Numerical Simulation Study on the Air/Water Counter- current Flow Limitation in Nuclear Reactors
DOI:
https://doi.org/10.15392/bjrs.v8i3B.610Palabras clave:
Countercurrent Fow Limitation (CCFL), Computational fluid dynamics, LOCA, PWR.Resumen
After a loss-of-coolant accident (LOCA) in a Pressurized Water Reactor (PWR), the temperature of the fuel elements cladding increases dramatically due to the heat produced by the fission products decay, which is not adequately
removed by the vapor contained in the core. In order to avoid this sharp rise in temperature and consequent melting of the core, the Emergency Core Cooling System is activated. This system initially injects borated water from accumulator
tanks of the reactor through the inlet pipe (cold leg) and the outlet pipe (hot leg), or through the cold leg only, depending on the plant manufacturer. Some manufacturers add to this, direct injection into the upper plenum of the
reactor. The penetration of water into the reactor core is a complex thermofluidodynamic process because it involves the mixing of water with the vapor contained in the reactor, added to that generated in the contact of the water with the still hot surfaces in various geometries. In some critical locations, the vapor flowing in the opposite direction of the water can control the penetration of this into the core. This phenomenon is known as Countercurrent Flow Limitation (CCFL) or Flooding, and it are characterized by the control that a gas exerts in the liquid flow in the opposite direction.
This work presents a proposal to use a CFD to simulate the CCFL phenomenon. Numerical computing can provide important information and data that is difficult or expensive to measure or test experimentally. Given the importance of
computational science today, it can be considered a third and independent branch of science on an equal footing with the theoretical and experimental sciences.
Descargas
Referencias
Al Issa, S.; Macian, R. Experimental investigation of countercurrent flow limitation (CCFL) in a large-diameter hot-leg geometry: A detailed description of CCFL mechanisms, flow patterns and high-quality HSC imaging of the interfacial structure in a 1/3.9 scale of PWR geometry. Nucl. Eng.
Des. V. 280, p. 550-563, 2014.
Navarro, M.A. Study of countercurrent flow limitation in a horizontal pipe connected to an inclined one. Nucl. Eng. Des. V. 235, p. 1139-1148, 2005.
Al Issa, S.; Macian, R. A review of CCFL phenomenon. Annals of Nuclear Energy. V. 38, p. 1795-1819, 2011.
Chistophe V; et Al. Counter –current flow limitation in a model of the hot leg of a PWR – comparison between air/water and steam/water experiments. Nuc.Eng.Des. V. 245, p. 113-124, 2012.
Deendarlianto; Thomas Hohne; Dirk Lucas; Karen Vierow; Gas-liquid countercurrent two-phase flow in a PWR hot leg: A comprehensive research review. Nuc. Eng.Des. V. 243, p. 214-233, 2011.
Descargas
Publicado
Número
Sección
Licencia
Derechos de autor 2021 Brazilian Journal of Radiation Sciences (BJRS)
Esta obra está bajo una licencia internacional Creative Commons Atribución 4.0.
Licencia: los artículos de BJRS tienen una licencia internacional Creative Commons Attribution 4.0, que permite el uso, el intercambio, la adaptación, la distribución y la reproducción en cualquier medio o formato, siempre que se otorgue el crédito correspondiente al autor o autores originales y a la fuente, proporcione un enlace a la licencia Creative Commons e indique si se realizaron cambios. Las imágenes u otros materiales de terceros en el artículo están incluidos en la licencia Creative Commons del artículo, a menos que se indique lo contrario en una línea de crédito al material. Si el material no está incluido en la licencia Creative Commons del artículo y su uso previsto no está permitido por la regulación legal o excede el uso permitido, el autor deberá obtener el permiso directamente del titular de los derechos de autor. Para ver una copia de esta licencia, visite http://creativecommons.org/licenses/by/4.0/
