KR20170061711A - Electrolysis system - Google Patents

Abstract

An electrolytic apparatus for electrolyzing treated sea water or salt water to produce an electrolytically treated water having hypochlorous acid; An electrolytic system having an injection line injected into the sea water line and a branch line branched from the injection line and injecting electrolytic water into the nitrogen treatment tank.

Description

Electrolysis System {ELECTROLYSIS SYSTEM}

The present invention relates to an electrolytic system having an electrolytic apparatus for electrolyzing seawater or brine to produce electrolytically treated water containing hypochlorous acid.

Priority is claimed on Japanese Patent Application No. 2014-228012, filed on November 10, 2014, the contents of which are incorporated herein by reference.

Conventionally, in a thermal power plant or a nuclear power plant that uses a large amount of seawater, the attachment of algae and shellfish to the seawater in the intake port, piping, condenser, Breeding is a challenge.

To solve this problem, sodium hypochlorite (chlorine, sodium hypochlorite) is produced by electrolyzing natural seawater and electrolytically treated water including sodium hypochlorite is injected into the intake port to inhibit attachment of marine life (For example, refer to Patent Document 1).

In order to remove oxygen which is a cause of corrosion of the feed water system in the plant, there is known a deoxidation method in which ammonia having a large pH (hydrogen ion index) (for example, pH 7 to pH 10.5) is injected . However, by using ammonia as the deoxidizing agent, it is assumed that the concentration of ammonia in the waste water from the plant will increase in the future. On the other hand, reduction of nitrogen is also required by drainage regulation, and prompt response is demanded.

Patent Document 2 discloses an ammonia nitrogen removing apparatus for decomposing ammonia by chlorination using sodium hypochlorite obtained by electrolyzing seawater.

Japanese Patent Application Laid-Open No. 10-85750 Japanese Laid-Open Patent Publication No. 2014-563

However, in a plant for collecting a large amount of seawater such as a thermal power plant and discharging ammonia-nitrogen-containing wastewater such as boiler drainage, it was necessary to install a device for preventing marine biofouling and an ammonia nitrogen removal device, respectively.

That is, in the apparatus for preventing marine organisms adherence, a method of controlling the injection flow rate and hypochlorous acid concentration of the electrolytically treated water in addition to the control of changing the concentration of hypochlorous acid contained in the electrolytically treated water by making the injection flow rate of the electrolytically treated water constant . On the other hand, in the ammonia nitrogen removal apparatus, the operation control is performed by keeping the concentration of hypochlorous acid constant and changing the injection amount of the electrolytic treatment water.

Therefore, it is difficult to perform both of the prevention of attachment of marine organisms and the removal of ammonia nitrogen by simply using one seawater electrolytic apparatus.

It is an object of the present invention to provide an electrolytic system capable of suppressing the attachment of marine organisms in a water intake port and using a single electrolytic apparatus to remove nitrogen components contained in nitrogen- .

According to a first aspect of the present invention, there is provided an electrolytic system comprising: a seawater line through which seawater flows into a plant; a nitrogen treatment tank into which nitrogen-containing waste water discharged from the plant is introduced; An electrolytic apparatus for generating electrolytic water, an injection line for injecting the electrolytic water to the seawater line, and a branch line branched from the injection line and injecting the electrolytic treatment water into the nitrogen treatment tank .

With this arrangement, it is possible to suppress the attachment of marine organisms in the sea water line by using one electrolytic apparatus, and to remove the nitrogen component contained in the nitrogen-containing drain water discharged from the plant.

The electrolytic system may have a control device for adjusting the flow rate of the electrolytically treated water introduced from the branch line based on the hypochlorous acid amount of the electrolytically treated water generated in the electrolytic apparatus.

According to this configuration, the amount of hypochlorous acid to be supplied to the nitrogen treatment tank and the amount of hypochlorous acid to be injected into the sea water line can be kept constant.

