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TW201339100A - Oxidation tank, seawater flue-gas desulfurization system and power generation system - Google Patents

Oxidation tank, seawater flue-gas desulfurization system and power generation system Download PDF

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Publication number
TW201339100A
TW201339100A TW102103569A TW102103569A TW201339100A TW 201339100 A TW201339100 A TW 201339100A TW 102103569 A TW102103569 A TW 102103569A TW 102103569 A TW102103569 A TW 102103569A TW 201339100 A TW201339100 A TW 201339100A
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seawater
sulfur
oxidation tank
air
gas desulfurization
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TW102103569A
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Chinese (zh)
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TWI531538B (en
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Takashi Yoshimoto
Susumu Okino
Seiji Kagawa
Hiroshi Nakashoji
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Mitsubishi Heavy Ind Ltd
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23JREMOVAL OR TREATMENT OF COMBUSTION PRODUCTS OR COMBUSTION RESIDUES; FLUES 
    • F23J15/00Arrangements of devices for treating smoke or fumes
    • F23J15/02Arrangements of devices for treating smoke or fumes of purifiers, e.g. for removing noxious material
    • F23J15/04Arrangements of devices for treating smoke or fumes of purifiers, e.g. for removing noxious material using washing fluids
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D53/00Separation of gases or vapours; Recovering vapours of volatile solvents from gases; Chemical or biological purification of waste gases, e.g. engine exhaust gases, smoke, fumes, flue gases, aerosols
    • B01D53/34Chemical or biological purification of waste gases
    • B01D53/46Removing components of defined structure
    • B01D53/48Sulfur compounds
    • B01D53/50Sulfur oxides
    • B01D53/507Sulfur oxides by treating the gases with other liquids
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D2251/00Reactants
    • B01D2251/10Oxidants
    • B01D2251/11Air
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D2252/00Absorbents, i.e. solvents and liquid materials for gas absorption
    • B01D2252/10Inorganic absorbents
    • B01D2252/103Water
    • B01D2252/1035Sea water
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D2258/00Sources of waste gases
    • B01D2258/02Other waste gases
    • B01D2258/0283Flue gases
    • CCHEMISTRY; METALLURGY
    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02F1/00Treatment of water, waste water, or sewage
    • C02F1/72Treatment of water, waste water, or sewage by oxidation
    • C02F1/74Treatment of water, waste water, or sewage by oxidation with air
    • CCHEMISTRY; METALLURGY
    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02F2103/00Nature of the water, waste water, sewage or sludge to be treated
    • C02F2103/08Seawater, e.g. for desalination
    • CCHEMISTRY; METALLURGY
    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02F2209/00Controlling or monitoring parameters in water treatment
    • C02F2209/06Controlling or monitoring parameters in water treatment pH
    • CCHEMISTRY; METALLURGY
    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02F2209/00Controlling or monitoring parameters in water treatment
    • C02F2209/08Chemical Oxygen Demand [COD]; Biological Oxygen Demand [BOD]
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23JREMOVAL OR TREATMENT OF COMBUSTION PRODUCTS OR COMBUSTION RESIDUES; FLUES 
    • F23J2215/00Preventing emissions
    • F23J2215/20Sulfur; Compounds thereof
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23JREMOVAL OR TREATMENT OF COMBUSTION PRODUCTS OR COMBUSTION RESIDUES; FLUES 
    • F23J2219/00Treatment devices
    • F23J2219/40Sorption with wet devices, e.g. scrubbers
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23JREMOVAL OR TREATMENT OF COMBUSTION PRODUCTS OR COMBUSTION RESIDUES; FLUES 
    • F23J2900/00Special arrangements for conducting or purifying combustion fumes; Treatment of fumes or ashes
    • F23J2900/15041Means for absorbing SOx using seawater

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Health & Medical Sciences (AREA)
  • General Engineering & Computer Science (AREA)
  • Biomedical Technology (AREA)
  • Environmental & Geological Engineering (AREA)
  • Mechanical Engineering (AREA)
  • Analytical Chemistry (AREA)
  • General Chemical & Material Sciences (AREA)
  • Oil, Petroleum & Natural Gas (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Treating Waste Gases (AREA)
  • Chimneys And Flues (AREA)
  • Gas Separation By Absorption (AREA)
  • Treatment Of Water By Oxidation Or Reduction (AREA)

Abstract

This oxidation tank (12) is characterized by comprising: a diluted seawater supply line (L14) which is coupled to a tank body in order to supply diluted seawater (13b) for dilution to sulfur content-absorbed seawater (14) containing sulfur content and discharged from a flue-gas desulfurization absorption tower (11); an aeration device (31) which is provided in the tank body and supplies air (33) to the sulfur content-absorbed seawater (14) discharged from the flue-gas desulfurization absorption tower (11); and a dissolved oxygen concentration measurement device (32) which is provided in the tank body and measures the dissolved oxygen concentration in the sulfur content-absorbed seawater (14), and adjusting the air quantity to be supplied from the aeration device (31) to the sulfur content-absorbed seawater (14) on the basis of the relation between the previously acquired length of the oxidation tank (12) and the dissolved oxygen concentration in the sulfur content-absorbed seawater (14).

Description

氧化槽、海水排煙脫硫系統及發電系統 Oxidation tank, seawater flue gas desulfurization system and power generation system

本發明係關於一種對使用海水進行脫硫之包含硫成分之吸收硫成分海水進行氧化處理之氧化槽、海水排煙脫硫系統及發電系統。 The present invention relates to an oxidation tank, a seawater flue gas desulfurization system and a power generation system for oxidizing seawater containing sulfur components containing sulfur components which are desulphurized using seawater.

於以煤或原油等作為燃料之發電設備中,藉由燃燒煤等石化燃料而於自鍋爐排出之燃燒廢氣(以下,稱為「廢氣」)中包含硫氧化物(SOx)等硫成分。因此,廢氣係於經脫硫處理而去除廢氣中所含之二氧化硫(SO2)等硫氧化物(SOx)之後向大氣中排出。作為此種脫硫處理方法,存在石灰石膏法、噴霧乾燥器(spray dryer)法及海水法等。 In a power generation facility that uses coal or crude oil as a fuel, a combustion component (hereinafter referred to as "exhaust gas") discharged from a boiler contains a sulfur component such as sulfur oxide (SOx) by burning a fossil fuel such as coal. Therefore, the exhaust gas is subjected to desulfurization treatment to remove sulfur oxides (SOx) such as sulfur dioxide (SO 2 ) contained in the exhaust gas, and then is discharged to the atmosphere. As such a desulfurization treatment method, there are a lime gypsum method, a spray dryer method, a seawater method, and the like.

發電廠等係由於需要大量之冷卻水故而建設於面向海之場所之情形較多。因此,就抑制脫硫處理所需之運轉成本等觀點而言,提出使用有將海水用作吸收廢氣中之硫氧化物之吸收液而進行脫硫之海水脫硫的海水排煙脫硫裝置。 Power plants and the like are often built in places facing the sea due to the large amount of cooling water required. Therefore, from the viewpoint of suppressing the operation cost required for the desulfurization treatment, it is proposed to use a seawater flue gas desulfurization apparatus which uses seawater as an absorption liquid for absorbing sulfur oxides in exhaust gas to desulfurize seawater.

海水排煙脫硫裝置係藉由對使大致圓筒之類之筒形狀或角形狀縱向放置之脫硫塔(吸收塔)之內部供給海水及鍋爐廢氣,使海水作為吸收液進行氣液接觸而去除SOx。於脫硫塔內用作吸收劑之脫硫後之海水(吸收硫成分海水)被供給至氧化槽。於氧化槽內流動之吸收硫成分海水經與未用於脫硫之海水混合而稀釋。又,吸收硫成分海水係藉由自設置於氧化槽之底面之曝氣裝置(空氣配給裝置)流出之微細氣泡而進行氧化、脫羧(曝氣)(例如,參照專利文獻1)。藉此,吸收硫成分海水經SO3之氧化與CO2之曝氣處理,於滿足地域之環境基準後放 流。 The seawater flue gas desulfurization device supplies seawater and boiler exhaust gas to the inside of a desulfurization tower (absorption tower) in which a cylindrical shape or an angular shape such as a substantially cylinder is longitudinally placed, so that seawater is subjected to gas-liquid contact as an absorption liquid. Remove SOx. The desulfurized seawater (the sulfur-absorbing component seawater) used as an absorbent in the desulfurization tower is supplied to the oxidation tank. The sulfur-absorbing component seawater flowing in the oxidation tank is diluted by mixing with seawater not used for desulfurization. In addition, the sulfur-absorbing component seawater is oxidized and decarboxylated (aerated) by fine bubbles flowing out from an aeration device (air distribution device) provided on the bottom surface of the oxidation tank (see, for example, Patent Document 1). Thereby, the sulfur-absorbing seawater is subjected to aeration treatment of SO 3 and CO 2 , and is discharged after satisfying the environmental standard.

[先前技術文獻] [Previous Technical Literature] [專利文獻] [Patent Literature]

[專利文獻1]日本專利特開2007-125474號公報 [Patent Document 1] Japanese Patent Laid-Open Publication No. 2007-125474

氧化槽通常為寬度20 m~40 m、長度100 m~200 m左右之上部經開放之較長之水槽(Seawater Oxidation Treatment System(海水氧化處理系統);SOTS),需要廣泛之設置面積。於氧化槽中,自設置於氧化槽之底部之空氣配給裝置向氧化槽之底部之大致整個表面以空氣之狀態供給氧。 The oxidation tank is usually a long water tank (Seawater Oxidation Treatment System) (SOTS) with a width of 20 m to 40 m and a length of 100 m to 200 m. It requires a wide area. In the oxidation tank, oxygen is supplied from the air distributing means provided at the bottom of the oxidation tank to the substantially entire surface of the bottom of the oxidation tank in the state of air.

