawater.

[0002]

2. Description of the Related Art Separation or concentration of metal ions from a solution is an important problem in terms of pollution environment and resources. For example, it is desired to remove harmful metal ions such as mercury from factory wastewater or to effectively recover valuable metal ions such as magnesium, uranium and rare earth metal ions from seawater.

Conventionally, as a method for separating or concentrating metal ions, a method by adsorption using an adsorbent, an ion exchange resin, a chelate resin, etc. (JP-A-64-80408), a reagent that reacts with an oil phase or metal ions A device for extracting metal ions from an aqueous solution by an oil phase in which
Alternatively, a device for precipitating metal ions by reaction is used.

A separation method using a liquid membrane in which a porous membrane is impregnated with an oil phase in which a reagent that reacts with metal ions is impregnated,
Membrane separation methods using functional membranes having functional groups have also been studied. Furthermore, a method has been developed in which a chelating agent is added to the treatment liquid by using an amphoteric ion exchange resin to form a complex with a specific metal ion to prevent membrane permeation and enhance separation of the metal ion (special feature (Kaisho 63-147504).

[0005]

However, since these conventional devices add an adsorbent, a chelating agent, etc. to the metal ion-containing solution, when a large amount of the metal ion-containing solution is used, such as factory wastewater and seawater, There is a drawback that the amount of the additive is considerably large and a running cost is high.

The present invention was developed for the purpose of solving this drawback, and an important object of the present invention is to recover metal ions by concentrating them from a large amount of a solution containing a dilute concentration of metal ions. It is to provide a metal ion recovery device.

[0007]

Means for Solving the Problems In the study of metal ion separation and concentration using a molecular sieve membrane and a chelate polymer, the present inventors have investigated the membrane permeation rate and found that a chelate polymer of a large molecule that cannot permeate the membrane is found. When used,
It has been found that the metal ions pass unilaterally through the membrane and the trapped metal ions do not reverse permeate through the membrane. The present invention is
It was completed based on the above findings, and its gist is
A chelate polymer is brought into contact with a metal ion-dissolved solution through a molecular sieve membrane, and the metal ion that has permeated through the molecular sieve membrane is bound to the chelate polymer to prevent reverse permeation of the metal ion, thereby recovering the metal ion. Is.

The metal ion bound to the chelate polymer can be dissociated from the chelate polymer and recovered by, for example, changing the pH of the solution in contact with the chelate polymer. The dissociated metal ions can be eluted and collected in an acidic solution. The chelate polymer thus activated by dissociating the metal ions can be repeatedly used again.

In order to achieve this, the metal ion recovery device of the present invention has the following structure. (A) The recovery device is provided with a recovery chamber 1 in which the metal ion-containing solution is partitioned by a molecular sieve membrane. (B) A water-soluble chelate polymer that binds to metal ions in the metal ion-containing solution is added to the recovery chamber 1. For the water-soluble chelating polymer, for example, the following metal ion scavengers are used. Polyacrylic acid and its derivative Poly-α-acetylaminoacrylic acid Polyacrylic acid Polyacrylic acid salt (for example, sodium polyacrylate) Polyvinyl alcohol Polyacrylamide and its derivative Polyalkyl oxide Polyethylene oxide Polypropylene oxide (c) Molecular sieve membrane 2 , The metal ions of the metal ion-containing solution can be transferred to the recovery chamber 1, but the metal ions bound to the chelate polymer in the recovery chamber 1 do not return to the metal ion-containing solution again, so that the metal ions contained in the metal ion-containing solution Is designed to pass through but not the chelate polymer. As the molecular sieve film 2, the following items are used. Also,
As the molecular sieve membrane 2, a dialysis membrane having a cut-off molecular weight of 3000 or more is suitable. Porous Cellulose Membrane Hollow Fiber Membrane Cellulose Acetate Membrane Synthetic Polymer Membrane Polyacrylonitrile (PAN) Polymethyl Methacrylate (PMMA) Ethylene-Vinyl Alcohol Copolymer (EVA) (d) A circulation pump 3 is connected to the recovery chamber 1. There is. (E) The recovery chamber 1 and the circulation pump 3 constitute a metal ion recovery circulation path. (F) The metal ions contained in the metal ion-containing solution are
It is configured such that it permeates through the molecular sieve membrane 2 and binds with the chelate polymer in the recovery chamber 1 to be separated.

[0010]

Embodiments of the present invention will be described below with reference to the drawings. However, the examples shown below exemplify a metal ion recovery apparatus for embodying the technical idea of the present invention, and the apparatus of the present invention has the following materials, shapes, structures, and arrangements of components. It is not specific to the structure of. The device of the present invention can be variously modified within the scope of the claims.

Further, in this specification, for easier understanding of the claims, the numbers corresponding to the members shown in the embodiments are referred to as "claims" and "means for solving the problems." It is added to the members shown in "Column". However, the members shown in the claims are not limited to the members of the embodiment.

