KR101980474B1 - Hypochlorous acid supply device and boiler waste-water treatment method - Google Patents

Abstract

An electrolytic apparatus for electrolyzing seawater received from a storage tank to generate hypochlorous acid containing liquid and returning it to a storage tank; a supply line for introducing hypochlorous acid-containing liquid stored in the storage tank; A reaction tank for reacting the hypochlorous acid-containing liquid supplied through the reaction tank with the ammonia-containing boiler drainage, and a mixed solution obtained by mixing the treatment liquid reacted in the reaction tank and the hypochlorous acid-containing liquid stored in the storage tank into the hypochlorous acid- Line and a hypochlorous acid supply device having a line.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hypochlorous acid supply device and a boiler drainage treatment method,

The present invention relates to a hypochlorous acid supplying apparatus and a method for treating boiler drainage, which supply a solution containing hypochlorous acid produced from seawater to a facility using hypochlorous acid and a boiler drain containing ammonia.

Priority is claimed on Japanese Patent Application No. 2015-085221, filed on April 17, 2015, and Japanese Patent Application No. 2015-202052, filed on October 13, 2015, the contents of which are incorporated herein by reference .

For example, in hydropower plants, hydrazine, which is used to remove oxygen which is a cause of corrosion, is evaluated as " chemical substance whose displacement is confirmed. &Quot; Therefore, in recent years, the adoption of a more safe deoxidizer or a water treatment using no oxygen scavenger has been progressed.

As the deoxidizer which does not use hydrazine, ammonia having a high pH value (for example, pH 7 to pH 10.5) is known. However, by using ammonia as the deoxidizing agent, it is assumed that the ammonia concentration of the waste water from the plant will be increased in the future (see, for example, Non-Patent Document 1). On the other hand, reduction of nitrogen is also requested by drainage regulation, and prompt response is demanded.

Patent Document 1 discloses a system for decomposing ammonia by chlorine treatment using sodium hypochlorite (sodium hypochlorite) obtained by electrolyzing seawater. In this system, boiler drainage, which is ammonia-containing drainage water, is introduced into the reaction tank, and hypochlorous acid is added to the reaction tank, and ammonia and hypochlorous acid present in the boiler drainage react with each other to decompose to nitrogen gas.

Japanese Laid-Open Patent Publication No. 2014-563

 (2009), [Search on March 30, 2012], Internet <URL: http: /www.mhi.co.jp/technology/review/pdf/462/462055.pdf>

However, in the system described in Patent Document 1, the treatment liquid treated in the reaction tank is discharged after reducing the hypochlorous acid concentration and pH in the treatment liquid to the drainage standard. The system neutralizes sodium hypochlorite using, for example, sodium thiosulfate and adjusts the pH using caustic soda (sodium hydroxide).

However, in order to treat the treatment liquid with chemicals, a cost of a multitude of chemicals is required, and therefore, there is a demand for a hypochlorous acid supply device capable of treating ammonia contained in boiler drainage at a lower cost.

It is an object of the present invention to provide a hypochlorous acid supplying device and a method of treating boiler drainage which can treat ammonia contained in boiler drainage at a lower cost.

According to the first aspect of the present invention, there is provided an apparatus for supplying hypochlorous acid, comprising: a storage tank for storing seawater; an electrolytic device for electrolyzing the seawater received from the storage tank to generate hypochlorous acid- A supply line through which the hypochlorous acid-containing liquid stored in the storage tank is introduced; a reaction tank which reacts the hypochlorous acid-containing liquid supplied through the supply line with the ammonia-containing boiler drainage; And a hypochlorous acid-containing liquid stored in the storage tank is injected into a hypochlorous acid utilization facility.

According to such a configuration, since the treatment liquid stored in the reaction tank is injected into the hypochlorous acid utilization facility without discharging, there is no need to perform the chemical treatment to satisfy the drainage standard of the treatment liquid, and the treatment cost of ammonia can be reduced have.

