KR20130131642A - Seawater desalination and salt manufacture system using waste heat of combustion gas - Google Patents

Abstract

Disclosed is a seawater desalination and salt manufacturing system using the waste heat of combustion gas. The system of the present invention is a facility using the waste heat discharged from a thermal power plant or a combined cycle power plant, and comprises: an evaporation tank generating salt by evaporating fed seawater using a heat source which is the combustion gas discharged from the thermal power plant or the combined cycle power plant; and a combustion gas pipe installed at the bottom part of the evaporation tank, and in which the combustion gas heat-exchanges with the seawater. [Reference numerals] (AA) Electric power transmission;(BB) Seawater for cooling;(CC) Seawater;(DD) Chimney;(EE) Combustion gas;(FF) Salt

Description

Seawater Desalination And Salt Manufacture System Using Waste Heat Of Combustion Gas}

The present invention relates to a seawater desalination decontamination system using combustion gas filtrate, and more particularly, the combustion gas discharged from a thermal or combined cycle power plant as a heat source, used as a condenser cooling water in a power plant and evaporated discharged seawater to fresh water and salt. The present invention relates to a seawater desalination decontamination system using combustion gas heat generation.

The power plant generates steam using the heat of combustion generated when burning fuel and generates electricity using it. The combustion gases produced by the combustion of fuel are released into the atmosphere through stacks of power plants.

1 is a view showing a conventional power generation system, the operation of the power plant is described schematically with reference to FIG.

The feed water delivered to the boiler drum 112 is fed into the boiler via a tube, converted into steam by the heat of combustion of the fuel, and again superheated to a substantial high temperature in the superheater 114 to become superheated steam of high temperature and high pressure. The superheated steam is supplied to the high pressure turbine 116 to rotate the high pressure turbine 116 and then sent to the reheater 118. The reheater 118 converts the low temperature reheat steam passed through the high pressure turbine 116 into high temperature reheat steam having a high superheat degree. The reheat steam is introduced to the medium pressure turbine 120. Rotating the medium pressure turbine 120 and the discharged steam is delivered to the condenser 102 after finally rotating the low pressure turbine 122.

The water (plural) condensed by the cooling water in the condenser 102 is delivered to the low pressure feed water heater 106 by a condensate extraction pump (CEP) 104. In the low pressure feed water heater 106, the feed water is heated by extraction steam supplied from the low pressure turbine 122.

The feed water heated in the low pressure feed water heater 106 is passed through a deaerator (not shown) to remove dissolved gases.

The deaerated water is supplied to the high pressure water heater 110 by a Boiler Feedwater Pump (BFP) 108. The feed water supplied to the high pressure feed water heater 110 by the feed pump 108 is further heated by high temperature bleeding supplied from the high pressure or medium pressure turbine 120 and then to the boiler drum 112 (corresponding to the circulating boiler). As it is supplied, a circulation cycle takes place.

In such a power plant system, the combustion gas generated by the combustion of fuel in the boiler 100 is discharged through a stack. In the case of a general thermal power plant, the temperature of the combustion gas is 1300 to 1650 ° C. in the superheater 114 and 800 in the reheater 118. ~ 1100 ℃, 500 ~ 550 ℃ in the coal mill, 350 ~ 450 ℃ preheater, the flue gas exhaust fluctuations depending on the season, but is a significant high temperature of about 85 ~ 125 ℃. The conventional power plant system has a problem that by discharging the combustion gas as it is, the residual heat contained in the high-temperature combustion gas is not utilized and becomes waste heat.

In addition, the cooling water discharged after being used in the condenser, which is heated to a considerable temperature while a plurality of hot steams are being discharged as it is, is discharged as it is, so that the heated cooling water not only has an environmental effect but also is not preferable in terms of heat utilization.

The present invention is to solve the conventional problems as described above, by using the combustion gas discharged from the thermal or combined cycle power plant as a heat source, used as a condenser cooling water of the power plant to evaporate the discharged sea water to produce fresh water and salt to burn It is to provide a system that can effectively utilize the heat of gas and condenser coolant.

