JPH0724457A - Waste liquid treatment device - Google Patents

Abstract

PURPOSE:To provide a waste water treating device capable of removing harmful ion components in a waste water containing the ions and easy in maintenance. CONSTITUTION:The waste water treating device is constituted by connecting an anion exchange equipment 4 mounting a cation exchange membrane 7 for separating the waste water from a regenerating water and/or an anion exchange equipment 4 mounting an anion exchange mambrane 12 for separating the waste water from the regenerated water to a pipe 2 for discharging the waste water.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a waste liquid treatment device,
More specifically, the present invention relates to a waste liquid treatment apparatus capable of removing harmful ionic components in a waste liquid containing ions, which is generated when an analysis such as a water quality test is performed, and is easy to maintain.

[0002]

2. Description of the Related Art Conventionally, in various chemical devices such as industrial analyzers, acid or alkali is mixed with a sample and a predetermined analysis is performed, and then such acid or alkali is contained. Waste liquid is generated. If such a waste liquid containing an acid or an alkali is immediately discharged through the pipe, the pipe may be corroded within a short time or a pollution problem due to the waste liquid may occur. Therefore, in the usual case, in order to remove harmful ions from such waste liquid, an ion exchange resin cylinder is connected to the pipe.

The ion-exchange resin cylinder is filled with a bead-shaped ion-exchange resin. If the ion-exchange resin and the ion-containing waste liquid are in contact with each other for a long time, the ions of the ion-exchange resin will be discharged. Exchange capacity is reduced. Therefore, in the past, when the ion exchange capacity decreased, the ion exchange resin cylinder filled with the bead-shaped ion exchange resin was removed from the pipe, and the ion exchange resin cylinder filled with a new ion exchange resin was attached to the pipe. Fix it or
Alternatively, it is necessary to regenerate the ion exchange resin by circulating a regeneration liquid through a pipe connected to the ion exchange resin cylinder. Such an operation is extremely complicated and may pose a danger to the operator in some cases.
For example, in a waste liquid system in a nuclear power plant, since radioactive liquid is contained in the waste liquid, the work of exchanging the ion-exchange resin cylinder from the pipe for flowing the waste liquid involves radiation exposure.

The present invention has been made based on the above circumstances. That is, an object of the present invention is to provide a waste liquid treatment device which does not require replacement work of the ion exchange device and can remove harmful ions in the waste liquid under an unmanned environment.

[0005]

The invention according to claim 1 for solving the above-mentioned problems is a cation exchange device in which a pipe for discharging the waste liquid is loaded with a cation exchange membrane for separating the waste liquid and the regenerating liquid. And an anion exchange device loaded with an anion exchange membrane that separates the waste liquid and the regenerant liquid are connected in series, and the invention according to claim 2 is the pipe for discharging the waste liquid. A waste liquid treatment apparatus comprising a cation exchange device loaded with a cation exchange membrane for separating the waste liquid and the regeneration liquid, or an anion exchange device loaded with an anion exchange membrane for separating the waste liquid and the regeneration liquid. Is.

[0006]

In the waste liquid treatment apparatus of the present invention, the cation exchange device and the anion exchange device are connected in series to the pipe for circulating the waste liquid, or the cation exchange device or the anion exchange device is connected to the pipe for circulating the waste liquid. There is.
In the cation exchange device and the anion exchange device, the waste liquid and the regeneration liquid are separated by the ion exchange membrane. When the ion exchange membrane has a negative fixed charge and the waste fluid comes into contact with the ion exchange membrane, it selectively permeates cations in the waste fluid,
When the ion exchange membrane has a positive fixed charge, when the waste fluid comes into contact with the ion exchange membrane, the anions in the waste fluid are selectively permeated. As a result, harmful ions in the waste liquid are selectively removed.

[0007]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows a waste liquid treatment apparatus which is an embodiment of the present invention. As shown in FIG.
A cation exchange device 3 and an anion exchange device 4 are connected in series to a pipe 2 for discharging the waste liquid.

In this cation exchange device 3, a pipe 2 is connected to one end of a cylindrical case body 5 and the other end is connected to an anion exchange device 4 via a connecting pipe 6. A cation exchange membrane 7 is loaded in the cylindrical case body 5. In addition, the first regenerant liquid supplied from the external first chemical tank 8 is supplied into the case body 5 from the inflow port of the peripheral side surface on the other end side of the case body 5, and is circulated in the case body 5. The regenerant liquid is discharged from the outlet on the peripheral side surface on one end side of the case body 5. In addition, 9 is the first after ion exchange
It is a receiving tank that stores the regenerating liquid.

In this anion exchange device 4, the connection pipe 6 is connected to one end of a cylindrical case body 10 and the discharge pipe 11 is connected to the other end. An anion exchange membrane 12 is loaded in the cylindrical case body 10. In addition, the second regenerant liquid supplied from the external second chemical tank 13 is supplied into the case body 10 from the inflow port of the peripheral side surface on the other end side of the case body 10, and the second regenerant liquid flowing in the case body 10 is supplied. The regenerating liquid is discharged from the outlet on the peripheral side surface on one end side of the case body 10. Incidentally, 14 is a receiving tank for containing the first regenerated liquid after ion exchange.