先前以來所使用之氧化槽係自氧化槽之底部整個表面起對在氧化槽內流動之吸收硫成分海水以空氣之狀態供給氧,故而氧化槽之運轉所需之動力成本較高。又,亦存在供給吸收硫成分海水中之SO3之氧化與CO2之曝氣所必需之氧以上之氧之場所,且供給需要以上的氧,從而未有效率地進行吸收硫成分海水中之SO3之氧化與CO2之曝氣。 The oxidation tank used in the prior art supplies oxygen to the seawater of the sulfur-absorbing component flowing in the oxidation tank from the entire surface of the bottom of the oxidation tank, and the power cost required for the operation of the oxidation tank is high. In addition, there is a place for supplying oxygen which is more than oxygen required for the oxidation of SO 3 in the seawater of the sulfur component and the aeration of the CO 2 , and the oxygen is required to be supplied, and the sulfur component is not efficiently absorbed. Oxidation of SO 3 and aeration of CO 2 .

本發明係鑒於上述課題,其課題在於提供一種可高效地進行吸收硫成分海水之處理,且降低供給至氧化槽內之總空氣量的氧化槽、海水排煙脫硫系統及發電系統。 The present invention has been made in view of the above problems, and an object of the invention is to provide an oxidation tank, a seawater flue gas desulfurization system, and a power generation system that can efficiently treat seawater containing sulfur components and reduce the total amount of air supplied to the oxidation tank.

用以解決上述課題之本發明之第1發明係一種氧化槽,其特徵在於包括:稀釋用海水供給機構,其與槽本體連結,且對自排煙脫硫吸收塔排出之包含硫成分之吸收硫成分海水供給稀釋用之海水;複數個空氣供給機構,其等設置於上述槽本體內,且對自上述排煙脫硫吸收塔排出之上述吸收硫成分海水供給空氣;及溶氧濃度測定裝置,其設 置於上述槽本體內,且測定上述吸收硫成分海水中之溶氧濃度;且基於預先求出之氧化槽之長度與吸收硫成分海水中之溶氧濃度之關係,調整自上述空氣供給機構供給至上述吸收硫成分海水之空氣量。 A first aspect of the present invention to solve the above problems is an oxidation tank comprising: a seawater supply mechanism for dilution, which is coupled to a tank body and absorbs sulfur containing components discharged from a flue gas desulfurization absorber. Sulfur component seawater is supplied to seawater for dilution; a plurality of air supply means are provided in the tank body, and air is supplied to the sulfur-absorbing component seawater discharged from the flue gas desulfurization absorption tower; and a dissolved oxygen concentration measuring device , its design Putting in the tank body, measuring the dissolved oxygen concentration in the seawater of the sulfur-absorbing component; and adjusting the supply from the air supply mechanism based on the relationship between the length of the oxidation tank obtained in advance and the dissolved oxygen concentration in the seawater of the sulfur-absorbing component The amount of air to the above-mentioned sulfur-absorbing seawater.

第2發明係如第1發明之氧化槽,其特徵在於:預先算出上述吸收硫成分海水之pH值、亞硫酸濃度、鹼性、溫度之任一者以上與溶氧濃度之關係,且上述溶氧濃度可基於預先算出之上述吸收硫成分海水之pH值、亞硫酸濃度、鹼性、溫度之任一者以上而求出。 According to a second aspect of the invention, in the oxidation tank according to the first aspect of the invention, the relationship between the pH value of the sulfur-absorbing component seawater, the sulfuric acid concentration, the alkalinity, and the temperature, and the dissolved oxygen concentration are calculated in advance, and the dissolution is performed. The oxygen concentration can be determined based on any one of the pH value of the sulfur-absorbing component seawater, the sulfurous acid concentration, the alkalinity, and the temperature calculated in advance.

第3發明係如第1發明之氧化槽,其特徵在於:上述空氣供給機構係將上述空氣一面隔開間隔一面供給至上述吸收硫成分海水。 According to a third aspect of the invention, in the oxidizing tank according to the first aspect of the invention, the air supply means supplies the air to the sulfur-absorbing component seawater at intervals.

第4發明係如第1發明之氧化槽,其特徵在於:上述空氣供給機構係於上述吸收硫成分海水之溶氧濃度成為特定值以下時供給。 According to a fourth aspect of the invention, in the oxidizing tank according to the first aspect of the invention, the air supply means is supplied when the dissolved oxygen concentration of the sulfur-absorbing component seawater is equal to or lower than a specific value.

第5發明係一種海水排煙脫硫系統,其特徵在於包括:排煙脫硫吸收塔,其使廢氣與海水進行氣液接觸而洗淨上述廢氣;第1發明之氧化槽,其設置於上述排煙脫硫吸收塔之後流側;海水供給線,其將上述海水供給至上述排煙脫硫吸收塔;吸收硫成分海水排出線,其將自上述排煙脫硫吸收塔排出之上述吸收硫成分海水供給至上述氧化槽;及稀釋海水供給線,其將上述海水供給至上述吸收硫成分海水排出線與上述氧化槽之任一者或兩者。 According to a fifth aspect of the invention, a seawater flue gas desulfurization system includes: a flue gas desulfurization absorption tower that cleans the exhaust gas by bringing gas and liquid gas into contact with seawater; and the oxidation tank according to the first aspect of the invention is provided in the above a flow side after the flue gas desulfurization absorption tower; a seawater supply line that supplies the seawater to the flue gas desulfurization absorption tower; and a sulfur component seawater discharge line that discharges the sulfur absorbed from the flue gas desulfurization absorption tower The component seawater is supplied to the oxidation tank; and the diluted seawater supply line supplies the seawater to either or both of the sulfur-absorbing component seawater discharge line and the oxidation tank.

第6發明係一種發電系統,其特徵在於包括:鍋爐;蒸氣渦輪,其將自上述鍋爐排出之廢氣用作蒸氣產生用之熱源,並且使用所產生之蒸氣來驅動發電機;及第5發明之海水排煙脫硫系統;且包括:冷凝器,其將上述蒸氣渦輪中凝結之水回收,並使其循環;排煙脫硝裝置,其進行自上述鍋爐排出之廢氣之脫硝;及集塵裝置,其去除上述廢氣中之煤塵。 A sixth aspect of the invention is a power generation system, comprising: a boiler; a steam turbine that uses exhaust gas discharged from the boiler as a heat source for steam generation, and uses the generated steam to drive a generator; and the fifth invention a seawater flue gas desulfurization system; and comprising: a condenser that recovers and circulates the condensed water in the steam turbine; a flue gas denitration device that performs denitration of the exhaust gas discharged from the boiler; and dust collection A device that removes coal dust from the exhaust gas.

根據本發明,可高效地進行吸收硫成分海水之處理,且降低供 給至氧化槽內之總空氣量。 According to the present invention, the treatment of the sulfur-absorbing component seawater can be efficiently performed, and the supply is lowered The total amount of air supplied to the oxidation tank.

10‧‧‧海水排煙脫硫系統 10‧‧‧Seawater flue gas desulfurization system

11‧‧‧排煙脫硫吸收塔 11‧‧‧Exhaust flue gas desulfurization absorption tower

12‧‧‧氧化槽 12‧‧‧oxidation tank

13‧‧‧海水 13‧‧‧ seawater

13a‧‧‧吸收海水 13a‧‧‧absorbing seawater

13b、13c‧‧‧稀釋海水 13b, 13c‧‧‧diluted seawater

14‧‧‧吸收硫成分海水 14‧‧‧Sulphur-absorbing seawater

21‧‧‧海 21‧‧‧Sea

22、23‧‧‧泵 22, 23‧‧‧ pump

25、51‧‧‧廢氣 25, 51‧‧‧ exhaust

26‧‧‧噴霧噴嘴 26‧‧‧ spray nozzle

28‧‧‧淨化氣體 28‧‧‧ Purified gas

31‧‧‧曝氣裝置(空氣配給裝置) 31‧‧‧Aeration device (air distribution device)

32‧‧‧溶氧濃度測定裝置 32‧‧‧Dissolved oxygen concentration measuring device

33‧‧‧空氣 33‧‧‧ Air

34‧‧‧氧化用空氣鼓風機 34‧‧‧Oxidation air blower

35‧‧‧散氣管 35‧‧‧Distribution tube

36‧‧‧氧化空氣用噴嘴 36‧‧‧Oxidizing air nozzle

37‧‧‧水質恢復海水 37‧‧‧Water quality restores seawater

38‧‧‧控制裝置 38‧‧‧Control device

40‧‧‧發電系統 40‧‧‧Power Generation System

41‧‧‧鍋爐 41‧‧‧Boiler

42‧‧‧蒸氣渦輪 42‧‧‧Vapor turbine

43‧‧‧冷凝器 43‧‧‧Condenser

44‧‧‧排煙脫硝裝置 44‧‧‧Exhaust smoke denitration device

45‧‧‧集塵裝置 45‧‧‧dust collection device

46‧‧‧燃料 46‧‧‧fuel

47‧‧‧空氣預熱器(AH) 47‧‧‧Air preheater (AH)

48‧‧‧空氣 48‧‧‧ Air

49‧‧‧壓入風扇 49‧‧‧Into the fan

50‧‧‧蒸氣 50‧‧‧Vapor

52‧‧‧水 52‧‧‧ water

53‧‧‧發電機 53‧‧‧Generator

55‧‧‧抽氣風扇 55‧‧‧Exhaust fan

56‧‧‧熱交換器 56‧‧‧ heat exchanger

57‧‧‧煙囪 57‧‧‧ chimney

L11、L12‧‧‧海水供給線 L11, L12‧‧‧ seawater supply line

L13‧‧‧吸收硫成分海水排出線 L13‧‧‧Sulphide-absorbing seawater discharge line

L14、L15、L18‧‧‧稀釋海水供給線 L14, L15, L18‧‧‧ diluted seawater supply line

L16‧‧‧淨化氣體排出通路 L16‧‧‧ Purified gas exhaust passage

L17‧‧‧海水排出線 L17‧‧‧Seawater discharge line

圖1係表示應用有本發明之實施例1之氧化槽的海水排煙脫硫系統之構成之概略圖。 Fig. 1 is a schematic view showing the configuration of a seawater flue gas desulfurization system to which an oxidation tank according to a first embodiment of the present invention is applied.