According to an aspect of the present invention, in the facility using the excess heat discharged from the thermal or combined cycle power plant,

An evaporation tank in which salt is generated by evaporating the supplied seawater as a heat source using combustion gas discharged from a thermal or combined cycle power plant; And

Provided is a seawater desalination decontamination system provided with a combustion gas filter heat provided in a bottom portion of the evaporation tank and including a combustion gas pipe in which the combustion gas exchanges heat with the seawater.

The evaporation tank may be supplied with all or part of the seawater discharged after use as the condenser cooling water of the thermal or combined cycle power plant.

The seawater desalination decontamination system using the combustion gas filtrate may further include a freshwater production unit in which freshwater is generated by collecting and condensing water vapor generated from the evaporation tank.

The fresh water production unit is provided on an upper portion of the evaporation tank, a collecting roof for collecting water vapor generated in the evaporation tank, a condenser connected to the collecting roof and converting the collected water vapor into water, and the water generated in the condenser. It may include a fresh water storage tank for storing.

The collecting roof may be made of a transparent material through which sunlight can pass.

According to another aspect of the present invention, in the method using the excess heat discharged from the thermal or combined cycle power plant,

The seawater desalination and decontamination method using combustion gas filtrate to produce salt water by evaporating the supplied seawater as a heat source, the seawater received from the thermal or combined cycle power plant as a heat source, and condensing the water vapor generated by evaporation of the seawater. Is provided.

All or part of the seawater used and used as the condenser cooling water of the thermal or combined cycle power plant may be supplied to the seawater for fresh water and salt production.

The seawater desalination power generation system using the combustion gas filtrate of the present invention uses the combustion gas discharged from a thermal or combined cycle power plant as a heat source, and is used as the condenser cooling water of the power plant to evaporate the discharged seawater to produce fresh water and salt, thereby producing combustion water and salt. Effective use of the residual heat of the condenser coolant can increase the efficiency of the power plant and reduce the environmental impact of the discharge of the heated condenser coolant.

1 is a view schematically showing a conventional power generation system.
2 is a view schematically illustrating a seawater desalination decontamination system using combustion gas filtrate according to an embodiment of the present invention.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

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

2 is a view showing a seawater desalination decontamination system using combustion gas filtrate according to an embodiment of the present invention.

As shown in FIG. 2, the seawater desalination decontamination system using the combustion gas filtrate according to the present embodiment is a heat source for the combustion gas discharged from the thermal or combined cycle power plant in a facility using the residual heat discharged from a thermal or combined cycle power plant. The evaporation tank 200 includes evaporating the supplied seawater to generate salt, and a combustion gas pipe 300 provided at the bottom of the evaporation tank 200 so that the combustion gas exchanges heat with the seawater.

Thermal or combined cycle power plants can be conventional general power plants. The water supplied to the boiler 100 receives combustion heat generated by combustion of fuel in the boiler 100, is converted into steam, and supplied to a turbine to drive a generator to generate electric power. Phase changes to water by the cooling water circulated at. The combustion gas generated after the combustion of fuel in the boiler 100 and the heat supply to the feed water is induced into the stack and discharged to the outside. This embodiment utilizes the combustion gas in the stack as the heat source.

The flue gas emitted by the flue has a seasonally significant but high temperature of about 85 to 125 ° C., so that the combustion gas immediately after it is discharged from the boiler can be a sufficient heat source to evaporate seawater.

In the seawater desalination decontamination system using combustion gas heat, the evaporation tank 200 may be supplied as all or part of the discharged seawater used as the condenser cooling water of a thermal or combined cycle power plant.

Seawater, used as condenser cooling water in thermal or combined cycle power plants, absorbs about 47% of the heat contained in the steam and therefore rises to a significant extent. Therefore, when the evaporation is introduced into the evaporation tank 200, since the evaporation is performed more effectively than when the general seawater is introduced, the waste heat that has been absorbed by the cooling seawater in a plurality of processes can be used. It can also reduce the impact on marine ecosystems that can occur when the cooling water heated to temperatures above surface water is discharged to the sea.

The system of the present embodiment may further include a fresh water producing unit 400 in which fresh water is generated by collecting and condensing water vapor generated from the evaporation tank 200.

Fresh water production unit 400 is provided on the top of the evaporation tank 200, the collecting roof for collecting water vapor generated in the evaporation tank 200, and a condenser 410 connected to the collecting roof to change the collected water vapor into water, It may include a fresh water storage tank 420 for storing the water generated in the condenser 410.

