Fringing effect on the dielectric constant measurement: experiment and simulation
All major supply components such as transformers and cables need to be in kept in perfect operating condition. Their insulation must be able to withstand high voltages stresses. Hence, it is crucial that their conditions can be verified throughout their life cycle. The measurement of permit...
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| Main Author: | |
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| Other Authors: | |
| Format: | Final Year Project |
| Language: | English |
| Published: |
2011
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/45738 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | All major supply components such as transformers and cables need to be in kept in
perfect operating condition. Their insulation must be able to withstand high voltages
stresses. Hence, it is crucial that their conditions can be verified throughout their life
cycle. The measurement of permittivity of dielectric material is important to identify
the partial discharge in the insulation of high voltage transmission application to
prevent any electrical breakdown.
This report covers the studying of the fringing effect on the measurement of
permittivity of different permittivity using Ansoft Maxwell simulation program.
This report begins with the utilization of Ansoft Maxwell 2D program to stimulate
and study the fringing effect on a pair of electrodes cylindrical model with dielectric
materials of various permittivities inserting between them. For further analysis
purpose, the simulation results will be exported out to Microsoft excel to undergo a
calculation procedure before obtaining the measured permittivity values and thus, a
comparison is made between the measured permittivity and intrinsic permittivity to
observe the fringing effect caused by the various permittivity.
To obtain a more precise result in the second half of the report, Ansoft Maxwell 3D is
used to simulate a pair of electrodes with dielectric materials of various permittivities
inserting between them.With the region under study increased by five times while the
dimension of the electrode capacitance model remain the same as first part, the results
obtained are more precise as compared to the result obtained in part 1.
Lastly, the report will end with a conclusion summarizing the knowledge the author
have gained from the final year project as well as the recommendation for further
enhancement in the future. |
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