圖2係表示氧化槽之長度與吸收硫成分海水中之溶氧濃度之關係的一例之圖。 Fig. 2 is a view showing an example of the relationship between the length of the oxidation tank and the dissolved oxygen concentration in the sulfur-absorbing seawater.

圖3係表示氧化槽之長度與溶解於吸收硫成分海水中之SO3 -濃度及溶氧濃度之關係的一例之說明圖。 Fig. 3 is an explanatory view showing an example of the relationship between the length of the oxidation tank and the SO 3 - concentration and the dissolved oxygen concentration dissolved in the sulfur-absorbing seawater.

圖4係表示氧化槽之長度與空氣供給量之關係之說明圖。 Fig. 4 is an explanatory view showing the relationship between the length of the oxidation tank and the amount of supplied air.

圖5係表示本發明之實施例2之發電系統的構成之概略圖。 Fig. 5 is a schematic view showing the configuration of a power generation system according to a second embodiment of the present invention.

以下,一面參照圖式一面對本發明進行詳細說明。再者,本發明並不受下述實施例所限定。又,於下述實施例中之構成要素中,包含業者可容易假定者、實質上相同者、所謂均等之範圍者。進而,下述實施例中揭示之構成要素可進行適當組合。 Hereinafter, the present invention will be described in detail with reference to the drawings. Further, the present invention is not limited by the following examples. Further, among the constituent elements in the following embodiments, those who can easily assume, substantially the same, and the so-called equal range are included. Further, the constituent elements disclosed in the following examples can be appropriately combined.

[實施例1] [Example 1]

參照圖式,對應用本發明之實施例1之氧化槽的海水排煙脫硫系統進行說明。圖1係表示應用本發明之實施例1之氧化槽的海水排煙脫硫系統構成之概略圖。如圖1所示,海水排煙脫硫系統10包括:排煙脫硫吸收塔11;本實施例之氧化槽12;海水供給線L11、L12,其等將海水13供給至排煙脫硫吸收塔11;吸收硫成分海水排出線L13,其將自排煙脫硫吸收塔11排出之包含硫成分之吸收硫成分海水14供給至氧化槽12;及稀釋海水供給線L14、L15,其等將海水13供給至吸收硫成分海水排出線L13、氧化槽12。 The seawater flue gas desulfurization system to which the oxidation tank of the first embodiment of the present invention is applied will be described with reference to the drawings. Fig. 1 is a schematic view showing the configuration of a seawater flue gas desulfurization system to which an oxidation tank according to a first embodiment of the present invention is applied. As shown in Fig. 1, the seawater flue gas desulfurization system 10 includes: a flue gas desulfurization absorption tower 11; an oxidation tank 12 of the present embodiment; seawater supply lines L11, L12, which supply the seawater 13 to the flue gas desulfurization absorption Tower 11; a sulfur-absorbing component seawater discharge line L13 for supplying the sulfur-absorbing component seawater 14 containing sulfur components discharged from the exhaust gas desulfurization absorption tower 11 to the oxidation tank 12; and the diluted seawater supply lines L14 and L15, etc. The seawater 13 is supplied to the sulfur-absorbing component seawater discharge line L13 and the oxidation tank 12.

海水13係自海21藉由泵22汲取至海水供給線L11,一部分之海水13係作為吸收海水13a藉由泵23或重力驅動經由海水供給線L12供給至 排煙脫硫吸收塔11。剩餘之海水13之一部分係作為稀釋海水13b經由稀釋海水供給線L14輸送至吸收硫成分海水排出線L13,稀釋海水13b之剩餘係作為稀釋海水13c經由稀釋海水供給線L15供給至氧化槽12。海水13係使用自海21藉由泵22直接汲取之海水,但本發明並不限定於此,亦可使用自未圖示之冷凝器排出之海水之排液等。 The seawater 13 is taken from the sea 21 by the pump 22 to the seawater supply line L11, and a part of the seawater 13 is supplied as the absorbing seawater 13a via the seawater supply line L12 by the pump 23 or gravity driving. The flue gas desulfurization absorption tower 11. One part of the remaining seawater 13 is sent to the sulfur-absorbing component seawater discharge line L13 via the diluted seawater supply line L14 as the diluted seawater 13b, and the remaining portion of the diluted seawater 13b is supplied to the oxidation tank 12 as the diluted seawater 13c via the diluted seawater supply line L15. The seawater 13 is a seawater directly taken from the sea 21 by the pump 22. However, the present invention is not limited thereto, and liquid discharging from seawater discharged from a condenser (not shown) may be used.

排煙脫硫吸收塔11係使廢氣25與吸收海水13a進行氣液接觸而淨化廢氣25之塔。於排煙脫硫吸收塔11中,吸收海水13a自噴霧噴嘴26向上方呈液柱狀地噴出,使廢氣25與經由海水供給線L12供給之吸收海水13a進行氣液接觸,進行廢氣25中之硫成分之脫硫。於本實施例中,噴霧噴嘴26係向上方呈液柱狀地噴出之噴霧噴嘴,但並不限定於此,亦可向下方呈淋浴狀地進行噴霧。 The flue gas desulfurization absorption tower 11 is a tower that purifies the exhaust gas 25 by bringing the exhaust gas 25 into gas-liquid contact with the absorbing seawater 13a. In the exhaust gas desulfurization absorption tower 11, the absorbing seawater 13a is ejected upward from the spray nozzle 26 in a liquid column shape, and the exhaust gas 25 is brought into gas-liquid contact with the absorbing seawater 13a supplied through the seawater supply line L12, and the exhaust gas 25 is discharged. Desulfurization of sulfur components. In the present embodiment, the spray nozzle 26 is a spray nozzle that is ejected in a liquid column shape upward. However, the spray nozzle 26 is not limited thereto, and may be sprayed downward in a shower shape.

即,於排煙脫硫吸收塔11中使廢氣25與吸收海水13a進行氣液接觸,產生下述式(I)所示之反應,使廢氣25中之以SO2等形態含有之SOx等硫成分經吸收海水13a吸收,使用吸收海水13a去除廢氣25中之硫成分。 In other words, in the exhaust gas desulfurization absorption tower 11, the exhaust gas 25 is brought into gas-liquid contact with the absorbing seawater 13a, and a reaction represented by the following formula (I) is generated, and sulfur such as SOx contained in the form of SO 2 or the like in the exhaust gas 25 is generated. The component is absorbed by the absorbing seawater 13a, and the sulphur component in the exhaust gas 25 is removed using the absorbing seawater 13a.

SO2(g)+H2O → H2SO3(l)→HSO3 -+H+ (I) SO 2 (g)+H 2 O → H 2 SO 3 (l)→HSO 3 - +H + (I)

藉由利用該海水脫硫而使吸收海水13a與廢氣25氣液接觸而產生之H2SO3解離,氫離子(H+)於吸收海水13a中游離,故而pH值下降,於吸收硫成分海水14中吸收大量之硫成分。因此,吸收硫成分海水14高濃度地包含硫成分。此時,作為吸收硫成分海水14之pH值,例如成為3~6左右。而且,排煙脫硫吸收塔11中吸收硫成分之吸收硫成分海水14蓄積於排煙脫硫吸收塔11之塔底部。蓄積於排煙脫硫吸收塔11之塔底部之吸收硫成分海水14經由吸收硫成分海水排出線L13輸送至氧化槽12。 By desulfurizing the seawater, the H 2 SO 3 generated by the contact of the absorbing seawater 13a with the gas and liquid of the exhaust gas 25 dissociates, and the hydrogen ions (H + ) are released in the absorbing seawater 13a, so that the pH value is lowered to absorb the sulfur component seawater. 14 absorbs a large amount of sulfur components. Therefore, the sulfur-absorbing seawater 14 contains a sulfur component at a high concentration. In this case, the pH of the sulfur-absorbing seawater 14 is, for example, about 3 to 6. Further, the sulfur-absorbing component seawater 14 which absorbs the sulfur component in the flue gas desulfurization absorption tower 11 is accumulated in the bottom of the tower of the flue gas desulfurization absorption tower 11. The sulfur-absorbing component seawater 14 accumulated in the bottom of the tower of the exhaust gas desulfurization absorption tower 11 is sent to the oxidation tank 12 via the sulfur-absorbing component seawater discharge line L13.

又,於排煙脫硫吸收塔11中脫硫之淨化氣體28係經由淨化氣體排出通路L16向大氣中排出。 Further, the purge gas 28 desulfurized in the flue gas desulfurization absorption tower 11 is discharged to the atmosphere through the purge gas discharge passage L16.