In this embodiment, since the combustion gas is circulated through the combustion gas pipe 300 at the bottom of the evaporation tank, the evaporation rate of seawater is greatly improved. Accordingly, a large amount of water vapor is generated in a short time. A collection roof for collecting them on top of the evaporation tank, and condensation by collecting this steam, can produce fresh water effectively and economically. The fresh water thus produced may be supplied to a power generation facility which is disposed on the beach and is not easy to supply fresh water, or may be supplied to the outside.

The condenser 410 may be supplied with cooling water or a refrigerant for condensing water vapor.

The collecting roof (not shown) may be made of a transparent material through which sunlight can pass.

By installing a collecting roof (not shown) made of a transparent material, natural salt can be produced by the evaporation effect of natural light as in conventional salt farms, and also prevents impurities or contaminants from entering during salt production.

As a result, the salt produced by the system of the present embodiment can be referred to as sun salt because it has the characteristics of natural salt by natural light and seawater heating by high temperature combustion gas at the same time.

According to another aspect of the present invention, in the method using the excess heat discharged from the thermal or combined cycle power plant,

The seawater desalination and decontamination method using the combustion gas filtrate which produces the fresh water by condensing the water vapor produced by the evaporation of the seawater by the combustion gas discharged from the thermal or combined cycle power plant as a heat source. do.

All or part of the seawater used and used as condenser cooling water in thermal or combined cycle power plants can be supplied to seawater for fresh water and salt production.

As described above, in the seawater desalination decontamination system using the combustion gas filtrate of the present invention, by using the combustion gas of the fossil and combined cycle power generation equipment as a heat source, by utilizing the cooling seawater discharged from the condenser, to produce fresh water and salt, It is possible to reduce the environmental impact due to the discharge of warmed cooling water and to effectively utilize the heat of combustion gas and condenser coolant to increase the efficiency of the power plant. Boiler efficiency is known to be as high as 1% when the temperature of the exhaust gases emitted after fuel combustion in power plants is reduced by 20 to 25 ° C.

In addition, cooling seawater and combustion gases can be used to produce salt and fresh water economically and environmentally, without the use of additional fuel or energy.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

100: Boiler
200: evaporation tank
300: combustion gas pipe
400: freshwater production department
410: condenser
420: freshwater storage tank

Claims (7)

In a facility that uses the excess heat emitted from a thermal or combined cycle power plant,
An evaporation tank in which salt is generated by evaporating the supplied seawater as a heat source using combustion gas discharged from a thermal or combined cycle power plant; And
Seawater desalination decontamination system using a combustion gas filter heat is provided in the bottom of the evaporation tank comprising a combustion gas pipe to exchange heat with the sea water. The method of claim 1,
The seawater desalination decontamination system using combustion gas filtrate, characterized in that the evaporation tank is supplied with all or part of the seawater discharged after use as the condenser cooling water of the thermal or combined cycle power plant. The method of claim 1,
Seawater desalination decontamination system further comprises a fresh water production unit by collecting and condensing the water vapor generated from the evaporation tank to produce fresh water. According to claim 3, wherein the fresh water production unit
A collecting roof provided at an upper portion of the evaporation tank to collect water vapor generated from the evaporation tank;
A condenser connected to the collecting roof and converting the collected water vapor into water; And
Seawater desalination decontamination system using a combustion gas excess heat, characterized in that it comprises a fresh water storage tank for storing the water generated in the condenser. 5. The method of claim 4,
The collection roof is a seawater desalination decontamination system using the combustion gas filtrate, characterized in that made of a transparent material that can transmit sunlight. In the method using the heat discharged from the thermal or combined cycle power plant,
Seawater desalination and decontamination method using a combustion gas filtrate to produce salt water by evaporating the supplied seawater as a heat source, the seawater received by the combustion gas discharged from the thermal or combined cycle power plant as a heat source. The method according to claim 6,
Seawater desalination and decontamination method using the combustion gas filtrate, characterized in that all or part of the seawater used as the condenser cooling water of the thermal or combined cycle power plant is supplied to the seawater for fresh water and salt production.

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