Overview
ABSTRACT
Cooling towers are currently the most widely used for cooling large power supplies. In the case of nuclear electric plants, they are indirect cooling towers. The building and design of a cooling tower require specific competences and qualifications in order to encompass every aspect concerned i.e. mechanical and technical aspects, civil engineering, dimensioning and building techniques. Prior to its operation, it is obligatory to carry out tests in order to validate the characteristics as well as implement safety, maintenance and surveillance instructions. Furthermore, high power cooling systems are currently being subjected to further developments in order to limit their impact on the environment.
Read this article from a comprehensive knowledge base, updated and supplemented with articles reviewed by scientific committees.
Read the articleAUTHOR
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Renaud FEIDT: Thermal energy engineer, Polytech Nantes - Installation Manager – Western Region – Johnson Controls Services and Solutions
INTRODUCTION
From the 1970s onwards, the construction of several high-powered power plants in France represented a major technological advance that is still recognized today.
Nuclear power plants, as well as conventional thermal power plants, involve considerable heat exchange in relation to their power output - up to 1,300 MW for a nuclear reactor. Assuming an average efficiency of 33%, the heat rejected by a reactor is therefore a maximum of 2,600 MW.
To remove this amount of heat, a first solution was to use river water cooling. For a nuclear power plant with 4 900 MW reactors, the total water flow required for cooling to 6 K (ΔT permissible for this type of application) is around 35 m 3 /s per reactor, i.e. 140 m 3 /s in total.
Unfortunately, it is almost always impossible to envisage this type of cooling without the risk of overheating river water. For example, with a total installed electrical capacity of 11,600 MW along the Loire, the total flow of cooling water to be drawn from the river would be 450 m 3 /s, which is higher than its normal average flow.
Other cooling solutions were therefore considered, such as the use of seawater or air, the two most important cold sinks in the surrounding environment. Because of the constraints involved in locating and using seawater, atmospheric coolants are currently the most widely used for high-power cooling. To ensure safe operation, those used to cool nuclear power plants are of the indirect type, with confinement to the secondary cooling circuit. Between lost-water cooling and wet atmospheric coolant, the most widespread system, water savings are estimated at 90% of total circulating water. In fact, the additional river water required to compensate for the quantity of water evaporated is of the order of 2 to 4 m 3 /s for a 900 MW reactor.
In this dossier, we will describe high-power indirect atmospheric coolers, also commonly referred to as indirect cooling towers:
operating principle ;
the state of the art ;
design and construction principles ;
advice on commissioning and operation.
For other types of atmospheric refrigerants, please refer to
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Atmospheric refrigerants. Indirect cooling towers
Bibliography
- (1) - CAUDRON (L.) - Les réfrigérants atmosphériques industriels. - Collection de la Direction des Études et Recherches d'Électricité de France, Eyrolles (1991).
Also in our database
Standards and norms
- Tours de refroidissement. Essais de réception (Classe A) - AFNOR NF X 10-251 - 12-74
- Tours de refroidissement à tirage mécanique. Essais sur le site (Classe B) - AFNOR NF X 10-252 - 12-80
- Specification for water cooling tower - BSI 4485 - 1969
- Leistungsversuche an Kühlturmen - EV DIN 6.59 - 1947
Regulations
Law no. 64.1245 (December 1964): authorization for water abstraction and discharge.
Decree no. 73.218 (February 1973): commodo and in commodo survey/law no. 64-1245.
Orders implementing decree 73.218 (May 13, 1975).
Circular no. 75.114 (July 2, 1975): authorization review procedure in the event of accidental water pollution.
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Directory
Manufacturers – Suppliers – Distributors (non-exhaustive list)
GEA EGI cooling (Heller System) http://www.egi.hu
Air traitement (Sté Nouvelle) http://www.air-traitement.fr
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