Wherein the electrolytic system is provided with a circulating flow path through which the seawater circulates, and the electrolytic apparatus is arranged to electrolyze the seawater in the middle of the circulating flow path, The nitrogen-containing wastewater may be retained in the nitrogen treatment tank until the amount of hypochlorous acid in the treated water reaches a predetermined amount.

According to such a constitution, it is possible to prevent the nitrogen-containing waste water from being exhausted to the outside of the system with insufficient nitrogen treatment.

According to the present invention, one electrolytic apparatus can be used to suppress the attachment of marine organisms in the intake port and to remove the nitrogen component contained in the nitrogen-containing wastewater discharged from the plant.

1 is a schematic configuration diagram of an electrolytic system according to a first embodiment of the present invention.
2 is a schematic configuration diagram of an electrolytic system according to a second embodiment of the present invention.
3 is a schematic configuration diagram of an electrolytic system according to a modified example of the second embodiment of the present invention.

(First Embodiment)

The electrolytic system 1 of the first embodiment of the present invention will be described in detail with reference to the drawings.

1 is a schematic configuration diagram of an electrolysis system 1 according to a first embodiment of the present invention. 1, the electrolytic system 1 includes a combine-cycle power generation plant P having an arrangement recovery boiler B, a seawater electrolytic device 2, and a control device (not shown) as main components Element.

A combined cycle power plant P (hereinafter referred to as a plant P) includes a gas turbine (not shown), an arrangement recovery boiler B (hereinafter referred to as a boiler B) to which exhaust gas from a gas turbine is sent, ), A steam turbine (not shown), and a generator (not shown) that is driven and driven by the rotational driving force of the gas turbine and the steam turbine.

Sea water M taken from the water intake port 4 of the sea water line 3 is introduced into the plant P. The seawater M is discharged after being used for, for example, cooling. For example, the boiler water in the boiler (B) contains ammonia as an oxygen scavenger for removing oxygen which is a cause of corrosion. Therefore, the boiler drainage W discharged from the boiler B is an ammonia nitrogen-containing drainage water containing ammonia nitrogen such as ammonia (NH ₃ ) and ammonium ions (NH ₄ ⁺ ). The boiler drainage W is stored in the drainage tank 6 and then introduced into the nitrogen treatment tank 7. The boiler drainage W is discharged through the waste water line 22 after the nitrogen is removed from the nitrogen treatment tank 7.

The electrolytic system 1 has a seawater supply pump 8 and a seawater electrolytic apparatus 2 for electrolyzing the seawater M introduced by the seawater supply pump 8. The seawater supply pump 8 may be configured to raise the seawater M directly from the ocean or to sweep the seawater M from the seawater line 3. [

The seawater supply pump 8 and the seawater electrolytic apparatus 2 are connected by a seawater supply line 12. A first flow rate sensor 13 for measuring the flow rate of the seawater M and a first flow rate regulating valve 14 for regulating the flow rate of the seawater M are formed in the sea water supply line 12. The seawater supply line 12 may be provided with a strainer for preventing foreign matter from interfering with electrolysis.

The seawater electrolytic apparatus 2 has an electrolytic bath 9 and a DC power supply apparatus 10. The seawater electrolytic apparatus 2 is an apparatus for producing an electrolytically treated water E containing sodium hypochlorite (chlorine, sodium hypochlorite) by electrolyzing seawater M. The electrolytic bath 9 has a plurality of electrodes (not shown).

The DC power supply apparatus 10 is an apparatus for supplying a current to be supplied for electrolysis of the seawater M, for example, a configuration including a DC power supply and a constant current control circuit can be employed. The DC power source is a power source for outputting DC power, for example, a configuration in which AC power outputted from an AC power source is rectified to DC and outputted.

The seawater electrolytic apparatus 2 of the present embodiment is a one-through system in which the seawater M is passed through the electrolytic bath 9 only once.

