A Mechanistic Model to Predict Fuel Channel Failure in the Event of Pressure Tube Overheating

Please use this identifier to cite or link to this item: http://hdl.handle.net/11375/20647

Title:	A Mechanistic Model to Predict Fuel Channel Failure in the Event of Pressure Tube Overheating
Other Titles:	A Model to Predict Fuel Channel Failure
Authors:	Dion, Alexander
Advisor:	Luxat, John
Department:	Engineering Physics
Keywords:	Thermal Hydraulics;CANDU;Fuel Channel Failure;Film Boiling
Publication Date:	2016
Abstract:	Under normal operating conditions a CANDU reactor pressure tube (PT) is insulated from its outer calandria tube (CT) by a CO2 gas annulus. If the primary loop coolant flow is compromised the PT can overheat and, if still pressurized, balloon into contact with the CT. At this point the moderator acts as an emergency heat sink. If the heat transferred from the CT to the moderator exceeds the critical heat flux (CHF) the CT can overheat, begin to strain due to the contact pressure, and eventually fail. A mechanistic model is presented that describes ballooning contact of the PT and CT, the resulting thermal contact conductance, heat flux to the moderator, and, if CHF is exceeded, the development of film boiling and potential CT strain. The goal is to create a software package that predicts fuel channel failure during a pressure tube overheat event.
URI:	http://hdl.handle.net/11375/20647
Appears in Collections:	Open Access Dissertations and Theses

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