Wherein the hypochlorous acid supply device has a first injection line for discharging the hypochlorous acid containing liquid stored in the storage tank and a second injection line for discharging the processing liquid stored in the reaction tank, The first injection line and the second injection line may be connected.

Wherein the hypochlorous acid supply device has a first injection line for discharging the hypochlorous acid acid-containing liquid stored in the storage tank and a second injection line for discharging the treatment liquid stored in the reaction tank, The injection line may be connected to the storage tank.

The hypochlorous acid supplying apparatus may further include a control device that controls the flow rate of the hypochlorous acid-containing liquid supplied to the reaction tank and the flow rate of the ammonia-containing boiler drain supplied to the reaction tank to the treatment liquid Adjust it to the extent that ammonia remains.

According to such a constitution, the generation of trihalomethane due to the reaction of hypochlorous acid and organic matter derived from seawater in the storage tank can be suppressed. In other words, since ammonia is preferentially oxidized by hypochlorous acid, organic matter is less likely to be oxidized, and the production of trihalomethane can be suppressed.

The hypochlorous acid supply device may have a discharge line for discharging a part of the treatment liquid flowing through the second injection line and an activated carbon treatment device formed on the discharge line.

According to such a constitution, unreacted or surplus hypochlorous acid (residual chlorine) can be subjected to reduction treatment to adsorb and remove nitrate ions and trihalomethane (generated by reaction of organic matter and hypochlorous acid in seawater).

According to a second aspect of the present invention, there is provided a method of treating boiler wastewater comprising an electrolysis step of electrolyzing seawater to generate a hypochlorous acid-containing liquid, and a step of reacting the hypochlorous acid-containing liquid with ammonia- And an injection step of injecting a mixed solution obtained by mixing the treatment liquid and the hypochlorous acid-containing liquid into a hypochlorous acid application facility.

According to the present invention, since the treatment liquid stored in the reaction tank is injected into the hypochlorous acid utilization facility without discharging, there is no need to perform the chemical treatment in order to satisfy the drainage standard of the treatment liquid, and the treatment cost of ammonia can be reduced .

1 is a schematic configuration diagram of a combined cycle power generation plant having a hypochlorous acid supply device according to a first embodiment of the present invention.
2 is a schematic configuration diagram of a combined cycle power generation plant having a hypochlorous acid supply device according to a second embodiment of the present invention.
3 is a schematic configuration diagram of a combined cycle power generation plant having a hypochlorous acid supply device according to a third embodiment of the present invention.

(First Embodiment)

Hereinafter, the hypochlorous acid supply device (1) and the method of treating boiler water according to the first embodiment of the present invention will be described in detail with reference to the drawings.

1 is a schematic configuration diagram of a combined cycle power generation plant P having a hypochlorous acid supply device 1 according to a first embodiment of the present invention. The hypochlorous acid supplying device 1 of the present embodiment is a device for supplying a liquid containing sodium hypochlorite (sodium hypochlorite) produced by the seawater electrolytic apparatus 2 to the water intake 3 of sea water, for example, (Boiler drain containing ammonia, hereinafter referred to as boiler drainage) containing ammonia discharged from an arrangement heat recovery boiler (B) of a combined cycle power generation plant (P). Quot;).

1, the hypochlorous acid supplying device 1 comprises a storage tank 5 for storing seawater M, a liquid E containing sodium hypochlorite (hereinafter referred to as a hypochlorous acid containing liquid E), and an arrangement recovery boiler B (hereinafter, referred to as a boiler B) of a combined-cycle power generation plant P (hereinafter referred to as a plant P) A drain tank 6 for storing the boiler drainage W discharged from the drain tank 6 and a reaction tank 7 formed on the downstream side of the drain tank 6 and a hypochlorous acid containing liquid E supplied to the reaction tank 7 And a supply line 17 for supplying the liquid.

The plant P includes a gas turbine (not shown), a boiler through which exhaust gas from the gas turbine is sent, a steam turbine (not shown), a generator (not shown) driven by the rotational driving force of the gas turbine and the steam turbine (Not shown).