The electrolytic water E generated in the seawater electrolytic apparatus 2 is injected into the intake port 4 of the seawater line 3 through the injection line 15. Electrolytically treated water (E) (sodium hypochlorite) is injected into the intake port (4), so that adhesion of marine organisms to the intake port (4) can be suppressed. In other words, the seawater electrolytic apparatus 2 of the present embodiment has a function as a device for preventing marine biofouling.

The hypochlorous acid concentration sensor 19 for measuring the hypochlorous acid concentration of electrolyzed water E flowing through the injection line 15 is formed in the injection line 15.

A branch line 16 for branching the electrolytic treated water E into the nitrogen treatment tank 7 is branched from the injection line 15 connecting the seawater electrolytic apparatus 2 and the water intake port 4. [ That is, the electrolytic water E generated in the seawater electrolytic apparatus 2 is introduced into the nitrogen treatment tank 7 through the branch line 16 branching from the injection line 15, Mixed.

The branch line 16 is provided with a second flow rate sensor 17 for measuring the flow rate of the electrolytic process water E and a second flow rate control valve 18 for regulating the flow rate of the electrolytic process water E .

The nitrogen treating tank 7 is provided with a pH measuring device 20 for measuring the pH (hydrogen ion exponent) of the treated water comprising the boiler drainage W and the electrolytically treated water E in the nitrogen treating tank 7, A pH adjusting device 21 for adjusting the pH of the treated water in the treatment tank 7 is formed.

The boiler drainage W and the electrolytically treated water E are introduced into the nitrogen treatment tank 7 so that the ammonia present in the boiler drainage W and the hypochlorous acid are subjected to solution reaction to decompose to nitrogen gas N ₂ . That is, the seawater electrolytic apparatus 2 of the present embodiment has a function as an ammonia nitrogen removing device.

The control method of the electrolytic system 1 of the present embodiment will be described.

The control device controls the DC power supply 10 of the seawater electrolytic unit 2 based on the amount of hypochlorous acid required at the intake port 4 (hereinafter referred to as the first hypochlorous acid amount). The control device calculates the first hypochlorous acid amount using the flow rate of the seawater M measured by the first flow sensor 13 and the hypochlorous acid concentration measured by the hypochlorous acid concentration sensor 19. [ The control device adjusts the hypochlorous acid concentration of the generated electrolytically treated water (E) by controlling the DC power supply (10) based on the calculated first hypochlorous acid amount.

Here, the amount of hypochlorous acid required in the intake port (4) is a necessary minimum amount in which hypochlorous acid is substantially consumed in the intake port (4), and hypochlorous acid is not substantially discharged. The first hypochlorous acid amount is calculated at predetermined time intervals by a predetermined method. The amount of primary hypochlorous acid is not constant and constantly changes.

The control device adjusts the hypochlorous acid concentration of the electrolytically treated water (E) according to the first hypochlorous acid amount.

On the other hand, the control device calculates the amount of hypochlorous acid per unit time (hereinafter referred to as the second hypochlorous acid amount) required in the nitrogen treatment tank 7. The amount of the second hypochlorous acid is approximately constant.

The control device calculates the electrolytic treated water E2 (e2) introduced into the nitrogen treatment tank 7 through the branch line 16 based on the calculated second hypochlorous acid concentration and the hypochlorous acid concentration measured by the hypochlorous acid concentration sensor 19. [ (Hereinafter, referred to as a second flow rate). The second flow rate can be calculated from the second hypochlorous acid amount and the hypochlorous acid amount concentration.

Specifically, the control device controls the second flow rate adjusting valve 18 so as to measure the flow rate of the branch line 16 from the second flow rate sensor 17 and adjust the measured flow rate to the second flow rate Conduct.