In the apparatus for recovering metal ions from a solution, a chelate polymer is brought into contact with a metal ion-dissolved solution through a molecular sieve membrane. The metal ion contained in the metal ion-containing solution permeates the molecular sieve membrane and bonds with the chelate polymer. The metal ions bound to the chelate polymer become large and cannot pass through the molecular sieve membrane. The metal ion bound to the chelate polymer can be dissociated from the chelate polymer and recovered by changing the pH of the solution contacted through the molecular sieve membrane. The dissociated metal ions can be eluted and collected in an acidic solution. The chelate polymer thus activated by dissociating the metal ions can be repeatedly used again.

In this way, in order to separate the metal ions, the metal ion recovery device shown in FIG. 1 comprises a metal ion recovery section 4, a metal ion separation section 5 and a chelate polymer liquidity adjustment section 6. It is configured.

The metal ion recovery unit 4 is provided with a recovery chamber 1 in which the metal ion-containing solution 7 is partitioned by the molecular sieve membrane 2. The recovery chamber 1 has a cylindrical shape, and a water-soluble chelate polymer that binds to metal ions in the metal ion-containing solution 7 is added to the recovery chamber 1. Molecular sieve membrane 2
The metal ions in the metal ion-containing solution 7 can be transferred to the recovery chamber 1, but the metal ions bound to the chelate polymer in the recovery chamber 1 are transferred to the metal ion-containing solution 7 so as not to return to the metal ion-containing solution 7 again. It is designed with a sieve mesh that allows the contained metal ions to pass but not the chelating polymer. As the molecular sieve membrane 2, the following or can be used. These molecular sieve membranes 2
Is suitable as a dialysis membrane having a molecular weight cutoff of 3000 or more. Porous cellulose membrane Hollow fiber membrane Cellulose acetate membrane Synthetic molecular membrane below Polyacrylonitrile (PAN) Polymethylmethacrylate (PMMA) Ethylene-vinyl alcohol copolymer (EVA)

As the water-soluble chelate polymer added to the recovery chamber 1, the following metal ion scavengers can be used. The following polyacrylic acid and derivatives thereof Polyacrylic acid Polyacrylic acid salt (for example, sodium polyacrylate) Poly-α-acetylaminoacrylic acid Polyvinyl alcohol Polyacrylamide and its derivatives Polyalkyl oxide Polyethylene oxide Polypropylene oxide

The recovery chamber 1 includes a metal ion separation section 5
The exhaust chamber 8, the exhaust chamber 8 is connected to the adjusting chamber 9, and the circulation pump 3 is connected between the adjusting chamber 9 and the recovery chamber 1. The recovery chamber 1, the discharge chamber 8, the adjustment chamber 9, and the circulation pump 3 constitute a metal ion recovery circulation path.

The recovery chamber 1 is arranged in a recovery tank 10 to which the metal ion-containing solution 7 is supplied. The metal ions recovered in the recovery chamber 1 and bound to the chelate polymer are discharged from the recovery circulation path in the metal ion separation unit 5.

The metal ion separating section 5 has a separation tank 11 filled with an acidic solution and a discharge chamber 8 disposed in the acidic solution. As the discharge chamber 8, the molecular sieve membrane 2 made of the same material as that of the recovery chamber 1 is used. When the separation tank 11 is filled with a hydrochloric acid solution of 2 N or more, most of the chelate polymer-bonded metal ions in the discharge chamber 8 can be separated. Therefore, the metal ions can be separated with a slight acidic solution. As the acidic solution, not only hydrochloric acid but all acidic solutions such as sulfuric acid and nitric acid can be used. An acidic solution is supplied to the separation tank 11 and the acidic solution in which metal ions are collected is discharged.

The chelate polymer from which the metal ions have been separated in the separation tank 11 is further adjusted in liquidity in the adjustment tank 12. Distilled water is supplied to the adjusting tank 12 and discharged from the bottom.

Recovery tank 10, separation tank 11, and adjustment tank 12
An agitating blade 13 for agitating the solution is provided at the bottom of the agitator, and a motor is connected to the agitating blade 13.

3 to 6 show the state in which SmCl ₃ is separated by using the experimental apparatus shown in FIG. In FIG. 3, metal ions were separated under the following conditions. The amount of the metal ion-containing solution 7 was 300 ml. The chelating polymer is 20 ml of poly-α.
-Acetylaminoacrylic acid was used. The concentration of poly-α-acetylaminoacrylic acid is 10
It was set to mmol / liter. (Hereinafter, millimoles / liter is abbreviated as mM.) In the recovery chamber 1, a cellulose membrane having a cut-off molecular weight of 12000 was used with an inner diameter of 8 mmφ and a length of 150 mm. The flow rate in the recovery chamber 1 is 1.6 ml /
Minutes A stir bar 14 is provided at the bottom of the recovery tank 10
Rotate at rpm.

