KR20110047710A - Electrosorptive Water Treatment Apparatus - Google Patents

Abstract

PURPOSE: An electro-absorptive water treatment system is provided to prevent the electrolysis of raw water in a stack module by forming a double flow path with the opposite flowing direction of the raw water inside the stack module. CONSTITUTION: An electro-absorptive water treatment system comprises stack modules(200) obtained by unit cells laminated into multiple layers. The stack modules include main flow paths(P1) and sub flow paths(P2) with the opposite flowing directions. The electro-absorptive water treatment system additionally includes an electric conductivity meter(400) measuring the electric conductivity value by being installed around the main flow paths, and a controller(500) connected to the electric conductivity meter.

Description

Electrosorption Water Treatment Apparatus {Electrosorptive Water Treatment Apparatus}

The present invention relates to an electrosorption water treatment device, and more particularly, to an electrosorption water treatment device in which two flow paths having opposite flows of raw water are formed in a stack module of a reactor.

In general, there are various methods for removing inorganic ions in water such as agglomeration method, ion exchange resin method, reverse osmosis membrane method, electrodialysis, evaporative condensation method, electrophoresis. However, these methods are difficult in operation and maintenance, such as the complexity of the processing apparatus and the energy consumption, and the problem of the generation of secondary polluted water.

In order to solve this problem, a water treatment method using the electrochemical adsorption / desorption principle has been developed and used. This method is partially applied to the treatment of raw water with low inorganic ion concentration, but there are many technical problems in treating brackish water or sea water having high concentration of inorganic ion.

Conventionally, an electrosorption water treatment apparatus for treating raw water containing high concentration inorganic ions is shown in FIG. 1.

Electrosorption type water treatment apparatus according to the prior art, comprises a raw water storage tank 10, a stack module 20, and a treated water storage tank (30). The stack modules 20 are connected in multiple stages, and each stack module 20 has only one flow path w for flowing raw water in only one direction, and the flow paths formed in each stack module 20 are connected to each other. do.

According to the electroadsorption water treatment apparatus according to the prior art configured as described above, the raw water supplied from the raw water storage tank 10 flows along the flow path formed in the stack module 20 of the multi-stage and after the inorganic ions are removed from each stack module 20 It is transferred to the treated water storage tank 30.

However, according to the conventional electroabsorption water treatment device having the configuration and action as described above, the saturation of the inorganic inorganic ions proceeds from the stack module closest to the raw water storage tank to the saturation, and then sequentially in the next stack module. Treatment of inorganic ions takes place.

When the desalination reaction is carried out as described above, the concentration of inorganic ions is excessively low in the stack modules except for the stack module at the front end, so that the electrochemical redox reaction, that is, not the adsorption reaction, occurs in the electrolysis of raw water. As the electrolysis of raw water proceeds, excessive energy consumption occurs and the efficiency of the desalination reactor is greatly reduced.

In addition, in the regeneration process of the desalination reactor stack module, the regeneration waste liquid of the stack module of the front end is used as regeneration water of the next stage, and thus there are various problems such as the complete regeneration of the stack module is difficult and a long regeneration time is required.

An object of the present invention was devised to solve the above problems, to prevent the electrolysis of raw water in the stack module during the treatment of brackish water and seawater having a high concentration of inorganic ions in the water, regeneration during the regeneration process It is to provide an electrosorption water treatment device that can improve the efficiency.

In order to achieve the above object, the present invention provides an electrosorption type water treatment device comprising: a stack module formed by stacking unit cells, wherein the stack module includes a main flow path and an auxiliary flow path in which raw water flows in opposite directions. Is formed.

The stack module is provided with a plurality is connected in the vertical direction, or side by side.

An electrical conductivity meter for measuring an electrical conductivity value is installed on the main flow path side of the stack module, and the electrical conductivity meter is connected to a controller.

A power supply device is connected to each stack module to apply a voltage.

The controller is electrically connected to the flow rate control pump to control the flow of raw water through the auxiliary flow path.

The main flow path may flow along one side of the stack module, and the auxiliary flow path may flow along the other side of the main flow path.

The main flow passage and the auxiliary flow passage may alternately flow along one side and the other side, and may be configured to intersect in a space of a unit cell provided in each stack module.

According to the electrosorption water treatment device according to the present invention, in order to treat raw water containing high concentration of inorganic ions in the water, the flow path of the stack module is composed of a double flow path of the fluid direction opposite to each other and the power supply device for each stack module By providing a, it is possible to prevent the phenomenon of the electrolysis reaction of the raw water in the stack modules located at the rear end can greatly increase the water treatment efficiency, and can greatly increase the regeneration efficiency during the regeneration process.

