Optimal inductor design for a 6.6 kW buck-boost converter
Magnetic components (such as transformers and inductors) play crucial roles in switch-mode power supplies, serving tasks like electrical isolation, voltage transformation, and energy buffering. They significantly impact the efficiency, size, and power density of the transformer. As the switching fre...
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2024
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sg-ntu-dr.10356-1762682024-05-17T15:48:56Z Optimal inductor design for a 6.6 kW buck-boost converter Xu, Dongchen Tang Yi School of Electrical and Electronic Engineering yitang@ntu.edu.sg Engineering Optimal inductor design Buck-boost converter Steinmetz equation Magnetic components (such as transformers and inductors) play crucial roles in switch-mode power supplies, serving tasks like electrical isolation, voltage transformation, and energy buffering. They significantly impact the efficiency, size, and power density of the transformer. As the switching frequency of the transformer continues to increase, the accuracy of high-frequency magnetic component design becomes more prominent in determining transformer performance. Therefore, optimizing the design and rational application of magnetic components is of utmost importance in enhancing the performance of power electronic converters. Achieving precise measurement and calculation of magnetic core losses is a prerequisite and essential condition for all these endeavors. In this paper, we first establish three different models based on magnetic core losses, such as the Steinmetz equation, Rayleigh relation, and parallel resistor model, and validate and analyze losses based on these models. By regressing and integrating complex mathematical derivation models, we obtain visualized loss analysis curves and validate them across different frequency ranges, ultimately deriving appropriate magnetic loss models. Regarding the winding losses, we explore the variation of factors such as the number of windings and permeability with fixed conductor dimensions, obtaining the optimal ratio of windings to magnetic core losses and further refining the loss analysis model. Finally, in the experimental phase, we conducted a comprehensive analysis of magnetic core losses in the inductor section of a high-power Buck-Boost converter environment. We compared and validated the feasibility of the design using data from the manufacturer's magnetic product manual, thereby achieving the research objectives of this paper. Master's degree 2024-05-15T00:43:49Z 2024-05-15T00:43:49Z 2024 Thesis-Master by Coursework Xu, D. (2024). Optimal inductor design for a 6.6 kW buck-boost converter. Master's thesis, Nanyang Technological University, Singapore. https://hdl.handle.net/10356/176268 https://hdl.handle.net/10356/176268 en application/pdf Nanyang Technological University |
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Engineering Optimal inductor design Buck-boost converter Steinmetz equation |
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Engineering Optimal inductor design Buck-boost converter Steinmetz equation Xu, Dongchen Optimal inductor design for a 6.6 kW buck-boost converter |
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Magnetic components (such as transformers and inductors) play crucial roles in switch-mode power supplies, serving tasks like electrical isolation, voltage transformation, and energy buffering. They significantly impact the efficiency, size, and power density of the transformer. As the switching frequency of the transformer continues to increase, the accuracy of high-frequency magnetic component design becomes more prominent in determining transformer performance. Therefore, optimizing the design and rational application of magnetic components is of utmost importance in enhancing the performance of power electronic converters. Achieving precise measurement and calculation of magnetic core losses is a prerequisite and essential condition for all these endeavors.
In this paper, we first establish three different models based on magnetic core losses, such as the Steinmetz equation, Rayleigh relation, and parallel resistor model, and validate and analyze losses based on these models. By regressing and integrating complex mathematical derivation models, we obtain visualized loss analysis curves and validate them across different frequency ranges, ultimately deriving appropriate magnetic loss models. Regarding the winding losses, we explore the variation of factors such as the number of windings and permeability with fixed conductor dimensions, obtaining the optimal ratio of windings to magnetic core losses and further refining the loss analysis model. Finally, in the experimental phase, we conducted a comprehensive analysis of magnetic core losses in the inductor section of a high-power Buck-Boost converter environment. We compared and validated the feasibility of the design using data from the manufacturer's magnetic product manual, thereby achieving the research objectives of this paper. |
| author2 |
Tang Yi |
| author_facet |
Tang Yi Xu, Dongchen |
| format |
Thesis-Master by Coursework |
| author |
Xu, Dongchen |
| author_sort |
Xu, Dongchen |
| title |
Optimal inductor design for a 6.6 kW buck-boost converter |
| title_short |
Optimal inductor design for a 6.6 kW buck-boost converter |
| title_full |
Optimal inductor design for a 6.6 kW buck-boost converter |
| title_fullStr |
Optimal inductor design for a 6.6 kW buck-boost converter |
| title_full_unstemmed |
Optimal inductor design for a 6.6 kW buck-boost converter |
| title_sort |
optimal inductor design for a 6.6 kw buck-boost converter |
| publisher |
Nanyang Technological University |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/176268 |
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1800916165852135424 |