The plant P is supplied with seawater M from the seawater inlet 3 through the first seawater supply line 4 and is used for applications such as cooling. A seawater supply pump (not shown) for sending and receiving the seawater M and a seawater flow rate adjusting valve (not shown) for adjusting the flow rate of the seawater M are formed in the first seawater supply line 4.

In the boiler drainage (W) of the boiler, ammonia is used as an oxygen scavenger for removing oxygen which is a cause of corrosion. Therefore, the boiler drainage W discharged from the boiler is ammonia nitrogen-containing drainage water (ammonia-containing boiler drainage) containing ammonia nitrogen such as ammonia (NH ₃ ) and ammonium ion (NH ₄ ⁺ ).

The boiler drainage (W) discharged from the boiler (B) is stored in the drainage tank (6). On the downstream side of the drain tank 6, a reaction tank 7 is formed. The drain tank (6) and the reaction tank (7) are connected to each other through a drain line (8). The boiler drainage W stored in the drainage tank 6 is introduced into the reaction tank 7 through the drainage line 8. The drainage line 8 is formed with a drainage pump 9 for sending the boiler drainage W stored in the drainage tank 6 to the reaction tank 7.

The storage tank 5 is a tank for storing the seawater M and the hypochlorous acid-containing liquid E generated in the seawater electrolytic apparatus 2. In the storage tank 5, seawater M is introduced from the intake port 3 through the second seawater supply line 11. A seawater supply pump 12 for sending and receiving the seawater M and a seawater flow rate adjusting valve (not shown) for adjusting the flow rate of the seawater M are formed in the second seawater supply line 11.

The seawater electrolytic apparatus 2 is a device for producing a hypochlorous acid-containing liquid E containing sodium hypochlorite by electrolyzing seawater M taken from the storage tank 5 and returning it to the storage tank 5 to be. The seawater electrolytic apparatus 2 has an electrolytic bath 14, a DC power supply device 15 and a circulation line 16 for circulating the hypochlorous acid-containing liquid E therein. The electrolytic bath 14 has a plurality of electrodes (not shown).

The direct-current power supply 15 is a device for supplying a current to be supplied for electrolysis of the seawater M, for example, a configuration including a direct-current power supply and a constant current control circuit. 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 according to the present embodiment is configured to connect the downstream side of the electrolytic bath 14 (the outlet port of the electrolytic bath 14) and the upstream side of the electrolytic bath 14 (the inlet port of the electrolytic bath 14) To circulate the seawater M in the recycling system. As the seawater electrolytic apparatus 2, in addition to the recycling method, a one-through system in which sea water is passed through the electrolytic cell only once may be adopted. That is, the seawater electrolytic apparatus 2 may be of any type as long as it can generate hypochlorous acid using seawater.

The supply line 17 for supplying the hypochlorous acid-containing liquid (E) stored in the storage tank 5 to the drain line 8 is connected to the storage tank 5. A first injection line 21 is connected to the storage tank 5 for injecting the hypochlorous acid-containing liquid (E) stored in the storage tank 5 into the intake port 3 which is a hypochlorous acid utilization facility. By injecting the hypochlorous acid-containing liquid (E) into the intake port (3), the attachment of marine organisms to the intake port (3) can be suppressed.

The mixture of the boiler waste water W and the hypochlorous acid-containing liquid E is promoted on the downstream side (the side of the reaction tank 7) on the drainage line 8 and on the downstream side of the merging portion 18 with the supply line 17 A line mixer 19 is formed.

A second injection line 22 for introducing the treatment liquid T reacted in the reaction tank 7 to the first injection line 21 is connected to the reaction tank 7 of this embodiment. The treatment liquid T in the reaction tank 7 is injected into the intake port 3 through the second injection line 22 and the first injection line 21. The first injection line 21 and the second injection line 22 are formed by mixing a mixed solution obtained by mixing the treatment liquid T reacted in the reaction tank 7 and the hypochlorous acid containing liquid E stored in the storage tank 5 And serves as an injection line for injecting the water into the water intake port 3. [

Next, the operation of the hypochlorous acid supply device 1 of the present embodiment will be described.

