Westinghouse W-164 owner manual Schéma

Page 6

FIGURE 1.

TROU LATERAL (P)

BARRE DE FIXATION (A)

FIL DE MISE A LA TERRE

*BOITE DE SORTIE DE COURANT (B)

CONNECTEURS

DE FIL (N)

*VIS DE LA BOITE DE SORTIE DE COURANT (C)

VIS DE MISE

RONDELLE DE BLOCAGE (F)

A LA TERRE

L’ECROU HEXAGONAL (D)

(VERTE) (O)

MANCHON

 

COLLIER

FILET DE

FILETE (L)

FIXATION (E)

 

CHAPEAU (M)

 

LA BAGUE

SCHÉMA

 

DU COLLIER

 

FILETE (K)

PANNEAU DE

 

VERRE (Q)

CHAINE (J)

PINCES (R)

 

LA BOUCLE DE L’APPAREIL

 

D’ECLAIRAGE (I)

 

CAGE DE

L’APPAREIL

D’ECLAIRAGE (G)

Il est possible que le dessin illustré ici ne soit pas la reproduction exacte

 

de l’appareil d’éclairage contenu dans la boîte.

 

*NON FOURNI

Les instructions d’installation demeurent cependant valables.

 

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Contents Outdoor Lighting Fixture Installation Instructions Warranty Information Assembly Instructions for Outdoor Light FixtureInset Mounting and Wiring Instructions Fixture Assembly InstructionsGarantie Limitée DE Cinq ANS Schéma Instructions DE Montage ET DE Raccordement Garantía Limitada DE Cinco Años Advertencia UNA Descarga Eléctrica Podría Causar LesionesFigura RecuadroInstrucciones DE Montaje Y Cableado Instrucciones DE Montaje DEL ArtefactoMise EN Garde Ordering Parts Cleaning and CareCommande DE Pièces Nettoyage ET Entretien

W-164 specifications

The Westinghouse W-164 is a significant model in the realm of nuclear technology, specifically known for its advancements in pressurized water reactor (PWR) design. Developed during the mid-20th century, the W-164 showcases innovative engineering and safety features that cater to the increasing demand for reliable energy sources.

One of the main features of the W-164 is its efficient heat exchange system. The reactor employs a steam generator that utilizes the pressurized water to transfer heat to a secondary water circuit, thus producing steam for turbine generators. This method enhances the efficiency of thermal energy conversion while allowing for a compact plant design.

The W-164 also emphasizes safety through its robust containment structures. Designed to withstand extreme conditions, including natural disasters and potential accidents, the containment system minimizes the risk of radioactive material release. Additionally, the reactor is equipped with multiple redundant safety systems, including emergency core cooling systems, designed to ensure the reactor core remains cooled even under abnormal conditions.

Another notable technology integrated into the W-164 is its advanced control and instrumentation systems. These systems provide real-time data on reactor performance and conditions, enabling operators to make informed decisions and maintain optimal performance. The control systems are designed for reliability and ease of use, promoting operational safety.

The W-164 utilizes low-enriched uranium fuel, optimizing the fuel cycle and minimizing waste. This feature aligns with the industry's push towards sustainability and environmental considerations. The reactor's design also allows for longer operational cycles, reducing the frequency of refueling and further enhancing its overall efficiency.

In terms of physical characteristics, the W-164 is designed to fit within a compact footprint, making it suitable for a variety of operational environments. Its modular construction allows for easier maintenance and upgrades, ensuring the reactor remains competitive in a rapidly evolving energy landscape.

Overall, the Westinghouse W-164 stands out for its innovative design, efficiency, and safety features. As global energy demands increase and the need for sustainable solutions intensifies, the technologies developed in the W-164 can provide valuable insights and pave the way for future advancements in nuclear energy. Its legacy continues to influence modern reactor designs, highlighting the importance of reliability and safety in energy production.