又,於吸收硫成分海水排出線L13連結有稀釋海水供給線L14,將吸收硫成分海水排出線L13內之吸收硫成分海水14與稀釋海水13b混合,進行稀釋。藉由將吸收硫成分海水14與稀釋海水13b混合並進行稀釋,可使吸收硫成分海水排出線L13內之吸收硫成分海水14之pH值上升,防止SO2氣體之再擴散。又,藉由防止於吸收硫成分海水排出線L13中SO2擴散而向外部洩漏,而可防止排放刺激氣味。 In addition, the diluted seawater supply line L14 is connected to the sulfur-absorbing seawater discharge line L13, and the sulfur-absorbing component seawater 14 in the sulfur-absorbing seawater discharge line L13 is mixed with the diluted seawater 13b and diluted. By mixing and diluting the sulfur-absorbing seawater 14 with the diluted seawater 13b, the pH of the sulfur-absorbing component seawater 14 in the sulfur-absorbing seawater discharge line L13 can be increased to prevent the SO 2 gas from being diffused again. Further, by preventing the SO 2 in the sulfur-absorbing seawater discharge line L13 from diffusing and leaking to the outside, it is possible to prevent the discharge of the irritating odor.

又,亦可於吸收硫成分海水排出線L13上設置將吸收硫成分海水14與稀釋海水13b稀釋、混合之稀釋混合槽。吸收硫成分海水14係於稀釋混合槽中與稀釋海水13b混合並進行稀釋。藉由將吸收硫成分海水14與稀釋海水13b混合並進行稀釋,可使稀釋混合槽內之吸收硫成分海水14之pH值上升,防止SO2氣體之再擴散。又,藉由防止於稀釋混合槽中SO2擴散而向外部洩漏,而可防止排放刺激氣味。 Further, a dilution mixing tank for diluting and mixing the sulfur-absorbing seawater 14 and the diluted seawater 13b may be provided on the sulfur-absorbing seawater discharge line L13. The sulfur-absorbing seawater 14 is mixed with the diluted seawater 13b in a dilution mixing tank and diluted. By mixing and diluting the sulfur-absorbing seawater 14 with the diluted seawater 13b, the pH of the sulfur-absorbing component seawater 14 in the dilution mixing tank can be increased to prevent re-diffusion of the SO 2 gas. Further, by preventing the SO 2 from diffusing in the dilution mixing tank and leaking to the outside, it is possible to prevent the discharge of the irritating odor.

氧化槽12係設置於排煙脫硫吸收塔11之後流側,且包括作為稀釋用海水供給機構之稀釋海水供給線L15、作為空氣供給機構之曝氣裝置(空氣配給裝置)31、及溶氧濃度測定裝置32之槽。再者,於本實施例中,設置稀釋海水供給線L15,對氧化槽12供給稀釋海水13c,但並不限定於此,亦可不設置稀釋海水供給線L15。 The oxidation tank 12 is disposed on the flow side after the exhaust gas desulfurization absorption tower 11, and includes a dilution seawater supply line L15 as a dilution seawater supply mechanism, an aeration device (air distribution device) 31 as an air supply mechanism, and dissolved oxygen. The tank of the concentration measuring device 32. In the present embodiment, the diluted seawater supply line L15 is provided, and the diluted seawater 13c is supplied to the oxidation tank 12. However, the present invention is not limited thereto, and the diluted seawater supply line L15 may not be provided.

稀釋海水供給線L15係將稀釋海水供給線L14與氧化槽12連結,且對氧化槽12內之吸收硫成分海水14供給稀釋海水13c者。 The diluted seawater supply line L15 connects the diluted seawater supply line L14 to the oxidation tank 12, and supplies the diluted seawater 13c to the sulfur-absorbing component seawater 14 in the oxidation tank 12.

曝氣裝置31係設置於氧化槽12內,且對吸收硫成分海水14供給空氣33者。於本實施例中,曝氣裝置31包括:氧化用空氣鼓風機34,其供給空氣33;散氣管35,其輸送空氣33;及氧化空氣用噴嘴36,其對氧化槽12內之吸收硫成分海水14供給空氣33。藉由氧化用空氣鼓風機34,而外部之空氣33經由散氣管35自氧化空氣用噴嘴36送入至氧化槽12內,產生如下述式(II)之氧之溶解。於氧化槽12內吸收硫成分海水14中之硫成分與空氣33接觸,產生如下述式(III)~(V)之亞硫酸氫 根離子(HSO3 -)之氧化反應、與重碳酸根離子(HCO3 -)之脫羧反應,吸收硫成分海水14經水質恢復而成為水質恢復海水37。再者,氧化空氣用噴嘴36之數量並無特別限定,根據氧化槽12內部之大小而適當設置。 The aeration device 31 is provided in the oxidation tank 12 and supplies air 33 to the sulfur-absorbing seawater 14 . In the present embodiment, the aeration device 31 includes an oxidizing air blower 34 that supplies air 33, a diffusing pipe 35 that transports the air 33, and an oxidizing air nozzle 36 that absorbs the sulfur-absorbing component seawater in the oxidizing tank 12. 14 supplies air 33. By the oxidizing air blower 34, the external air 33 is sent from the oxidizing air nozzle 36 to the oxidizing tank 12 via the diffusing pipe 35, and the oxygen is dissolved by the following formula (II). The sulfur component absorbed in the sulfur component seawater 14 in the oxidation tank 12 is brought into contact with the air 33 to generate an oxidation reaction of bisulfite ions (HSO 3 - ) of the following formulas (III) to (V), and a bicarbonate ion. The decarboxylation reaction of (HCO 3 - ), the sulfur-absorbing seawater 14 is recovered by water quality, and the water quality is restored to seawater 37. Further, the number of the oxidizing air nozzles 36 is not particularly limited, and is appropriately set depending on the size of the inside of the oxidation tank 12.

O2(g) → O2(l) (II) O 2 (g) → O 2 (l) (II)

HSO3 -+1/2O2 → SO4 2-+H+ (III) HSO 3 - +1/2O 2 → SO 4 2- +H + (III)

HCO3 -+H+ → CO2(g)+H2O (IV) HCO 3 - +H + → CO 2 (g) + H 2 O (IV)

CO3 2-+2H+ → CO2(g)+H2O (V) CO 3 2- +2H + → CO 2 (g) + H 2 O (V)

藉此,可使吸收硫成分海水14之pH值上升並且降低化學需氧量(COD:Chemical Oxygen Demand),且可將水質恢復海水37之pH值、溶氧濃度、COD設為可放流海水之級別而排出。又,即便於在氧化槽12中進行吸收硫成分海水14之水質恢復時產生氣體,該產生之氣體亦可以滿足SO2環境基準濃度之方式於氧化槽12中擴散。水質恢復海水37係經由海水排出線L17向海21放流。 Thereby, the pH value of the sulfur-absorbing seawater 14 can be raised and the chemical oxygen demand (COD: Chemical Oxygen Demand) can be lowered, and the water quality can be restored to the pH value of the seawater 37, the dissolved oxygen concentration, and the COD can be set as the dischargeable seawater. Discharged at the level. Further, even when the water in the sulfur-absorbing component seawater 14 is recovered in the oxidation tank 12, gas is generated, and the generated gas can be diffused into the oxidation tank 12 so as to satisfy the SO 2 environment reference concentration. The water quality recovery seawater 37 is discharged to the sea 21 via the seawater discharge line L17.

又,溶氧濃度測定裝置32係設置於氧化槽12內,測定吸收硫成分海水14中之溶氧濃度。溶氧濃度測定裝置32係於氧化槽12內之吸收硫成分海水14之流動方向上設置複數個。作為溶氧濃度測定裝置32,例如可列舉市售之攜帶型、定置型等之溶氧計。以溶氧濃度測定裝置32測定之測定結果傳遞至控制裝置38。 Further, the dissolved oxygen concentration measuring device 32 is installed in the oxidation tank 12, and measures the dissolved oxygen concentration in the sulfur-absorbing seawater 14. The dissolved oxygen concentration measuring device 32 is provided in plural in the flow direction of the sulfur-absorbing component seawater 14 in the oxidation tank 12. Examples of the dissolved oxygen concentration measuring device 32 include a commercially available dissolved oxygen meter such as a portable type or a fixed type. The measurement result measured by the dissolved oxygen concentration measuring device 32 is transmitted to the control device 38.

於本實施例中,溶氧濃度可基於吸收硫成分海水14之pH值、亞硫酸濃度、鹼性、溫度之任一者以上而求出。預先算出吸收硫成分海水14之pH值、亞硫酸濃度、鹼性、溫度之任一者以上與溶氧濃度之關係,控制裝置38係基於預先算出之吸收硫成分海水14之pH值、亞硫酸濃度、鹼性、溫度之任一者以上與溶氧濃度之關係,根據吸收硫成分海水14之pH值、亞硫酸濃度、鹼性、溫度之任一者以上之值求出溶氧濃度。 In the present embodiment, the dissolved oxygen concentration can be determined based on the pH value of the sulfur-absorbing component seawater 14, the sulfuric acid concentration, the alkalinity, and the temperature. The relationship between the pH value, the sulfuric acid concentration, the alkalinity, and the temperature of the sulfur-absorbing component seawater 14 and the dissolved oxygen concentration is calculated in advance, and the control device 38 is based on the pH value of the sulfur-absorbing component seawater 14 calculated in advance, and sulfurous acid. The relationship between the concentration, the alkalinity, and the temperature and the dissolved oxygen concentration is determined based on the value of the pH value of the sulfur-absorbing component seawater 14, the sulfuric acid concentration, the alkalinity, and the temperature.