First, as a plant cooling process, sea water (M) is supplied to the plant (P) through the first seawater supply line (4). The boiler drainage W discharged from the boiler B of the plant P is stored in the drainage tank 6. The boiler drainage W stored in the drainage tank 6 is introduced into the reaction tank 7 through the drainage line 8.

On the other hand, as the electrolysis step, the seawater M is introduced into the storage tank 5 through the second seawater supply line 11, and the hypochlorous acid-containing liquid E is generated by the seawater electrolytic apparatus 2. [ The hypochlorous acid-containing liquid (E) is introduced into the reaction tank (7) through the supply line (17). The hypochlorous acid-containing liquid (E) is injected into the intake port (3) through the first injection line (21).

The flow rate of the hypochlorous acid-containing liquid E to be injected is adjusted by controlling a flow rate control valve (not shown) formed in the first injection line 21 by a control device (not shown). The control device adjusts the flow rate of the hypochlorous acid-containing liquid (E) so that hypochlorous acid is almost consumed in the water intake port (3) to return to the original seawater (M).

Next, in the reaction step, in the reaction tank 7, ammonia present in the boiler waste water W is subjected to solution reaction with hypochlorous acid contained in the hypochlorous acid-containing liquid E to decompose to nitrogen gas (N ₂ ) . In the reaction tank 7, the ammonia is treated and the treatment liquid T is stored in the reaction tank 7.

Here, hypochlorous acid used for the decomposition of ammonia may remain in the treatment liquid (T). The pH (hydrogen ion index) of the treatment liquid T may deviate from the drainage standard. Thus, the treatment liquid T can not be discharged to the ocean, for example, unless the treatment liquid T is subjected to a chemical treatment.

Next, as the injection step, the treatment liquid T stored in the reaction tank 7 is introduced into the first injection line 21 and mixed with the hypochlorous acid-containing liquid E. The treatment liquid T in the reaction tank 7 is introduced into the first injection line 21 through the second injection line 22.

The mixed solution of the process liquid T in the reaction tank 7 and the hypochlorous acid-containing liquid E in the storage tank 5 is injected into the intake port 3. In the reaction tank 7, the ammonia-treated boiler drainage W is injected into the intake port 3 without being discharged.

According to the above embodiment, the hypochlorous acid-containing liquid (E) containing hypochlorous acid is added to the boiler waste water (W) that is the waste water containing ammonia nitrogen, whereby the ammonia contained in the boiler waste water (W) can do.

In addition, since the treatment liquid T stored in the reaction tank 7 is injected into the intake port 3 serving as a hypochlorous acid utilization facility without discharging it, it is necessary to perform the chemical treatment in order to satisfy the drainage standard of the treatment liquid T And the treatment cost of ammonia can be reduced.

The hypochlorous acid-containing liquid E generated in the seawater electrolytic apparatus 2 is injected into the intake port 3 of the seawater M through the first injection line 21. The hypochlorous acid-containing liquid (E) is injected into the intake port (3), so that the attachment of marine organisms to the intake port (3) can be suppressed.

(Second Embodiment)

Hereinafter, the hypochlorous acid supplying device 1B according to the second embodiment of the present invention will be described with reference to the drawings. In the present embodiment, differences from the above-described first embodiment will be mainly described, and description of the same portions will be omitted.

2, the second infusion line 22 of the hypochlorous acid supplying device 1B of the present embodiment is connected to the storage tank 5. As shown in Fig. The treatment liquid T in the reaction tank 7 is introduced into the storage tank 5.

A first flow rate regulating valve 23 for regulating the flow rate of the boiler water W flowing through the drain line 8 is formed in the drain line 8 of the present embodiment. The supply line 17 of the present embodiment is provided with a second flow rate adjusting valve 24 for adjusting the flow rate of the hypochlorous acid-containing liquid E flowing through the supply line 17.

