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dc.contributor.advisorCilliers, A.C.
dc.contributor.authorVisagie, Herman
dc.date.accessioned2016-01-08T08:27:24Z
dc.date.available2016-01-08T08:27:24Z
dc.date.issued2015
dc.identifier.urihttp://hdl.handle.net/10394/15761
dc.descriptionMIng (Nuclear Engineering), North-West University, Potchefstroom Campus, 2015en_US
dc.description.abstractCurrent regulations specify the minimum number of operators required per nuclear power plant. However, these requirements are based on the operation of large nuclear power plants, which are not inherent safe and can result in a meltdown. For newly developed small nuclear reactors, the current number of operators seems to be excessive causing the technology to be less competitive. Before the number of required operators can be optimised, it should be demonstrated that human errors will not endanger or cause risk to the plant or public. For this study, a small pebble bed High Temperature Reactor (HTR) Nuclear Power Plant (NPP), the Th-100, was evaluated. The inherent safety features of this type of nuclear reactor include independent barriers for fission product capture and passive heat dissipation during a loss of coolant. The control and instrumentation architecture include two independent protection systems. The Control and Limitation System is the first protection system to react if the reactor parameters exceed those of the normal operational safe zone. If the Control and Limitation System fail to maintain the reactor within the safe zone, the Reactor Protection System would at that time operate and force the reactor to a safe state. Both these automated protection systems are installed in a control room local to the reactor building, protected from adverse conditions. In addition, it is connected to a semi-remote control room, anticipated as a multi-unit control room to include the monitoring and control of the auxiliary systems. Probable case studies of human error associated with multi-unit control rooms were evaluated against the logic of the Control and Limitation System. Fault Tree Analysis was used to investigate all possible failures. The evaluation determined the reliability of the Control and Limitation System and highlighted areas which design engineers should take into account if a higher reliability is required. The scenario was expanded, applying the same methods, to include the large release of fission products in order to verify the reliability calculations. The probability of a large release of fission products compared with studies done on other nuclear installations revealed to be much less for the evaluated HTR as was expected. As the study has proved that human error cannot have a negative influence on the safety of the reactor, it can be concluded that the first step has been met which is required, when applying for a waiver to utilise a multi-unit control room for the small pebble bed HTR NPP. Also, from the study, it is recommended that a practical approach be applied for the evaluation of operator duties on a live plant, to optimise the number of operators required. This in turn will position the inherent safe HTR competitively over other power stations.en_US
dc.language.isoenen_US
dc.subjectControl and Limitation Systemen_US
dc.subjectFault Tree Analysisen_US
dc.subjectHigh Temperature Reactor Nuclear Power Planten_US
dc.subjectHuman erroren_US
dc.subjectMulti-unit control roomen_US
dc.subjectPebble beden_US
dc.subjectProtection systemen_US
dc.subjectReactor Protection Systemen_US
dc.titleEvaluation and verification of an architecture suitable for a multi-unit control room of a pebble bed high temperature reactor nuclear power planten
dc.typeThesisen_US
dc.description.thesistypeMastersen_US


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