The control device is introduced through the seawater supply line 12 to supplement the flow rate of the electrolytically treated water E1 flowing through the infusion line 15 decreasing by the second flow rate (hereinafter referred to as the first flow rate) The control for adjusting the flow rate of the seawater M is performed. When the flow rate of the seawater M is FM, the flow rate of the electrolytically treated water E flowing through the injection line 15 is F1 and the flow rate of electrolytically treated water E flowing through the branch line 16 is F2, = F1 + F2, the flow rate of the introduced seawater M is increased.

More specifically, the control device measures the flow rate of the seawater supply line 12 at the first flow sensor 13 and controls the flow rate of the seawater M to be measured so that the measured flow rate becomes the flow rate of the calculated sea water M ).

In the nitrogen treating tank 7, the pH of the treated water in the nitrogen treating tank 7 is adjusted to a predetermined value by using the pH adjusting device 21 based on the pH measured by the pH measuring device 20 Adjust by adding pH adjuster.

According to the above embodiment, one seawater electrolytic apparatus 2 can be used to suppress the attachment of marine organisms in the water intake port 4 and to suppress the nitrogen component contained in the nitrogen-containing wastewater discharged from the plant P Can be removed.

The amount of electrolytic water E2 introduced from the branch line 16 is adjusted based on the amount of hypochlorous acid in the electrolytically treated water E generated in the seawater electrolytic apparatus 2, And the amount of hypochlorous acid to be injected into the seawater line 3 can be kept constant.

(Second Embodiment)

An electrolytic system 1B according to a second embodiment of the present invention will be described with reference to the drawings. In the present embodiment, description will be made mainly on the differences from the above-described first embodiment, and description of the same portions will be omitted.

The seawater electrolytic apparatus 2 of the electrolytic system 1B of the present embodiment is provided with the circulating flow path 24 for circulating the electrolytically treated water E (seawater M). The seawater electrolytic apparatus 2 is disposed so as to electrolyze the seawater M in the middle of the circulating flow passage 24. That is, the seawater electrolytic apparatus 2 of the present embodiment employs a recycling method in which the concentration of hypochlorous acid in the electrolytically treated water E is gradually increased by circulating the seawater M in the circulating flow path 24.

A transfer line 27 for transferring wastewater flowing through the wastewater line 22 to the drain tank 6 is branched from the wastewater line 22 of the electrolytic system 1B of the present embodiment.

A control method of the electrolytic system 1B of the present embodiment will be described.

When the seawater M is introduced into the circulation flow passage 24, the seawater M is slowly circulated through the circulation flow passage 24 until the electrolysis treatment water E having a predetermined hypochlorous acid concentration is obtained do. That is, after starting the seawater electrolytic apparatus 2 or changing the setting of the electrolytic system 1B, a predetermined time is required until the hypochlorous acid concentration is determined based on the first hypochlorous acid amount.

The control device operates the valve 28 formed in the waste water line 22 and the return line until the amount of hypochlorous acid in the electrolytic treatment water E flowing out from the circulating flow path 24 reaches a predetermined amount The waste water discharged from the nitrogen treatment tank 7 is conveyed to the drain tank 6 through the return line 27. [ That is, control is performed so that the waste water having insufficient nitrogen treatment is retained in the nitrogen treatment tank 7.

At the stage where the amount of hypochlorous acid in the electrolytic treatment water E reaches a predetermined amount, the same control as that of the electrolytic system 1 of the first embodiment is performed.

The method of retaining the wastewater in the nitrogen treatment tank 7 is not limited to this. For example, the nitrogen treatment tank 7 may be sufficiently enlarged without forming the conveying line 27. In this configuration, the valve 29 on the wastewater line 22 is closed so that the wastewater can be held in the nitrogen treatment tank 7.

According to the above embodiment, when the seawater electrolytic apparatus 2 is started or the setting of the electrolytic system 1B is changed, the wastewater is retained in the nitrogen treatment tank 7, whereby nitrogen-containing waste water with insufficient nitrogen treatment is discharged out of the system Can be prevented.