於本實施例中,控制裝置38係基於預先求出之氧化槽12之長度與吸收硫成分海水14中之溶氧濃度之關係,調整自曝氣裝置31之各個氧化空氣用噴嘴36供給至吸收硫成分海水14之空氣33之空氣量。 In the present embodiment, the control device 38 adjusts the relationship between the length of the oxidation tank 12 obtained in advance and the dissolved oxygen concentration in the sulfur-absorbing seawater 14, and adjusts the respective oxidizing air nozzles 36 supplied from the aeration device 31 to absorb sulfur. The amount of air in the air 33 of the component seawater 14.

將氧化槽12之長度與吸收硫成分海水14中之溶氧濃度之關係之一例示於圖2。如圖2所示,可使用表示氧化槽12之長度與吸收硫成分海水14中之溶氧濃度之關係的關係圖調整自各個曝氣裝置31供給至吸收硫成分海水14之空氣33之空氣量。 An example of the relationship between the length of the oxidation tank 12 and the dissolved oxygen concentration in the sulfur-absorbing seawater 14 is shown in Fig. 2 . As shown in Fig. 2, the amount of air supplied from the respective aeration devices 31 to the air 33 absorbing the sulfur component seawater 14 can be adjusted using a relationship diagram showing the relationship between the length of the oxidation tank 12 and the dissolved oxygen concentration in the sulfur-absorbing seawater 14. .

曝氣裝置31較佳為將空氣33一面隔開間隔一面供給至吸收硫成分海水14。於本實施例中,所謂一面隔開間隔一面供給,係指自所有氧化空氣用噴嘴36對吸收硫成分海水14一直供給空氣33之情形以外之意義,且指於氧化槽12之長度方向上一面保持間隔一面自受限定之氧化空氣用噴嘴36對吸收硫成分海水14供給空氣33。 The aeration device 31 preferably supplies the air 33 to the sulfur-absorbing component seawater 14 while being spaced apart from each other. In the present embodiment, the term "supply" is used to mean that the air is supplied from all of the oxidizing air nozzles 36 to the sulphur-insoluble seawater 14 and is in the longitudinal direction of the oxidizing tank 12. The air 33 is supplied to the sulfur-absorbing component seawater 14 from the limited oxidizing air nozzle 36 while maintaining the interval.

曝氣裝置31較佳為於吸收硫成分海水14之溶氧濃度成為特定值以下時供給。所謂特定值,係指可確保充分之氧化速度之量,例如吸收硫成分海水14之溶氧濃度成為飽和濃度之1/3以下則供給。再者,該特定值並不限定於溶氧濃度為飽和濃度之1/3之情形。 The aeration device 31 is preferably supplied when the dissolved oxygen concentration of the sulfur-absorbing seawater 14 is equal to or lower than a specific value. The specific value refers to an amount that can ensure a sufficient oxidation rate, and is supplied, for example, when the dissolved oxygen concentration of the sulfur-absorbing seawater 14 is equal to or less than 1/3 of the saturated concentration. Furthermore, the specific value is not limited to the case where the dissolved oxygen concentration is 1/3 of the saturated concentration.

曝氣裝置31較佳為於對吸收硫成分海水14供給空氣33時,向氧化槽12之上游側供給較多之空氣33,越去向氧化槽12之下游側越降低空氣33之供給量。此係由於供給至氧化槽12之空氣33未立即被溶解於吸收硫成分海水14中之亞硫酸根離子(SO3 -)之氧化、或CO2曝氣所消耗,故而吸收硫成分海水14向氧化槽12之下游側流動。又,氧化槽12之上游側係由於SO3 -之濃度較高而容易進行氧化,故而存在吸收硫成分海水14中之溶氧容易變少之傾向。因此,考慮溶解於吸收硫成分海水14中之SO3 -受氧化之反應時間、CO2曝氣所需之時間,於氧化槽12之上游側供給較多之空氣33,於氧化槽12之下游側降低空氣33之供給量,藉此,可於氧化槽12內切實地降低吸收硫成分海水14之SO3 -濃 度。 In the aeration device 31, when the air 33 is supplied to the sulfur-absorbing seawater 14, the air 33 is supplied to the upstream side of the oxidation tank 12, and the amount of the air 33 is reduced toward the downstream side of the oxidation tank 12. This is because the air 33 supplied to the oxidation tank 12 is not immediately dissolved by the oxidation of the sulfite ions (SO 3 - ) in the sulfur-absorbing seawater 14 or the CO 2 aeration, so that the sulfur component seawater 14 is absorbed. The downstream side of the oxidation tank 12 flows. Further, since the upstream side of the oxidation tank 12 is easily oxidized due to the high concentration of SO 3 - , the dissolved oxygen in the sulfur-absorbing seawater 14 tends to be small. Therefore, in consideration of absorbing sulfur component is dissolved in the seawater SO 3 14 - oxidized by the reaction time, the time required for the aeration of CO 2, air 33 is supplied to the more upstream of the oxidation tank 12 side, downstream of the oxidation tank 12 The side reduces the supply amount of the air 33, whereby the SO 3 -concentration concentration of the sulfur-absorbing seawater 14 can be reliably reduced in the oxidation tank 12.

圖3係表示氧化槽12之長度與溶解於吸收硫成分海水14中之SO3 -濃度及溶氧濃度之關係的一例之說明圖。如圖3所示,即便於將空氣33隔開間隔地供給至氧化槽12內之情形時,亦可藉由在吸收硫成分海水14之溶氧濃度成為特定之設定值α時將空氣33隔開間隔地供給至氧化槽12內並且調整其供給量,而將吸收硫成分海水14中之SO3 -濃度降低至與向氧化槽12內一直供給空氣33之情形大致同等。 3 is an explanatory view showing an example of the relationship between the length of the oxidation tank 12 and the SO 3 - concentration and the dissolved oxygen concentration dissolved in the sulfur-absorbing seawater 14 . As shown in Fig. 3, even when the air 33 is supplied to the oxidation tank 12 at intervals, the air 33 can be separated by the concentration of dissolved oxygen of the sulfur-containing seawater 14 being set to a specific set value α. The supply to the oxidation tank 12 is intermittently supplied and the supply amount thereof is adjusted, and the SO 3 - concentration in the sulfur-absorbing seawater 14 is reduced to be substantially equal to the case where the air 33 is supplied all the way to the oxidation tank 12 .

又,藉由將空氣33隔開間隔地供給至氧化槽12內,即便於將溶解於吸收硫成分海水14中之SO3 -濃度設為特定值以下為止所需之氧化槽12之長度產生變化之情形時,亦可藉由調整氧化槽12之深度、流路寬度並以使吸收硫成分海水14之流速變慢之方式進行調整,而調整為使再生、排出吸收硫成分海水14所需之氧化槽12之長度成為與如先前般向氧化槽12內一直供給空氣33而再生、排出吸收硫成分海水14所需之氧化槽12之長度同等程度。 Further, by supplying the air 33 to the oxidation tank 12 at intervals, the length of the oxidation tank 12 required to be equal to or lower than the SO 3 - concentration dissolved in the sulfur-absorbing seawater 14 is a specific value or less. In the case of adjusting the depth of the oxidation tank 12 and the width of the flow path, and adjusting the flow rate of the sulfur-absorbing seawater 14 to be slow, it is adjusted to regenerate and discharge the sulfur-containing seawater 14 The length of the oxidation tank 12 is equal to the length of the oxidation tank 12 required to supply the air 33 to the oxidation tank 12 and regenerate and discharge the sulfur-containing seawater 14 as previously.

圖4係表示氧化槽12之長度與空氣供給量之關係之說明圖。如圖4所示,將氧化槽12之長度方向之長度設為1.0,對在氧化槽12之長度方向上均等地分割成5個部分之各區域均等地供給空氣33之情形時的供給至氧化槽12內之總空氣量比設為1.0(參照比較例1)。此時,如實驗例1般,變更將氧化槽12分割成5個部分時之各區域之長度,調整供給至各區域之空氣量。具體而言,使對氧化槽12供給空氣33之區域之長度稍長,未供給空氣33之區域之長度縮短,且供給至氧化槽12內之空氣量係以越於氧化槽12之上游側越多,越朝向氧化槽12之下游側越變少之方式進行調整。 Fig. 4 is an explanatory view showing the relationship between the length of the oxidation tank 12 and the amount of supplied air. As shown in FIG. 4, when the length of the oxidation tank 12 in the longitudinal direction is 1.0, and the air 33 is equally supplied to each of the five sections which are equally divided in the longitudinal direction of the oxidation tank 12, the supply is oxidized. The total air amount ratio in the tank 12 was set to 1.0 (refer to Comparative Example 1). At this time, as in Experimental Example 1, the length of each region when the oxidation tank 12 was divided into five portions was changed, and the amount of air supplied to each region was adjusted. Specifically, the length of the region where the air 33 is supplied to the oxidation tank 12 is slightly longer, the length of the region where the air 33 is not supplied is shortened, and the amount of air supplied into the oxidation tank 12 is increased toward the upstream side of the oxidation tank 12. In many cases, the adjustment is performed so as to become smaller toward the downstream side of the oxidation tank 12.

藉此,於實驗例1中,與如比較例1般於氧化槽12內對各區域均等地一直供給空氣33之情形相比,可使供給至氧化槽12之總空氣量降低例如20%左右。因此,藉由調整將氧化槽12分割成複數個區域時之 各區域之長度與供給至各區域之空氣量,可高效地進行吸收硫成分海水14之處理,故而可減少在氧化槽12內之多餘之位置上設置曝氣裝置31,並且可降低供給至氧化槽12內之總空氣量,可降低對氧化槽12內供給需要以上的氧。 As a result, in Experimental Example 1, as compared with the case where the air 33 is uniformly supplied to the respective regions in the oxidation tank 12 as in Comparative Example 1, the total amount of air supplied to the oxidation tank 12 can be reduced by, for example, about 20%. . Therefore, by adjusting the oxidation groove 12 into a plurality of regions The length of each region and the amount of air supplied to each region can efficiently perform the treatment of absorbing the sulfur component seawater 14, so that the aeration device 31 can be provided at an excessive position in the oxidation vessel 12, and the supply to the oxidation can be reduced. The total amount of air in the tank 12 reduces the amount of oxygen required for the supply to the oxidation tank 12.

