Heat Generation Summary

Heat Transfer HEAT GENERATION If this corrosion layer is allowed to form, a larger temperature difference will be required between the coolant and fuel to maintain the same heat flux. Therefore, operation at the same power level will cause higher fuel temperatures after the buildup of corrosion products and crud. Summary The important information in this chapter is summarized below: Heat Generation Summary • The power generation process in a nuclear core is directly proportional to the fission rate of the fuel and the thermal neutron flux present. • The thermal power produced by a reactor is directly related to the mass flow rate of the reactor coolant and the temperature difference across the core. • The nuclear enthalpy rise hot channel factor is the ratio of the total kW heat generation along a fuel rod with the highest total kW, to the total kW of the average fuel rod. • The average linear power density in the core is the total thermal power divided by the active length of the fuel rods. • The nuclear heat flux hot channel factor is the ratio of the maximum heat flux expected at any area to the average heat flux for the core. • The total heat output of a reactor core is called the heat generation rate. • The heat generation rate divided by the volume of fuel will give the average volumetric thermal source strength. Rev. 0 Page 51 HT-02