The ammonia concentration measuring device 25 for measuring the ammonia concentration of the treatment liquid T stored in the reaction tank 7 is formed in the reaction tank 7 of the hypochlorous acid supply device 1 of the present embodiment.

Next, the operation of the hypochlorous acid supplying device 1B of the present embodiment will be described.

The controller 26 controls the first flow rate adjusting valve 23 and the second flow rate adjusting valve 24 so that the flow rate of the boiler water W introduced into the reaction tank 7 and the flow rate of the hypochlorous acid- ) Is adjusted. The control device 26 adjusts the flow rate of the boiler drainage and the flow rate of the hypochlorous acid-containing liquid E to such an extent that ammonia remains in the process liquid T stored in the reaction tank 7. The hypochlorous acid supplying device 1 of the present embodiment does not completely decompose the ammonia present in the boiler drainage W in the reaction tank 7 but remains in the treatment liquid T.

It is not necessary to adjust both of the hypochlorous acid-containing liquid E and the boiler drainage W if the ammonia can be left in the treatment liquid T, Ammonia may be left.

Specifically, the control device 26 adjusts at least one of the hypochlorous acid-containing liquid (E) and the boiler drainage (W) so that ammonia remains in the treatment liquid (T).

As the injection process, the treatment liquid T containing ammonia is introduced into the storage tank 5 through the second injection line 22. That is, the treatment liquid T is returned to the storage tank 5 without being discharged. Thereby, ammonia is added to seawater (M) and hypochlorous acid-containing liquid (E) stored in the storage tank (5).

According to the above embodiment, the generation of trihalomethane due to the reaction of hypochlorous acid with an organic matter derived from seawater (M) can be suppressed in the storage tank (5). That is, the ammonia introduced into the storage tank 5 together with the treatment liquid T is preferentially oxidized by hypochlorous acid, so that the organic matter is hardly oxidized. Thus, generation of trihalomethane can be suppressed.

(Third Embodiment)

Hereinafter, a hypochlorous acid supply device 1C according to a third embodiment of the present invention will be described with reference to the drawings. In the present embodiment, differences from the above-described first embodiment will be mainly described, and description of the same portions will be omitted.

3, from the second injection line 22 of the hypochlorous acid supply device 1C of the present embodiment, a part of the treatment liquid T flowing through the second injection line 22 is discharged Line 27 is connected. A part of the treatment liquid T flowing through the second injection line 22 is discharged through the discharge line 27.

An activated carbon treatment device 28 is formed in the discharge line 27. The activated carbon treatment device 28 is a device for treating activated carbon by passing the treatment liquid T through activated carbon.

A flow rate regulating valve 29 for regulating the flow rate of the process liquid T flowing through the discharge line 27 is formed in the discharge line 27.

In the activated carbon treatment device 28, the residual residual chlorine is decomposed by the decomposition reaction shown in the formula (1). Here, the amount of activated carbon used per kg of NaClO is about 0.08 kg.

2NaClO + C? CO ₂ + 2NaCl (1)

On the other hand, when the excess residual chlorine is decomposed by a reaction using a chemical such as sodium thiosulfate (Na ₂ SO ₃ ) shown in the formula (2), the amount of sodium thiosulfate per kg of NaClO is about 1.7 kg.

_{NaClO + Na 2 SO 3 → NaCl} + Na 2 SO 4 ··· (2)

According to the above embodiment, by forming the activated carbon treatment device 28 on the discharge line 27, unreacted or surplus hypochlorous acid (residual chlorine) is reduced and nitrate ions and trihalomethane Which is formed by reaction of an organic substance and hypochlorous acid) can be adsorbed and removed.

In addition, the treatment liquid T discharged from the reaction tank 7 is treated up to a dischargeable property. Therefore, when the treated water T diluted by mixing with the boiler drainage flows into the water intake port 3 and the chloride ion concentration is further lowered, for example, when the chloride ion concentration of seawater is low , And the treatment water (T) treated by the activated carbon treatment facility is discharged to the outside, whereby the decrease of the chloride ion concentration can be suppressed.