In other words, according to the above-described embodiment, not only the one-through type seawater electrolytic apparatus 2 for passing the seawater M only once to the electrolytic bath 9 as shown in the first embodiment, It is possible to carry out both of the prevention of attachment of marine life and the removal of ammonia nitrogen even in the recycling system having a high prevention effect.

(Modification of Second Embodiment)

An electrolytic system 1C according to a modification of the second embodiment will be described.

3, the injection line 15 of the present modification includes a third flow rate sensor 25 for measuring the flow rate of the electrolytically treated water E flowing through the injection line 15, And a third flow rate regulating valve 26 for regulating the flow rate of the fluid. That is, the electrolytic system 1 of the present modification example is a system capable of adjusting the flow rate of the electrolytically treated water E1 together with the electrolytic water E1 of the electrolytically treated water E1 flowing through the injection line 15 to be.

The control apparatus of the present modification operates the valves 28 and 29 formed in the wastewater line 22 and the return line 27 in the same manner as the control apparatus of the second embodiment, Control is performed to convey the wastewater discharged from the nitrogen treatment tank 7 to the drain tank 6 through the return line 27 until the amount of hypochlorous acid in the electrolytic treatment water E reaches a predetermined amount do.

According to this modified example, even when the flow rate of the injection line 15 and the concentration of the electrolytically treated water (E) are changed, it is possible to perform both of the prevention of marine life attachment and the removal of ammonia nitrogen.

While the embodiments of the present invention have been described in detail with reference to the drawings, the respective constitutions and combinations thereof in the embodiments are merely examples, and the addition of the constituent elements, Omission, substitution, and other modifications are possible. The present invention is not limited to the embodiments, but is limited only by the scope of claims.

For example, in each of the above embodiments, the seawater electrolytic apparatus 2 is configured to introduce seawater M, but it is also possible to adopt a configuration in which salt water is introduced into seawater electrolytic apparatus 2. That is, the liquid introduced to the water electrolysis device (2), water (M) equal to the chlorine ion (Cl ^-) and it is sufficient to include.

1, 1B, 1C: electrolysis system
2: Sea water electrolytic unit (electrolytic unit)
3: Sea water line
4: Water intake
6: Drain tank
7: Nitrogen treatment tank
8: Seawater supply pump
9: electrolytic cell
10: DC power supply
12: Sea water supply line
13: first flow sensor
14: First flow regulating valve
15: Infusion line
16: Branch line
17: Second flow sensor
18: Second flow regulating valve
19: hypochlorous acid concentration sensor
20: pH measuring device
21: pH adjusting device
22: Waste water line
24:
25: Third flow sensor
26: Third flow regulating valve
27: return line
B: Boiler
E, E1, E2: electrolytic water
M: Seawater
P: Plant
W: Boiler drainage (nitrogen-containing drainage)

Claims (3)

A seawater line through which seawater flows into the plant,
A nitrogen treatment tank into which nitrogen-containing waste water discharged from the plant is introduced,
An electrolytic apparatus for electrolyzing seawater or salt water to produce electrolytically treated water having hypochlorous acid,
An injection line for injecting the electrolytic treatment water into the sea water line,
And a branch line branching from the injection line and injecting the electrolytic treatment water into the nitrogen treatment tank. The method according to claim 1,
And a control device for adjusting a flow rate of the electrolytically treated water introduced from the branch line based on an amount of hypochlorous acid in the electrolytically treated water generated in the electrolytic apparatus. 3. The method of claim 2,
And a circulation channel through which the seawater circulates,
Wherein the electrolytic apparatus is arranged to electrolyze the sea water in the middle of the circulation channel,
Wherein the control apparatus stays the nitrogen-containing wastewater in the nitrogen-treating tank until the amount of hypochlorous acid in the electrolytically treated water flowing out from the circulation channel reaches a predetermined amount.

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