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FIGURE 1.

FIL DE MISE

*BOITE DE SORTIE

DE COURANT (C)

A LA TERRE

 

 

VIS DE

 

TROU LATERAL (K)

FIXATION (A)

 

 

CONNECTEURS

DE FIL (I)

*VIS DE LA BOITE DE

BARRE DE SORTIE DE COURANT (D)

FIXATION (B)

VIS DE MISE A LA TERRE (VERTE) (J)

CHAPEAU (L)

ECROUS

CAPUCHONS (M)

BRAS L’APPAREIL

D’ECLAIRAGE (E)

ANNERO DE

L’APPAREL

D;ECLAIRAGE (R)

RACCORD (H)

L’ECROU HEXAGONAL 1 (F1)

MANCHON FILETE (G)

 

CACHE

 

MANCHON (U)

ABAT-JOUR

 

EN VERRE (Q)

COUVERCLE (N)

 

RONDELLE EN

RONDELLE 1 (O1)

 

CAOTCHOUC (P)

 

 

RONDELLE 2 (O2)

L’ECROU HEXAGONAL 2 (F2)

CAPUCHON

 

 

DECORATIF (S)

Il est possible que le dessin illustré ici ne

 

soit pas la reproduction exacte de l’appareil

ECROU

d’éclairage contenu dans la boîte.

DECORATIF (T)

Les instructions d’installation demeurent

 

*NON FOURNI

cependant valables.

6

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Image 6
Westinghouse W-185 owner manual Ecrou

W-185 specifications

The Westinghouse W-185 is a notable entry in the landscape of nuclear power technology. Designed during the mid-20th century, this pressurized water reactor (PWR) has made significant contributions to the commercial nuclear power generation field. With a thermal power output of approximately 1,000 megawatts, the W-185 was conceived to meet the growing demands for robust and reliable energy sources in an increasingly electrified world.

One of the main features of the W-185 is its use of enriched uranium as fuel. This choice is a characteristic of PWRs, allowing for a more efficient fission process. The reactor operates at high pressure to keep the water in a liquid state, even at elevated temperatures, which is vital for maintaining efficiency in heat transfer. The design incorporates a secondary cooling system, wherein steam generated in the primary loop is transferred to a secondary loop for electricity generation through turbines.

The W-185 employs advanced safety systems that align with modern nuclear regulations and practices. Safety is bolstered by multiple backup systems, including redundant cooling mechanisms and containment structures designed to withstand significant external events. These safety features are critical in addressing potential concerns around nuclear accidents and ensuring public trust in the technology.

In terms of operational efficiency, the Westinghouse W-185 is equipped with automated control systems that facilitate real-time monitoring and adjustment of the reactor's functioning. Digital instrumentation enhances the ability to respond to operational anomalies, contributing to safer and more efficient operations. Further, the reactor has been designed to allow for extended operational lifespans through regular maintenance schedules and upgrades.

The Westinghouse W-185 plays a pivotal role in demonstrating the potential of nuclear energy as a clean and reliable power source. As countries around the world grapple with energy demands and the transition to reduced carbon emissions, technologies like the W-185 represent a crucial component in the energy mix. Its design illustrates how nuclear technology can meet energy needs while adherating to strict safety and environmental standards, making it an important case study in the evolution of nuclear power generation. The Westinghouse W-185 stands as a testament to the advancements in nuclear engineering and the future of sustainable energy.