In addition, in the production of freshwater from raw water containing a high concentration of inorganic ions in water, energy consumption is significantly lower than that of the conventional evaporation or reverse osmosis membrane which is widely used.

In addition, since the raw water flowing along the auxiliary flow path is introduced into the raw water storage tank again, the inorganic ion treatment load of the electrosorption water treatment device can be greatly reduced.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a schematic diagram showing an electrosorption water treatment apparatus according to an embodiment of the present invention.

Electrosorption type water treatment apparatus according to the invention, the raw water storage tank 100, the stack module 200, the treated water storage tank 300, the electrical conductivity meter 400, the controller 500.

The raw water storage tank 100 stores water supplied from brackish water or seawater (hereinafter referred to as 'raw water') and supplies it to the stack module 200.

The treated water storage tank 300 receives and stores purified raw water from which inorganic ions contained in raw water are removed while passing through the stack module 200.

The stack module 200 adsorbs and separates inorganic ions contained in raw water, and a plurality of stack modules 200 are connected in series, i.e., up and down, and the number thereof may be adjusted according to the concentration of the inorganic ions. Connection form of the stack module 200 may be connected in parallel, that is, side by side.

The interior of the stack module 200 is composed of one or a plurality of electrochemical unit cells. In the stack module 200, two flow paths P1 and P2 flowing in opposite directions, that is, a main flow path P1 and an auxiliary flow path P2 are formed.

The electrical conductivity meter 400 is installed on the main flow path P1 to measure the conductivity value of the raw water flowing along the main flow path P1 and transmit the measured conductivity value to the controller 500.

The controller 500 receives a signal of the conductivity value of the raw water transmitted from the electrical conductivity meter 400 and then sends a command signal to the flow rate control pump 600 according to a pre-input internal command to flow the main flow path P1. The optimum flow rate is controlled to flow along the auxiliary flow path P2 within a range of 0 to 50%.

3 is a view illustrating a power supply device connected to each stack module of FIG. 2.

The electrosorption water treatment device according to the present invention further includes a power supply device 700.

The power supply device 700 is provided for each stack module 200 to apply voltage to each stack module 200 according to the inorganic ion concentration, flow rate, etc. of the feed water supplied from the raw water storage tank 100. do. In this case, only one power supply device 700 may be provided to apply voltage to the plurality of stack modules 200.

4 is a cross-sectional view of a cell constituting each stack module of FIG. 2.

The unit cell 210 constituting the stack module 200 includes adsorption electrodes 211 and 212, ion exchange membranes 213 and 214, spacers 215, and current collectors 216 and 217. do.

The adsorption electrodes 211 and 212 are composed of an anion carbon electrode 211 that directly adsorbs and separates anions in water, and a cationic carbon electrode 212 that adsorbs and separates cations.

The ion exchange membranes 213 and 214 are composed of an anion exchange membrane 213 for selectively passing anions in water and a cation exchange membrane 214 for selectively passing cations. The anion exchange membrane 213 is in contact with the anion carbon electrode 211, and the cation exchange membrane 214 is in contact with the cationic carbon electrode 212.

The spacer 215 forms a flow path of raw water, is formed in the form of a net, and is surrounded by a gasket (not shown) to prevent the inflow and outflow of raw water to the outside.

The current collectors 216 and 217 are applied with a DC voltage supplied from the power supply device 700 to apply a voltage to each of the carbon electrodes 211 and 212. In surface contact with the same, a DC voltage of 1 to 3 V is applied to the entire carbon electrodes 211 and 212 evenly.

5 is a cross-sectional view illustrating an example in which a flow path is formed in the stack module of FIG. 2, and FIG. 6 is a cross-sectional view illustrating another example in which a flow path is formed in the stack module of FIG. 2.

Each of the stack modules 200 has a main flow path P1 and an auxiliary flow path P2 flowing in opposite directions. As shown in FIG. 5, the main channel P1 may flow along one side of the stack module 200, and the auxiliary channel P2 may flow along the other side of the main channel P1. In addition, as shown in FIG. 6, the main flow path P1 and the auxiliary flow path P2 are configured to flow alternately with one side and the other side of the stack module 200 based on the spacer 215 of the unit cell 210. It may be configured to cross each other at 215.

Hereinafter will be described in detail the operation of the electrosorption water treatment device according to an embodiment of the present invention configured as described above.

