Probabilistic analysis on the failure of reactivity control for the PWR

The fundamental safety function of the power reactor is to control reactivity, to remove heat from the reactor, and to confine radioactive material. The safety analysis is used to ensure that each parameter is fulfilled during the design and is done by deterministic and probabilistic method. The ana...

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Bibliographic Details
Published in:Journal of physics. Conference series 2018-02, Vol.962 (1), p.12046
Main Authors: Tjahyani, D T Sony, Deswandri, Sunaryo, G R
Format: Article
Language:English
Subjects:
Assembly
Boron
Control rods
Dilution
Error analysis
Failure
Failure analysis
Fault tree analysis
Fuels
Fundamental safety function
Human error
Misalignment
Nuclear fuels
Nuclear safety
Physics
Power reactors
Pressurized water reactors
Probabilistic
Probabilistic analysis
Probabilistic methods
PWR
Radioactive materials
Reactivity
Reactivity control
Safety analysis
Statistical analysis
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Summary:The fundamental safety function of the power reactor is to control reactivity, to remove heat from the reactor, and to confine radioactive material. The safety analysis is used to ensure that each parameter is fulfilled during the design and is done by deterministic and probabilistic method. The analysis of reactivity control is important to be done because it will affect the other of fundamental safety functions. The purpose of this research is to determine the failure probability of the reactivity control and its failure contribution on a PWR design. The analysis is carried out by determining intermediate events, which cause the failure of reactivity control. Furthermore, the basic event is determined by deductive method using the fault tree analysis. The AP1000 is used as the object of research. The probability data of component failure or human error, which is used in the analysis, is collected from IAEA, Westinghouse, NRC and other published documents. The results show that there are six intermediate events, which can cause the failure of the reactivity control. These intermediate events are uncontrolled rod bank withdrawal at low power or full power, malfunction of boron dilution, misalignment of control rod withdrawal, malfunction of improper position of fuel assembly and ejection of control rod. The failure probability of reactivity control is 1.49E-03 per year. The causes of failures which are affected by human factor are boron dilution, misalignment of control rod withdrawal and malfunction of improper position for fuel assembly. Based on the assessment, it is concluded that the failure probability of reactivity control on the PWR is still within the IAEA criteria.
ISSN:1742-6588
1742-6596
DOI:10.1088/1742-6596/962/1/012046