因此,根據本實施例之氧化槽12,使用表示預先求出之氧化槽12之長度與吸收硫成分海水14中之溶氧濃度之關係的關係圖,調整自曝氣裝置31之各個氧化空氣用噴嘴36供給至吸收硫成分海水14之空氣33之空氣量,調整將氧化槽12分割成複數個區域時之各區域之長度與供給至各區域之空氣量。因此,本實施例之氧化槽12係藉由高效地進行吸收硫成分海水14之處理,而可不增大氧化槽12而降低設置於氧化槽12內之曝氣裝置31之數量,並且可降低自曝氣裝置31供給至氧化槽12內之空氣33之總空氣量且降低供給空氣33所需之動力。 Therefore, according to the relationship diagram showing the relationship between the length of the oxidation tank 12 obtained in advance and the dissolved oxygen concentration in the sulfur-absorbing seawater 14 according to the oxidation tank 12 of the present embodiment, the respective nozzles for oxidizing air from the aeration device 31 are adjusted. The amount of air supplied to the air 33 absorbing the sulfur component seawater 14 is adjusted to the length of each region when the oxidation tank 12 is divided into a plurality of regions and the amount of air supplied to each region. Therefore, the oxidation tank 12 of the present embodiment can reduce the amount of the aeration device 31 disposed in the oxidation tank 12 without increasing the oxidation tank 12 by efficiently performing the treatment of absorbing the sulfur component seawater 14, and can reduce the self-exposure. The gas device 31 supplies the total amount of air to the air 33 in the oxidation tank 12 and reduces the power required to supply the air 33.

如此,應用本實施例之氧化槽12之海水排煙脫硫系統10可降低設置於氧化槽12內之曝氣裝置31之氧化空氣用噴嘴36之數量,並且可降低供給至氧化槽12內之總空氣量且降低供給空氣33所需之動力,故而可對在外開放型之氧化槽12中流動之吸收硫成分海水14高效地進行氧化處理,並進行水質恢復處理。 Thus, the seawater flue gas desulfurization system 10 to which the oxidation tank 12 of the present embodiment is applied can reduce the number of the oxidizing air nozzles 36 of the aeration device 31 disposed in the oxidation tank 12, and can reduce the supply to the oxidation tank 12. Since the total amount of air is reduced and the power required to supply the air 33 is reduced, the sulfur-absorbing component seawater 14 flowing through the open-type oxidation tank 12 can be efficiently oxidized and subjected to water quality recovery treatment.

因此,根據應用本實施例之氧化槽12之海水排煙脫硫系統10,藉由一面於氧化槽12內降低曝氣裝置31之氧化空氣用噴嘴36之數量一面高效地對氧化槽12內供給空氣33,而可對自排煙脫硫吸收塔11排出之吸收硫成分海水14高效地處理吸收硫成分海水14,並進行水質恢復處理,故而可提供一種可靠性較高之海水排煙脫硫系統。 Therefore, according to the seawater flue gas desulfurization system 10 to which the oxidation tank 12 of the present embodiment is applied, the inside of the oxidation tank 12 is efficiently supplied while reducing the number of the oxidizing air nozzles 36 of the aeration device 31 in the oxidation tank 12. The air 33 can efficiently treat the sulfur-absorbing seawater 14 from the sulfur-absorbing component seawater 14 discharged from the flue gas desulfurization absorption tower 11 and perform water quality recovery treatment, thereby providing a highly reliable seawater flue gas desulfurization process. system.

又,於本實施例中,對在排煙脫硫吸收塔11中進行用於海水脫硫之吸收海水13a之處理之海水排煙脫硫系統進行了說明,但本發明並不限定於此。海水排煙脫硫系統亦可應用於對自例如各種產業中之工廠、大型、中型火力發電廠等發電廠、電力企業用大型鍋爐或一般產 業用鍋爐、煉鐵廠、精煉廠等排出之廢氣中所含之硫氧化物進行海水脫硫之海水排煙脫硫裝置。 Further, in the present embodiment, the seawater flue gas desulfurization system for treating the seawater 13a for seawater desulfurization in the flue gas desulfurization absorption tower 11 has been described, but the present invention is not limited thereto. The seawater flue gas desulfurization system can also be applied to power plants such as factories in various industries, large and medium-sized thermal power plants, large-scale boilers for electric power enterprises, or general production. A seawater flue gas desulfurization device for seawater desulfurization by using sulfur oxides contained in exhaust gas discharged from boilers, ironworks, refineries, and the like.

又,於本實施例中,排煙脫硫吸收塔11、氧化槽12係作為各自分別之槽而獨立,並以吸收硫成分海水排出線L13連結排煙脫硫吸收塔11與氧化槽12,但本實施例並不限定於此,亦可將排煙脫硫吸收塔11、氧化槽12設為一體而以一個槽構成。 Further, in the present embodiment, the flue gas desulfurization absorption tower 11 and the oxidation tank 12 are independent of the respective tanks, and the flue gas desulfurization absorption tower 11 and the oxidation tank 12 are connected by the sulfur absorption component seawater discharge line L13. However, the present embodiment is not limited thereto, and the exhaust gas desulfurization absorption tower 11 and the oxidation tank 12 may be integrally formed as one groove.

[實施例2] [Embodiment 2]

參照圖式對本發明之實施例2之發電系統進行說明。對本實施例之發電系統所應用之海水排煙脫硫系統使用有實施例1之海水排煙脫硫系統。再者,對與實施例1相同之構件標註同一符號並省略其說明。 The power generation system of the second embodiment of the present invention will be described with reference to the drawings. The seawater flue gas desulfurization system of the first embodiment is used for the seawater flue gas desulfurization system applied to the power generation system of the present embodiment. The same members as those in the first embodiment are denoted by the same reference numerals, and their description will be omitted.

圖5係表示本發明之實施例2之發電系統的構成之概略圖。如圖5所示,本實施例之發電系統40係包括鍋爐41、蒸氣渦輪42、冷凝器43、排煙脫硝裝置44、集塵裝置45、及海水排煙脫硫系統10者。再者,於本實施例中,如上所述,所謂吸收硫成分海水14,係指於海水排煙脫硫系統10中吸收有SO2等硫成分之已使用之海水。 Fig. 5 is a schematic view showing the configuration of a power generation system according to a second embodiment of the present invention. As shown in FIG. 5, the power generation system 40 of the present embodiment includes a boiler 41, a steam turbine 42, a condenser 43, a smoke exhausting and denitrating device 44, a dust collecting device 45, and a seawater flue gas desulfurization system 10. Further, in the present embodiment, as described above, the sulphur-absorbing component seawater 14 refers to seawater that has been used in the seawater flue gas desulfurization system 10 to absorb sulfur components such as SO 2 .

鍋爐41係使自油槽或煤研磨機等供給之燃料46與經空氣預熱器(AH,Air Heater)47預熱之空氣48一起自燃燒器(未圖示)噴射燃燒。自外部供給之空氣48係藉由壓入風扇49輸送至空氣預熱器47進行預熱。燃料46與經空氣預熱器47預熱之空氣48係供給至燃燒器(未圖示),燃料46於鍋爐41中燃燒。藉此,產生用以驅動蒸氣渦輪42之蒸氣50。 The boiler 41 is configured to inject and burn a fuel 46 supplied from an oil tank or a coal grinder together with air 48 preheated by an air preheater (AH, Air Heater) 47 from a burner (not shown). The air 48 supplied from the outside is preheated by the press-in fan 49 to the air preheater 47. The fuel 46 and the air 48 preheated by the air preheater 47 are supplied to a burner (not shown), and the fuel 46 is combusted in the boiler 41. Thereby, a vapor 50 for driving the steam turbine 42 is generated.

於鍋爐41內燃燒而產生之廢氣51輸送至排煙脫硝裝置44。又,廢氣51與自冷凝器43排出之水52進行熱交換,用作用以產生蒸氣50之熱源。蒸氣渦輪42係使用該產生之蒸氣50驅動發電機53。而且,冷凝器43將蒸氣渦輪42中凝結之水52回收,並再次送回至鍋爐41,使其循 環。 The exhaust gas 51 generated by combustion in the boiler 41 is sent to the exhaust gas denitration device 44. Further, the exhaust gas 51 exchanges heat with the water 52 discharged from the condenser 43 to serve as a heat source for generating the vapor 50. The steam turbine 42 drives the generator 53 using the generated steam 50. Moreover, the condenser 43 recovers the water 52 condensed in the steam turbine 42 and returns it to the boiler 41 again to follow ring.

自鍋爐41排出之廢氣51係於排煙脫硝裝置44內進行脫硝,於以空氣預熱器47與空氣48進行熱交換之後,輸送至集塵裝置45,去除廢氣51中之煤塵。然後,經集塵裝置45除塵之廢氣51藉由抽氣風扇55而供給至排煙脫硫吸收塔11內。此時,廢氣51係於熱交換器56中,於與經排煙脫硫吸收塔11脫硫排出之淨化氣體28進行熱交換之後,供給至排煙脫硫吸收塔11內。又,廢氣51亦可不於熱交換器56中與淨化氣體28進行熱交換而是直接供給至排煙脫硫吸收塔11。 The exhaust gas 51 discharged from the boiler 41 is denitrated in the exhaust gas denitration device 44, and is exchanged with the air 48 by the air preheater 47, and then sent to the dust collecting device 45 to remove the coal dust in the exhaust gas 51. Then, the exhaust gas 51 dedusted by the dust collecting device 45 is supplied to the exhaust gas desulfurization absorption tower 11 by the air suction fan 55. At this time, the exhaust gas 51 is supplied to the heat exchanger 56, and is subjected to heat exchange with the purge gas 28 that has been desulfurized and discharged through the flue gas desulfurization absorption tower 11, and then supplied to the flue gas desulfurization absorption tower 11. Further, the exhaust gas 51 may be directly supplied to the exhaust gas desulfurization absorption tower 11 without being exchanged with the purge gas 28 in the heat exchanger 56.

