Simulation flux distribution and loss calculation of three phase transformer core 100kVA using FEM
This theses describes result of simulation flux distribution and loss calculation on three phase transformer core 100kVA using FEM. From these theses, best material and best T-Joint configuration can be found. It’s important to make sure transformers work at 100% efficiency. Transformer is a device...
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Universiti Malaysia Perlis
2009
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my.unimap-44822017-11-29T09:03:05Z Simulation flux distribution and loss calculation of three phase transformer core 100kVA using FEM Izzat, Rosli Dina Maizana, Ir. (Advisor) Flux distribution Electric transformers Power loss Transformer core Magnetic flux This theses describes result of simulation flux distribution and loss calculation on three phase transformer core 100kVA using FEM. From these theses, best material and best T-Joint configuration can be found. It’s important to make sure transformers work at 100% efficiency. Transformer is a device that transfers electrical energy from one circuit to another circuit with a shared magnetic field. Transformer can converts voltage by step-up and step-down. The transformer core is used to provide a controlled path for the magnetic flux which generated in the transformer. The core is built up from thin sheet – steel with many layers of lamination. The lamination that is used to reduce heating on transformer core will cause power losses. Three types of transformer core were used in this simulation such as M5, MOH and ZDKH. T-Joint configuration is importance in avoidance the losses. Transformer core configurations in this simulation were 23˚ T-Joint, 45˚ T-Joint, 60˚ TJoint and 90˚ T-Joint. Simulation on power loss and flux distribution will be done by using FEM software called Quickfield 5.5. QuickField is an interactive environment for electromagnetic, thermal and stress analysis. QuickField can perform linear and nonlinear magnetostatic analysis for 2-D and axisymmetric models. Flux density for M5 was 1.79T better than the MOH and ZDKH material which only 0.207T and 0.214T. Best T-Joint configuration for each material was 60˚ T-Joint. Flux line, flux density and T-Joint configuration were an important factor in causing the differences in performance. 2009-02-04T02:38:01Z 2009-02-04T02:38:01Z 2008-04 Learning Object http://hdl.handle.net/123456789/4482 en Universiti Malaysia Perlis School of Electrical Systems Engineering |
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Flux distribution Electric transformers Power loss Transformer core Magnetic flux |
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Flux distribution Electric transformers Power loss Transformer core Magnetic flux Izzat, Rosli Simulation flux distribution and loss calculation of three phase transformer core 100kVA using FEM |
| description |
This theses describes result of simulation flux distribution and loss calculation on
three phase transformer core 100kVA using FEM. From these theses, best material and best T-Joint configuration can be found. It’s important to make sure transformers work at 100% efficiency. Transformer is a device that transfers electrical energy from one circuit to another circuit with a shared magnetic field. Transformer can converts voltage by step-up and step-down. The transformer core is used to provide a controlled path for the magnetic flux which generated in the transformer. The core is built up from thin sheet – steel with
many layers of lamination. The lamination that is used to reduce heating on transformer
core will cause power losses. Three types of transformer core were used in this simulation
such as M5, MOH and ZDKH. T-Joint configuration is importance in avoidance the losses. Transformer core configurations in this simulation were 23˚ T-Joint, 45˚ T-Joint, 60˚ TJoint and 90˚ T-Joint. Simulation on power loss and flux distribution will be done by using FEM software called Quickfield 5.5. QuickField is an interactive environment for electromagnetic, thermal and stress analysis. QuickField can perform linear and nonlinear magnetostatic analysis for 2-D and axisymmetric models. Flux density for M5 was 1.79T better than the MOH and ZDKH material which only 0.207T and 0.214T. Best T-Joint
configuration for each material was 60˚ T-Joint. Flux line, flux density and T-Joint
configuration were an important factor in causing the differences in performance. |
| author2 |
Dina Maizana, Ir. (Advisor) |
| author_facet |
Dina Maizana, Ir. (Advisor) Izzat, Rosli |
| format |
Learning Object |
| author |
Izzat, Rosli |
| author_sort |
Izzat, Rosli |
| title |
Simulation flux distribution and loss calculation of three phase transformer core 100kVA using FEM |
| title_short |
Simulation flux distribution and loss calculation of three phase transformer core 100kVA using FEM |
| title_full |
Simulation flux distribution and loss calculation of three phase transformer core 100kVA using FEM |
| title_fullStr |
Simulation flux distribution and loss calculation of three phase transformer core 100kVA using FEM |
| title_full_unstemmed |
Simulation flux distribution and loss calculation of three phase transformer core 100kVA using FEM |
| title_sort |
simulation flux distribution and loss calculation of three phase transformer core 100kva using fem |
| publisher |
Universiti Malaysia Perlis |
| publishDate |
2009 |
| url |
http://dspace.unimap.edu.my/xmlui/handle/123456789/4482 |
| _version_ |
1643802694322749440 |
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13.214268 |