FIGURE 1. *BOITE DE SORTIE DE COURANT (C)

SIDE HOLE (G)

VIS DE

FIXATION (A)

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

CHAPEAU (H)

RACCORD (S)

L'ABAT-JOUR (R)

L’ECROU

HEXAGONAL (T) LA RONDELLE PLATE (Q)

RONDELLE EN

CAOTCHOUC (P)

FIL DE MISE

A LA TERRE

BARRE

TRANSVERSALE (B)

CONNECTEURS

DE FIL (E)

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

ECROUS

CAPUCHONS (I)

MANCHON

FILETE (J)

RACCORD (V)

MANCHON

FILETE (K)

GLOBE DE

VERRE (J)

LA RONDELLE PLATE (L)

L’ECROU

HEXAGONAL (O)

CAPUCHON (M)

ECROU DECORATIF (N)

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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Westinghouse W-367 owner manual Les instructions d’installation demeurent cependant valables

W-367 specifications

The Westinghouse W-367 is a noteworthy model in the realm of nuclear reactors, particularly designed for educational purposes and research applications. Developed by the Westinghouse Electric Corporation in the mid-20th century, this reactor is recognized for its compact design and innovative engineering, which provides an efficient means for nuclear experimentation and training.

One of the main features of the W-367 is its pool-type design, where the reactor core is submerged in a large pool of water. This not only serves as adequate radiation shielding but also provides effective cooling for the reactor. The water in the pool absorbs neutron radiation, thereby ensuring a safer environment for both operators and researchers. This design feature significantly enhances the operational safety of the reactor, making it an ideal choice for academic institutions and research facilities.

The W-367 utilizes low-enriched uranium fuel, which is suitable for many research applications. This choice of fuel allows for a higher level of flexibility in experimentation while also ensuring compliance with regulatory standards. Its low power output, typically around 1 megawatt, makes it less hazardous than higher-capacity reactors, which is essential for educational users or smaller-scale research projects.

Another standout characteristic of the W-367 is its advanced control systems. The reactor is equipped with a series of control rods made from materials capable of effectively capturing neutrons, allowing for precise manipulation of the reactor's power levels. This feature gives operators fine control over the fission process, which is essential during experiments and demonstrations.

The instrumentation integrated into the W-367 allows for continuous monitoring of critical parameters such as temperature, radiation levels, and power output. These monitoring systems are crucial for maintaining safety and performance standards without interrupting operations.

In summary, the Westinghouse W-367 reflects a combination of innovative engineering and operational safety, making it a valuable asset in the fields of education and research. Its pool-type design, low-enriched uranium fuel use, and advanced control systems contribute to a robust platform for nuclear experimentation, making it an exemplary model in the landscape of nuclear reactors.