又,熱交換器56係包含熱回收器、與再加熱器者,且熱介質於上述熱回收器與上述再加熱器之間循環。上述熱回收器係設置於抽氣風扇55與排煙脫硫吸收塔11之間,對自鍋爐41排出之廢氣51與上述熱媒體進行熱交換。上述再加熱器係設置於排煙脫硫吸收塔11之後流側,對自排煙脫硫吸收塔11排出之淨化氣體28與上述熱媒體進行熱交換,並對淨化氣體28進行再加熱。 Further, the heat exchanger 56 includes a heat recovery unit and a reheater, and the heat medium circulates between the heat recovery unit and the reheater. The heat recovery device is disposed between the extraction fan 55 and the exhaust gas desulfurization absorption tower 11, and exchanges heat between the exhaust gas 51 discharged from the boiler 41 and the heat medium. The reheater is disposed on the flow side after the exhaust gas desulfurization absorption tower 11, and exchanges heat between the purge gas 28 discharged from the flue gas desulfurization absorption tower 11 and the heat medium, and reheats the purge gas 28.

海水排煙脫硫系統10係上述實施例1之海水排煙脫硫裝置。即,海水排煙脫硫系統10係包括排煙脫硫吸收塔11、氧化槽12、海水供給線L11、L12、吸收硫成分海水排出線L13、及稀釋海水供給線L14、L15者。 The seawater flue gas desulfurization system 10 is the seawater flue gas desulfurization device of the above first embodiment. That is, the seawater flue gas desulfurization system 10 includes the flue gas desulfurization absorption tower 11, the oxidation tank 12, the seawater supply lines L11 and L12, the sulfur-absorbing component seawater discharge line L13, and the diluted seawater supply lines L14 and L15.

於海水排煙脫硫系統10中,如上所述,使用自海21汲上之海水13對廢氣51中所含有之硫成分進行海水脫硫。又,海水13係於自海21藉由泵22汲上,並於冷凝器43中進行熱交換之後,一部分之吸收海水13a經由海水供給線L12並藉由泵23輸送至海水排煙脫硫系統10。又,剩餘之稀釋海水13b經由稀釋海水供給線L14輸送至氧化槽12之上游側。於海水排煙脫硫系統10中使廢氣51與吸收海水13a進行氣液接觸,使廢氣51中之硫成分吸收於吸收海水13a中。吸收有硫成分之吸收硫成分海水14係於自排煙脫硫吸收塔11排出之後,與稀釋海水13b 混合並進行稀釋,輸送至氧化槽12之上游側。又,經海水排煙脫硫系統10淨化之廢氣51成為淨化氣體28並經由淨化氣體排出通路L16自煙囪57向外部排出。 In the seawater flue gas desulfurization system 10, as described above, seawater desulfurization is performed on the sulfur component contained in the exhaust gas 51 using the seawater 13 from the sea. Further, after the seawater 13 is branched from the sea 21 by the pump 22 and heat-exchanged in the condenser 43, a part of the absorbed seawater 13a is sent to the seawater flue gas desulfurization system 10 via the seawater supply line L12 via the pump 23. . Further, the remaining diluted seawater 13b is sent to the upstream side of the oxidation tank 12 via the diluted seawater supply line L14. In the seawater flue gas desulfurization system 10, the exhaust gas 51 is brought into gas-liquid contact with the absorbing seawater 13a, and the sulfur component in the exhaust gas 51 is absorbed into the absorbing seawater 13a. The seawater 14 which absorbs the sulfur component and absorbs the sulfur component is discharged from the flue gas desulfurization absorption tower 11, and the diluted seawater 13b The mixture is mixed and diluted and delivered to the upstream side of the oxidation tank 12. Moreover, the exhaust gas 51 purified by the seawater flue gas desulfurization system 10 becomes the purge gas 28 and is discharged to the outside from the chimney 57 via the purge gas discharge passage L16.

又,本實施例之發電系統40將稀釋海水13b之一部分經由稀釋海水供給線L15供給至氧化槽12內之上游側,但並不限定於此,亦可不將稀釋海水13b之一部分經由稀釋海水供給線L15供給至氧化槽12內之上游側。 Further, the power generation system 40 of the present embodiment supplies a part of the diluted seawater 13b to the upstream side in the oxidation tank 12 via the diluted seawater supply line L15. However, the present invention is not limited thereto, and a part of the diluted seawater 13b may not be supplied via the diluted seawater. The line L15 is supplied to the upstream side in the oxidation tank 12.

又,自海21汲上之海水13係於在冷凝器43中進行熱交換之後,輸送至海水排煙脫硫系統10,用於海水脫硫,但亦可不使自海21汲上之海水13於冷凝器43中進行熱交換而是直接輸送至海水排煙脫硫系統10,用於海水脫硫。 Further, the seawater 13 from the sea 21 is subjected to heat exchange in the condenser 43, and then sent to the seawater flue gas desulfurization system 10 for seawater desulfurization, but it is also possible not to condense the seawater 13 from the sea 21 The heat exchange in the unit 43 is carried out directly to the seawater flue gas desulfurization system 10 for seawater desulfurization.

於在稀釋混合槽中將吸收硫成分海水14與稀釋海水13b混合之後,輸送至氧化槽12。於本實施例中,氧化槽12包括稀釋海水供給線L15、曝氣裝置31、及溶氧濃度測定裝置32。控制裝置38係根據以溶氧濃度測定裝置32測定之測定結果,基於預先求出之氧化槽12之長度與吸收硫成分海水14中之溶氧濃度之關係,調整自各個曝氣裝置31之氧化空氣用噴嘴36供給至吸收硫成分海水14之空氣33之空氣量。藉由調整將氧化槽12分割成複數個區域時之各區域之長度與供給至各區域之空氣量,可高效地進行吸收硫成分海水14之處理,不增大氧化槽12而降低設置於氧化槽12內之曝氣裝置31之數量,並且可降低自曝氣裝置31供給至氧化槽12內之空氣33之總空氣量且降低供給空氣33所需之動力。 The sulfur-absorbing seawater 14 is mixed with the diluted seawater 13b in a dilution mixing tank, and then sent to the oxidation tank 12. In the present embodiment, the oxidation tank 12 includes a diluted seawater supply line L15, an aeration device 31, and a dissolved oxygen concentration measuring device 32. The control device 38 adjusts the oxidation from each aeration device 31 based on the measurement result measured by the dissolved oxygen concentration measuring device 32 based on the relationship between the length of the oxidation tank 12 obtained in advance and the dissolved oxygen concentration in the sulfur-absorbing seawater 14. The air nozzle 36 supplies the amount of air to the air 33 that absorbs the sulfur component seawater 14. By adjusting the length of each region when the oxidation tank 12 is divided into a plurality of regions and the amount of air supplied to each region, the treatment of the sulfur-absorbing seawater 14 can be efficiently performed, and the oxidation tank 12 can be reduced without being increased in oxidation. The number of aeration devices 31 in the tank 12 can reduce the total amount of air supplied from the aeration device 31 to the air 33 in the oxidation tank 12 and reduce the power required to supply the air 33.

以上述方式於氧化槽12中對吸收硫成分海水14進行水質恢復,獲得水質恢復海水37。氧化槽12中所獲得之水質恢復海水37係將pH值、溶氧濃度、COD設為可放流海水之級別而自氧化槽12經由海水排出線L17向海21放流。 The water content of the sulfur-absorbing seawater 14 is recovered in the oxidation tank 12 in the above manner, and the water quality recovery seawater 37 is obtained. The water quality recovery seawater 37 obtained in the oxidation tank 12 discharges the pH value, the dissolved oxygen concentration, and the COD to the level of the seawater to be released from the oxidation tank 12 via the seawater discharge line L17.

又,本實施例之發電系統40包括自海水供給線L11除吸收海水13a及稀釋海水13b以外將海水13之一部分供給至氧化槽12之後流側之稀釋海水供給線L18。本實施例之發電系統40係自海水供給線L11將海水13之一部分經由稀釋海水供給線L18供給至氧化槽12內之水質恢復海水37之後流側。藉此,可進一步稀釋水質恢復海水37。其結果為,可使水質恢復海水37之pH值上升,使海水排液之pH值上升至靠近海水21之pH值為止,滿足海水排液之pH值之排水基準(pH值6.0以上),並且降低COD,且可將水質恢復海水37之pH值、COD設為可放流海水之級別而排出。再者,於本實施例中,經由稀釋海水供給線L18供給至氧化槽12內之下游側,但並不限定於此,亦可不將稀釋海水13b之一部分經由稀釋海水供給線L18供給至氧化槽12內之下游側。 Further, the power generation system 40 of the present embodiment includes the diluted seawater supply line L18 on the flow side after the seawater supply line 13 is supplied to the oxidation tank 12 from the seawater supply line L11 except for the absorption seawater 13a and the diluted seawater 13b. The power generation system 40 of the present embodiment supplies a part of the seawater 13 from the seawater supply line L11 to the flow side after the water quality recovery seawater 37 in the oxidation tank 12 via the diluted seawater supply line L18. Thereby, the water quality recovery seawater 37 can be further diluted. As a result, the pH value of the seawater recovery seawater 37 can be increased, and the pH value of the seawater discharge liquid can be raised to a pH value close to the seawater 21, and the drainage standard (pH value 6.0 or more) which satisfies the pH value of the seawater discharge liquid can be satisfied, and The COD is lowered, and the water quality is restored to the pH value of the seawater 37, and the COD is discharged to the level of the seawater that can be discharged. In the present embodiment, the diluted seawater supply line L18 is supplied to the downstream side in the oxidation tank 12, but the present invention is not limited thereto, and a part of the diluted seawater 13b may not be supplied to the oxidation tank via the diluted seawater supply line L18. The downstream side of the 12th.