Here, as the cation exchange membrane 7,
Mention may be made of porous membranes with a large number of anionic groups attached. The anion exchange membrane may be a porous membrane having a large number of cation groups bonded.
As the anionic group, a carboxyl group (-COO-),
A sulfonic acid group (-SO ₃ -) can be mentioned. Examples of cationic groups include quaternary ammonium bases. As the cation exchange membrane, other than this, a polymer material that binds an amino group can be used.

As the cation exchange membrane and the anion exchange membrane that can be used in the present invention, commercially available ion exchange membranes can be appropriately adopted. Examples of commercially available ion exchange membranes include hydrocarbon ion exchange membranes, fluorine ion exchange membranes such as Nafion (registered trademark), Flemion (registered trademark), and Neosept (registered trademark). . The type of ion exchange membrane to be used can be appropriately selected according to the ion species to be removed in the waste liquid.

The shape of the ion exchange membrane of the cation exchange membrane and the anion exchange membrane is not particularly limited, and examples thereof include a hollow fiber shape, a flat plate shape, a tubular shape, and a spiral shape.

The first regenerant liquid supplied to the cation exchange device is supplied from the first chemical tank. The first regenerant can be appropriately selected depending on the ionic species to be removed in the waste liquor. For example, when the cation species to be removed from the waste liquor is Na ions, a dilute sulfuric acid aqueous solution is used as the second regenerant. Can be mentioned.

[0014] Thus, for example, is contacted through the waste liquid and the cation exchange membrane and a dilute sulfuric acid aqueous solution as a first regenerant containing Na ₂ CO _3, as shown in FIG. 2, Na ⁺
Selectively pass through the cation exchange membrane and move into the first regenerant, and hydrogen ions in the first regenerant move into the waste solution through the cation exchange membrane. As a result, the waste liquid that passed through this cation exchange device did not contain Na ₂ CO ₃ and H ₂
It will contain CO ₃ .

The second regenerant liquid supplied to the anion exchange device is supplied from the second chemical tank. The second regenerant can be appropriately selected according to the ionic species to be removed in the waste liquor. For example, when the anion species to be removed from the waste liquor is CO ₃ ⁻ , a caustic soda aqueous solution is used as the second regenerant. Can be mentioned.

Thus, when the waste liquid containing, for example, Na ₂ CO ₃ and the aqueous solution of caustic soda as the second regenerant are brought into contact with each other through the anion exchange membrane, as shown in FIG.
O ₃ ^-2 selectively permeates the anion exchange membrane 7 and moves into the second regenerant, and the hydroxide ion in the second regenerant moves through the anion exchange membrane 7 into the waste liquid. As a result, the waste liquid that has passed through the cation exchange device 3 does not contain Na ₂ CO ₃ but contains NaOH.

According to the apparatus of this embodiment, the cation in the waste liquid is moved into the first regenerant liquid by flowing the waste liquid into the anion exchange device, and the anion in the waste liquid is moved into the first regeneration liquid by passing the waste liquid into the anion exchange device. 2 Move into regeneration solution. Therefore, harmful cations and anions are removed from the waste liquid, so no pollution problem occurs even if the waste liquid is discharged into a river. Moreover, since the anion exchange device and the ion exchange membrane loaded in the anion exchange device are constantly regenerated by the first regenerant and the second regenerant, the cations in the ion exchange resin cylinder filled with the bead-shaped ion exchange resin are When the ion exchange capacity of the exchange resin is reduced, it is not necessary to replace the ion exchange resin cylinder or to regenerate the ion exchange resin. Therefore, in this embodiment, the anion exchange device and the anion exchange device can be left semi-permanently connected to the pipe.

In addition to the above embodiment, it is possible to connect either the anion exchange device or the anion exchange device to the pipe. Whether or not one or both of the anion exchange device and the anion exchange device should be connected to the pipe can be appropriately determined depending on the ion species to be removed from the waste liquid.

[0019]

According to the present invention, the ionic species in the waste liquid can be efficiently removed, and the work of exchanging the ion exchange device can be omitted. Therefore, it is possible to provide a waste liquid treatment apparatus capable of significantly reducing the labor required for maintenance work.

[Brief description of drawings]

FIG. 1 is an explanatory view showing a waste liquid treatment apparatus which is an embodiment of the present invention.

FIG. 2 is an explanatory view showing an ion exchange action by a cation exchange device.

FIG. 3 is an explanatory view showing an ion exchange action by the anion exchange device.

[Explanation of symbols]

 1 Waste Liquid Treatment Device 2 Piping 3 Cation Exchanger 4 Anion Exchanger 7 Cation Exchange Membrane 12 Anion Exchange Membrane

Claims (2)

[Claims] 1. A cation exchange device having a cation exchange membrane for separating the waste liquid and the regenerating liquid and an anion exchange device having an anion exchange membrane for separating the waste liquid and the regenerating liquid are connected in series to a pipe for discharging the waste liquid. A waste liquid treatment device characterized by being connected. 2. A cation exchange device loaded with a cation exchange membrane for separating the waste liquid and the regeneration liquid or an anion exchange device loaded with an anion exchange membrane for separating the waste liquid and the regeneration liquid is connected to a pipe for discharging the waste liquid. A waste liquid treatment device characterized by the following.