Design and evaluation of metal oxide surge arrester parameters for lightning over voltages / Syahirah Abd. Halim
Surge arrester is widely used as a protective device to reduce possibility of flashover during transient overvoltage. It is important to understand the characteristics of surge arrester as over-specification of its rating will result in a reduction of the protective characteristics. Researches on...
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| Format: | Thesis |
| Published: |
2016
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| Online Access: | http://studentsrepo.um.edu.my/6721/4/syahirah.pdf http://studentsrepo.um.edu.my/6721/ |
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| Summary: | Surge arrester is widely used as a protective device to reduce possibility of flashover
during transient overvoltage. It is important to understand the characteristics of surge
arrester as over-specification of its rating will result in a reduction of the protective
characteristics. Researches on reliability and stability of surge arrester normally involve
detailed experimental works, which are usually not feasible due to high cost in
conducting test using actual prototype. The usage of computer tools in carrying out
virtual testing is important to verify the performance of the arresters in early stages
before proceeding with actual prototype built-up.
In this work, transmission line surge arresters with different dimensions and ratings
were modeled to investigate their discharge energy during lightning discharge using the
finite element analysis (FEA) method. The main advantage of FEA models in this work
is real dimensions of the actual surge arrester can be modeled, which may increase the
accuracy of the results obtained. To validate the accuracy of the method, the arrester
models were also simulated by the use of PSCAD/EMTDC and EMTP-RV software
and compared with the specifications provided by the manufacturer. In spite of
distinctive representations of the arrester models in COMSOL Multiphysics, EMTP-RV
and PSCAD/EMTDC, the comparison made between the results indicates a satisfactory
agreement. Parametric analyses were also conducted using finite element method to
study the effects of varying the design geometry of the arresters, which cannot be
evaluated using PSCAD and EMTP-RV software.
The surge arrester models that have been developed were then used in designing
protection scheme for a 275/132 kV quadruple circuit transmission line in Malaysia.
The best arrester configuration was selected by considering the effects of tower footing
resistance, lightning current and power frequency angle on the line lightning performance. Improvement on the lightning performance could be achieved by
installing surge arresters on all phases of a 132 kV circuit, where the double circuit
outages were successfully eliminated. The results are useful for the utility company in
determining the most effective installation position with the minimum number of
installed surge arresters. |
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