The curves A, B and C in FIG. 3 are, in order, SmC
It shows a decrease in the concentration when the concentration of l ₃ was 0.2 mM, 0.1 mM and 0.05 mM. As shown in this figure, it can be seen that the concentration of SmCl ₃ decreased with the passage of time and was recovered in the recovery chamber 1.

FIG. 4 shows changes in the concentration of the metal ion-containing solution 7 when the concentration of poly-α-acetylaminoacrylic acid used as a chelate polymer was changed. As shown in this figure, by setting the concentration of poly-α-acetylaminoacrylic acid to 20 mM, SmCl ₃ was extremely effectively recovered in 5 hours.

Further, FIG. 5 shows changes in the concentration of the metal ion-containing solution 7 when the flow rate in the recovery chamber 1 is changed. As shown in this figure, there was almost no difference in recovery time even if the flow rate was changed within this range.

FIG. 6 shows a state in which the metal ion concentration of the metal ion-containing solution 7 decreases when the stirring speed of the metal ion-containing solution 7 is changed. As shown in this figure, even if the stirring speed of the metal ion-containing solution 7 is changed,
The rate of decrease in concentration was almost unchanged.

[0026]

The metal ion recovery apparatus of the present invention is provided with a recovery chamber in which the solution containing metal ions is partitioned by a molecular sieve membrane without adding a chelate polymer or the like to the solution in which the metal ions are dissolved. The chelate polymer solution can be circulated to recover the metal ions. The metal ions contained in the metal ion-containing solution permeate the molecular sieve membrane and bond with the chelate polymer in the recovery chamber. The metal ion-containing solution combined with the chelate polymer has a large molecular weight and cannot reversely permeate through the molecular sieve membrane, and is recovered in the recovery chamber. That is, the metal ion-containing solution permeates the molecular sieve membrane only toward the recovery chamber and does not permeate in the opposite direction. The metal ions that have permeated the recovery chamber and bound to the chelate polymer can be dissociated from the chelate polymer by a method such as adjusting the pH. Therefore, the metal ion recovery device of the present invention is characterized in that it is possible to efficiently separate metal ions from a large amount of metal ion-containing solution with a chelate polymer. If necessary, the chelate polymer can be effectively reused many times by dissociating the metal ion from the chelate polymer by a method such as pH adjustment if necessary.

Therefore, the apparatus of the present invention separates harmful metal ions such as mercury contained in factory wastewater from wastewater pollution and further separates a large amount of metal ions such as magnesium contained in seawater. It is also possible to effectively use the same and to separate expensive rare earth metals such as samarium.

[Brief description of drawings]

FIG. 1 is a sectional view of an apparatus for recovering metal ions from a solution showing an embodiment of the present invention.

FIG. 2 is a sectional view of the metal ion recovery device used in the experiment.

FIG. 3 is a graph showing changes with time in SmCl ₃ decrease using the apparatus shown in FIG.

FIG. 4 is a graph showing a state in which SmCl ₃ is lowered using the apparatus shown in FIG.

FIG. 5 is a graph showing a state where SmCl ₃ is lowered using the apparatus shown in FIG.

FIG. 6 is a graph showing a state where SmCl ₃ is lowered using the apparatus shown in FIG.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Recovery chamber 2 ... Molecular sieve membrane 3 ... Circulation pump 4 ... Metal ion recovery part 5 ... Metal ion separation part 6 ... Liquid property adjustment part 7 ... Metal ion containing solution 8 ... Discharge chamber 9 ... Adjustment chamber 10 ... Recovery tank 11 ... Separation tank 12 ... Adjusting tank 13 ... Stirring blade 14 ... Stirrer

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[Procedure amendment]

[Submission date] August 29, 1992

[Procedure Amendment 1]

[Document name to be corrected] Drawing

[Name of item to be corrected] Figure 5

[Correction method] Change

[Correction content]

[Figure 5]

[Procedure Amendment 2]

[Document name to be corrected] Drawing

[Name of item to be corrected] Figure 6

[Correction method] Change

[Correction content]

[Figure 6]

Claims (1)

[Claims] 1. A device for recovering metal ions from a solution having all of the following constitutions (a) to (f): (A) A recovery chamber (1) is provided by partitioning the metal ion-containing solution with a molecular sieve membrane (2). (B) A water-soluble chelating polymer is added to the recovery chamber (1). (C) The molecular sieving membrane (2) is designed to have a sieve mesh that allows passage of metal ions contained in the metal ion-containing solution but not passage of chelate polymers. (D) A circulation pump (3) is connected to the recovery chamber (1). (E) The recovery chamber (1) and the circulation pump (3) constitute a metal ion recovery circulation path. (F) The metal ions contained in the metal ion-containing solution are
It is configured so that it permeates through the molecular sieve membrane (2) and binds to the chelate polymer in the recovery chamber (1) to be separated.