Modeling and simulation of loss of the ultimate heat sink in a typical material testing reactor

A thermal–hydraulic model has been developed to simulate loss of the ultimate heat sink in a typical material testing reactor (MTR). The model involves three interactively coupled sub-models for reactor core, heat exchanger and cooling tower. The model is validated against PARET code for steady-state operation and verified by the reactor operation records for transients. Then, the model is used to simulate the thermal–hydraulic behavior of the reactor under a loss of the ultimate heat sink event. The simulation is performed for two operation regimes: regime I representing 11 MW power and three cooling tower cells operated, and regime II representing 22 MW power and six cooling tower cells operated. In regime I, the simulation is performed for 1, 2 and 3 cooling tower cells failed while in regime II, it is performed for 1, 2, 3, 4, 5 and 6 cooling tower cells failed. The simulation is performed under protected conditions where the safety action called power reduction is triggered by reactor protection system to decrease the reactor power by 20% when the coolant inlet temperature to the core reaches 43 °C and scram is triggered if the core inlet temperature reaches 44 °C. The model results are analyzed and discussed.

► A thermal–hydraulic model has been developed to simulate loss of the ultimate heat sink in MTR.
► The model involves three coupled sub-models for core, heat exchanger and cooling tower.
► The model is validated against PARET for steady-state and verified by operation data for transients.
► The model is used to simulate the behavior of the reactor under a loss of the ultimate heat sink.
► The model results are analyzed and discussed.