Uncertainty analysis of the control rod drop based on the adaptive collocation stochastic perturbation method.

• A deterministic simplified model of the control rod drop and fluid flow is established. • A fifth-order adaptive collocation stochastic perturbation (ACSP) method is established to approximate the random responses. • The uncertainty analysis of the CR drop based on the ACSP method is carried out in both large and small reactor. • The research results can provide guidance for the analysis and design optimization of the control rod scram process. There are many uncertain factors to affect the control rod drop from its design and manufacture to the chain reaction in the reactor. They have to be considered in the simulation to realistically predict the dynamic behavior of control rod drop. Different from the previous method by using the nominal and extreme values of the uncertain factors, a statistical method is applied in this paper to analyze them in the process of the control rod drop. The uncertain factors obey uniform distribution, based on which a fifth-order adaptive collocation stochastic perturbation (ACSP) method is established in this paper, which is featured with simple format, high precision, and high calculation efficiency. The mean and standard deviation of the responses (such as the final time of the control rod drop) in two different types of reactors are calculated by using the ACSP method. On this basis, the response intervals and corresponding probabilities of the control rod drop are obtained. Besides, influences of each random variable on the responses are analyzed by the sensitivity analysis. In addition, the linear correlation degree and correlation between the two are discussed through the correlation coefficient of random variables and the responses. The uncertainty analysis of control rod drop in this paper not only provides a relatively strong theoretical support for scientifically dealing with uncertain factors, but also offers specific help for the optimal design of control rod assembly. [ABSTRACT FROM AUTHOR]