The flow rate of the process liquid T discharged from the discharge line 27 can be adjusted using the flow rate control valve 29. [

Further, when a part of the treatment liquid T is discharged, the amount of drug used can be reduced as compared with the case of decomposing with the use of sodium thiosulfate. In addition, it becomes unnecessary to control the amount of drug to be injected necessary for decomposition using sodium thiosulfate.

The technical scope of the present invention is not limited to the above-described embodiments, and various modifications can be added within the scope of the present invention.

For example, the supply line 17 for the hypochlorous acid-containing liquid (E) in each of the above-described embodiments is connected to the drainage line 8 through which the boiler drainage W flows, (7).

Although the supply line 17 and the first injection line 21 of each of the above embodiments are connected to the storage tank 5 respectively, the first injection line 21 may be branched from the supply line 17.

The discharge line 27 of the third embodiment may be provided in the hypochlorous acid supply device 1B of the second embodiment.

1, 1B: Hypochlorous acid supply device
2: Sea water electrolyzer
3: Water intake (hypochlorous acid use facility)
4: First sea water supply line
5: Storage tank
6: drainage tank
7: Reactor
8: Drain line
9: Drain pump
10: pH measuring device
11: Second seawater supply line
12: Seawater supply pump
14: electrolytic bath
15: DC power supply
16: circulation line
17: Supply line
18:
19: line mixer
21: first injection line
22: second injection line
23: First flow regulating valve
24: second flow regulating valve
25: Ammonia concentration measuring device
26: Control device
27: Outflow line
28: Activated carbon equipment
29: Flow regulating valve
B: Array recovery boiler
E: hypochlorous acid-containing liquid
M: Seawater
P: Plant
T: treatment liquid
W: Boiler drainage

Claims (6)

A reservoir for storing seawater,
An electrolytic apparatus for electrolyzing the seawater taken in from the storage tank to generate hypochlorous acid-containing liquid and return it to the storage tank;
A supply line through which the hypochlorous acid-containing liquid stored in the storage tank is introduced,
A reaction tank for reacting the hypochlorous acid-containing liquid supplied through the supply line with ammonia-containing boiler wastewater,
An injection line for injecting a mixed solution obtained by mixing the treatment liquid reacted in the reaction tank and the hypochlorous acid-containing liquid stored in the storage tank into a water intake port of the plant,
A first injection line for discharging the hypochlorous acid-containing liquid stored in the storage tank;
And a second injection line for discharging the treatment liquid stored in the reaction tank,
Wherein the injection line is connected to the first injection line and the second injection line. delete A reservoir for storing seawater,
An electrolytic apparatus for electrolyzing the seawater taken in from the storage tank to generate hypochlorous acid-containing liquid and return it to the storage tank;
A supply line through which the hypochlorous acid-containing liquid stored in the storage tank is introduced,
A reaction tank for reacting the hypochlorous acid-containing liquid supplied through the supply line with ammonia-containing boiler wastewater,
An injection line for injecting a mixed solution obtained by mixing the treatment liquid reacted in the reaction tank and the hypochlorous acid-containing liquid stored in the storage tank into a water intake port of the plant,
A first injection line for discharging the hypochlorous acid-containing liquid stored in the storage tank;
And a second injection line for discharging the treatment liquid stored in the reaction tank,
And the second injection line is connected to the storage tank. The method of claim 3,
A control device,
Wherein the control device adjusts the flow rate of the hypochlorous acid-containing liquid supplied to the reaction tank and the flow rate of the ammonia-containing boiler drain water supplied to the reaction tank to an extent that ammonia remains in the treatment liquid. The method according to any one of claims 1, 3, and 4,
A discharge line for discharging a part of the treatment liquid flowing through the second injection line,
And an activated carbon treatment device formed on the discharge line. delete

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