如此,根據本實施例之發電系統40,藉由於氧化槽12中,一面降低設置於氧化槽12內之曝氣裝置31之數量一面高效地對氧化槽12內供給空氣33,可高效地處理吸收硫成分海水14,降低供給至氧化槽12內之總空氣量,故而可降低在氧化槽12內對吸收硫成分海水14供給空氣33之動力,實現運轉成本之抑制。因此,本實施例之發電系統40可高效地穩定處理吸收硫成分海水14並進行水質恢復處理,故而可提供一種安全性及可靠性較高之發電系統。 As described above, according to the power generation system 40 of the present embodiment, the air 33 is efficiently supplied to the oxidation tank 12 while reducing the number of the aeration devices 31 provided in the oxidation tank 12 in the oxidation tank 12, so that the absorption can be efficiently performed. Since the sulfur component seawater 14 reduces the total amount of air supplied into the oxidation tank 12, the power for supplying the air 33 to the sulfur-absorbing seawater 14 in the oxidation tank 12 can be reduced, and the operation cost can be suppressed. Therefore, the power generation system 40 of the present embodiment can efficiently and stably treat the sulfur-absorbing seawater 14 and perform the water quality recovery process, thereby providing a power generation system having high safety and reliability.

又,本實施例之海水排煙脫硫系統10係例如,可用於藉由對自各種產業中之工廠、大型、中型火力發電廠等發電廠、電力企業用大型鍋爐或一般產業用鍋爐等排出之廢氣中所含之硫氧化物進行海水脫硫而產生的吸收硫成分溶液中之硫成分之去除。 Further, the seawater flue gas desulfurization system 10 of the present embodiment can be used, for example, for discharging power plants such as factories, large and medium-sized thermal power plants, and large-scale boilers or general industrial boilers in various industries. The sulfur component contained in the exhaust gas is subjected to removal of sulfur component in the sulfur-absorbing component solution generated by seawater desulfurization.

10‧‧‧海水排煙脫硫系統 10‧‧‧Seawater flue gas desulfurization system

11‧‧‧排煙脫硫吸收塔 11‧‧‧Exhaust flue gas desulfurization absorption tower

12‧‧‧氧化槽 12‧‧‧oxidation tank

13‧‧‧海水 13‧‧‧ seawater

13a‧‧‧吸收海水 13a‧‧‧absorbing seawater

13b、13c‧‧‧稀釋海水 13b, 13c‧‧‧diluted seawater

14‧‧‧吸收硫成分海水 14‧‧‧Sulphur-absorbing seawater

21‧‧‧海 21‧‧‧Sea

22、23‧‧‧泵 22, 23‧‧‧ pump

25‧‧‧廢氣 25‧‧‧Exhaust

26‧‧‧噴霧噴嘴 26‧‧‧ spray nozzle

28‧‧‧淨化氣體 28‧‧‧ Purified gas

31‧‧‧曝氣裝置(空氣配給裝置) 31‧‧‧Aeration device (air distribution device)

32‧‧‧溶氧濃度測定裝置 32‧‧‧Dissolved oxygen concentration measuring device

33‧‧‧空氣 33‧‧‧ Air

34‧‧‧氧化用空氣鼓風機 34‧‧‧Oxidation air blower

35‧‧‧散氣管 35‧‧‧Distribution tube

36‧‧‧氧化空氣用噴嘴 36‧‧‧Oxidizing air nozzle

37‧‧‧水質恢復海水 37‧‧‧Water quality restores seawater

38‧‧‧控制裝置 38‧‧‧Control device

L11、L12‧‧‧海水供給線 L11, L12‧‧‧ seawater supply line

L13‧‧‧吸收硫成分海水排出線 L13‧‧‧Sulphide-absorbing seawater discharge line

L14、L15‧‧‧稀釋海水供給線 L14, L15‧‧‧ diluted seawater supply line

L16‧‧‧淨化氣體排出通路 L16‧‧‧ Purified gas exhaust passage

L17‧‧‧海水排出線 L17‧‧‧Seawater discharge line

Claims (6)

一種氧化槽,其特徵在於包括:稀釋用海水供給機構,其與槽本體連結,且對自排煙脫硫吸收塔排出之包含硫成分之吸收硫成分海水供給稀釋用之海水;空氣供給機構,其設置於上述槽本體內,且對自上述排煙脫硫吸收塔排出之上述吸收硫成分海水供給空氣;及溶氧濃度測定裝置,其設置於上述槽本體內,且測定上述吸收硫成分海水中之溶氧濃度;且基於預先求出之氧化槽之長度與吸收硫成分海水中之溶氧濃度之關係,調整自上述空氣供給機構供給至上述吸收硫成分海水之空氣之供給量。 An oxidizing tank, comprising: a seawater supply mechanism for dilution, which is connected to a tank body, and supplies seawater for dilution to seawater containing sulfur which is discharged from a flue gas desulfurization absorption tower and contains a sulfur component; and an air supply mechanism; Provided in the tank body, and supplying air to the sulfur-absorbing component seawater discharged from the exhaust gas desulfurization absorption tower; and a dissolved oxygen concentration measuring device installed in the tank body and measuring the sulfur-absorbing component seawater The dissolved oxygen concentration in the medium is adjusted based on the relationship between the length of the oxidation tank obtained in advance and the dissolved oxygen concentration in the seawater of the sulfur-absorbing component, and the supply amount of the air supplied from the air supply means to the sulfur-absorbing component seawater is adjusted. 如請求項1之氧化槽,其中預先算出上述吸收硫成分海水之pH值、亞硫酸濃度、鹼性、溫度之任一者以上與溶氧濃度之關係,且上述溶氧濃度可基於預先算出之上述吸收硫成分海水之pH值、亞硫酸濃度、鹼性、溫度之任一者以上而求出。 In the oxidation tank of claim 1, wherein the relationship between the pH value of the sulfur-absorbing component seawater, the sulfuric acid concentration, the alkalinity, and the temperature and the dissolved oxygen concentration is calculated in advance, and the dissolved oxygen concentration can be calculated based on the calculation. The pH value of the sulfur-absorbing component seawater, the sulfuric acid concentration, the alkalinity, and the temperature are determined. 如請求項1之氧化槽,其中上述空氣供給機構係將上述空氣一面隔開間隔一面供給至上述吸收硫成分海水。 The oxidation tank according to claim 1, wherein the air supply means supplies the air to the sulfur-absorbing component seawater while being spaced apart from each other. 如請求項1之氧化槽,其中上述空氣供給機構係於上述吸收硫成分海水之溶氧濃度成為特定值以下時供給。 The oxidation tank according to claim 1, wherein the air supply means is supplied when the dissolved oxygen concentration of the sulfur-absorbing component seawater is equal to or lower than a specific value. 一種海水排煙脫硫系統,其特徵在於包括:排煙脫硫吸收塔,其使廢氣與海水進行氣液接觸而洗淨上述廢氣; 如請求項1之氧化槽,其設置於上述排煙脫硫吸收塔之後流側;海水供給線,其將上述海水供給至上述排煙脫硫吸收塔;吸收硫成分海水排出線,其將自上述排煙脫硫吸收塔排出之上述吸收硫成分海水供給至上述氧化槽;及稀釋海水供給線,其將上述海水供給至上述吸收硫成分海水排出線與上述氧化槽之任一者或兩者。 A seawater flue gas desulfurization system, comprising: a flue gas desulfurization absorption tower, which washes the exhaust gas by gas-liquid contact with the seawater; The oxidation tank of claim 1, which is disposed on the flow side after the exhaust gas desulfurization absorption tower; the seawater supply line supplies the seawater to the exhaust gas desulfurization absorption tower; and absorbs the sulfur component seawater discharge line, which will be The sulfur-absorbing component seawater discharged from the flue gas desulfurization absorption tower is supplied to the oxidation tank; and the diluted seawater supply line supplies the seawater to either or both of the sulfur-absorbing component seawater discharge line and the oxidation tank. . 一種發電系統,其特徵在於包括:鍋爐;蒸氣渦輪,其將自上述鍋爐排出之廢氣用作蒸氣產生用之熱源,並且使用產生之蒸氣驅動發電機;及如請求項5之海水排煙脫硫系統;且包括:冷凝器,其將上述蒸氣渦輪中凝結之水回收,並使其循環;排煙脫硝裝置,其進行自上述鍋爐排出之廢氣之脫硝;及集塵裝置,其去除上述廢氣中之煤塵。 A power generation system, comprising: a boiler; a steam turbine that uses exhaust gas discharged from the boiler as a heat source for steam generation, and uses the generated steam to drive a generator; and desulfurization of seawater flue gas as claimed in claim 5 a system comprising: a condenser that recovers and circulates water condensed in the steam turbine; a flue gas denitration device that performs denitration of exhaust gas discharged from the boiler; and a dust collecting device that removes the above Coal dust in the exhaust gas.
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