Time constants and feedback transfer functions of EBR-II subassembly types

“…some (weighted) average of fuel and moderator and/or coolant temperature. The same can be done for the thermal hydraulic part which leads to a description in the form of feedback transfer functions with time constants characteristic for the physical system; an example of this approach is given by Grimm and Meneghetti (1987) for the case of a fast reactor. For practical reasons it is even more elegant to parametrize the reactivity effects as a function of well-defined operational variables, like coolant temperature at the inlet of the core, reactor power and the power-to-coolant flow ratio.…”

Physics of nuclear reactor safety

“…some (weighted) average of fuel and moderator and/or coolant temperature. The same can be done for the thermal hydraulic part which leads to a description in the form of feedback transfer functions with time constants characteristic for the physical system; an example of this approach is given by Grimm and Meneghetti (1987) for the case of a fast reactor. For practical reasons it is even more elegant to parametrize the reactivity effects as a function of well-defined operational variables, like coolant temperature at the inlet of the core, reactor power and the power-to-coolant flow ratio.…”

Physics of nuclear reactor safety

Reactivity-induced time-dependencies of EBR-II linear and non-linear feedbacks

Power-induced power and power-to-flow transfer functions for EBR-II subassemblies