First, raw water containing a high concentration of inorganic ions flows from the raw water storage tank 100 along the main flow path P1 by a raw water transfer pump (not shown), and in the process, each carbon electrode of the unit cell 210 ( 211) and 212, inorganic ions are adsorbed and separated. In this process, a voltage of 1 to 3 V is applied from the power supply device 700 to the current collectors 216 and 217 of each unit cell 210, and the voltages applied to the current collectors 216 and 217 are different from each other. It is applied to each carbon electrode (211, 212) in contact.

The raw water supplied from the raw water storage tank 100 flows along the main flow path P1 formed at one side of each stack module 200 and is sent to the spacer 215 of the unit cell 210 constituting each stack module 200. The negative ions of the inorganic ions contained in the raw water are adsorbed to the anion carbon electrode 211 through the anion exchange membrane 213, and the cation is adsorbed to the cationic carbon electrode 212 through the cation exchange membrane 214. Raw water processed while passing through each stack module 200 is stored in the treated water storage tank 300.

As described above, the electrical conductivity value is measured in the electrical conductivity meter 400 installed on the main flow path P1 in the course of raw water flowing along the main flow path P1, and the value is transmitted to the controller 500. If the electric conductivity value transmitted to the controller is different from the previously input value, the flow rate regulating pump 600 operates to transfer the raw water in the opposite direction to the main passage P1 through the auxiliary passage P2 so that the electric conductivity value is constant. To keep it intact. At this time, the flow rate flowing through the auxiliary passage (P2) occupies 0 to 50% of the volume of the flow rate flowing through the main passage (P1).

The raw water transported through the auxiliary flow path P2 is supplied from the raw water storage tank 100 and then sent back to the raw water storage tank 100 via the stack module 200. As such, the raw water flowing along the auxiliary flow path flows back into the raw water storage tank 100, thereby greatly reducing the inorganic ion treatment load of the present invention.

Meanwhile, the paths of the main flow path P1 and the auxiliary flow path P2 may be connected in series as shown in FIG. 5, that is, the two flow paths P1 and P2 may flow individually, or may be parallel as shown in FIG. 6. In other words, the two flow paths P1 and P2 may be formed to cross each other through the spacer 215.

When two flow paths P1 and P2 are connected in series as shown in FIG. 5, the auxiliary flow path P2 flows along the other side of each stack module 200 to supplement raw water, and as shown in FIG. When P1 and P2 are connected in parallel, the auxiliary flow path P2 flows alternately along one side and the other side of the stack module 200 based on the spacer 215 of the unit cell 210 to replenish the raw water. The inorganic ion treatment process of the raw water supplied through the auxiliary channel P2 is the same as the inorganic ion treatment process of the raw water supplied through the main channel P1.

As described above, although described based on the preferred embodiment according to the present invention, the present invention is not limited to the specific embodiment, can be changed within the scope described in the claims by those of ordinary skill in the art have.

1 is a schematic view showing an electrosorption water treatment apparatus according to the prior art.

Figure 2 is a schematic diagram showing an electrosorption water treatment apparatus according to an embodiment of the present invention.

3 is a view showing a power supply connected to each stack module of FIG.

4 is a cross-sectional view of a cell constituting each stack module of FIG.

5 is a cross-sectional view illustrating an example in which a flow path is formed in the stack module of FIG. 2.

6 is a cross-sectional view showing another example in which a flow path is formed in the stack module of FIG. 2.

<Description of the symbols for the main parts of the drawings>

100: raw water storage tank 200: stack module

210: unit cell 211: anion carbon electrode

212 cation carbon electrode 213 cation exchange membrane

214 anion exchange membrane 215 spacer

216: gasket 217, 218: current collector

300: treated water storage tank 400: electrical conductivity meter

500 controller 600 flow rate control pump

700: power supply

Claims (7)

In the electrosorption water treatment apparatus comprising a stack module formed by stacking unit cells, The stack module is an electrosuction water treatment device, characterized in that the main flow path and the auxiliary flow path is formed so that the raw water flows in the opposite direction. The method of claim 1, The stack module is provided with a plurality of electro-adsorption water treatment apparatus, characterized in that connected in the up, down direction or side by side. The method according to claim 1 or 2, And an electric conductivity meter installed at the main flow path side of the stack module to measure an electric conductivity value, and a controller connected to the electric conductivity meter. The method of claim 3, wherein And a power supply device for applying a voltage to each of the stack modules, respectively. The method of claim 4, wherein And a flow rate control pump electrically connected to the controller to control the flow of raw water through the auxiliary flow path. The method according to claim 1 or 2, And the main flow passage flows along one side of the stack module, and the auxiliary flow passage flows along the other side of the main flow passage. The method according to claim 1 or 2, And the main flow passage and the auxiliary flow passage alternately along one side and the other side to cross each other in the space of the unit cell provided in each stack module.

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