Xyn-converter used in isolated two-phase three-wire AC power grids
| Ano de defesa: | 2024 |
|---|---|
| Autor(a) principal: | |
| Orientador(a): | |
| Banca de defesa: | |
| Tipo de documento: | Tese |
| Tipo de acesso: | Acesso aberto |
| Idioma: | eng |
| Instituição de defesa: |
Universidade Federal de Minas Gerais
|
| Programa de Pós-Graduação: |
Não Informado pela instituição
|
| Departamento: |
Não Informado pela instituição
|
| País: |
Não Informado pela instituição
|
| Palavras-chave em Português: | |
| Link de acesso: | https://hdl.handle.net/1843/76015 |
Resumo: | Isolated electric AC power grids are feasible solutions to energize remote communities, usually based on renewables and energy storage devices, interfaced by power electronics converters that require high reliability. The key element of such a system is the grid-forming converter that provides the voltage magnitude and frequency to other devices, such as loads. Therefore, this dissertation proposes the two-phase three-wire (2Φ3W) xyn-converter applied in a case study of isolated riverside communities in the Brazilian Amazon region. This dissertation compares the current stresses of grid-forming converters (GFC) under an isolated grid mission profile, considering three different grid configurations in terms of the displacement angle between the voltage in the phases: 90◦ (αβn-GFC); 120◦ (abn-GFC) and 180◦ (xyn-GFC). Additionally, analytical expressions for current stress through the semiconductors and the DC-link capacitor are obtained for each converter under balanced and unbalanced load conditions. The lifetime analysis of the grid-forming converter indicates that the xyn-GFC has the lowest wear-out. Furthermore, this work highlights the influence of high-frequency components on the RMS current of the DC-link capacitor. The xyn-GFC demonstrates a lower probability of capacitor failure compared to the other converters, even with higher low-frequency components. A sensitivity analysis shows that the xyn-GFC can increase its output power in 12% or reduce its heatsink volume in 25% to achieve the same wear-out B10 lifetime as the abn-GFC (i.e., benchmark) under nominal conditions. An experiment is conducted using a full-bridge converter and discrete IGBTs to measure the power losses in the semiconductors and the case temperature of the IGBTs. Compared with the αβn-converter, the xyn-converter shows 44% lower power losses, and the abn-converter shows 18% lower power losses. Finally, the thermal stress analysis is validated by means of a 2Φ3W converter prototype with an open semiconductor module. For the evaluated converters, the xyn-GFC has the lowest thermal stress for balanced and unbalanced load conditions and therefore the longest lifetime. Experimental validation shows that the average temperature of the xyn-GFC is 19.4% and 23.3% lower than both the abn-GFC and the αβn-GFC under balanced load conditions. |
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2024-09-09T15:17:31Z2025-09-09T01:30:51Z2024-09-09T15:17:31Z2024-02-29https://hdl.handle.net/1843/76015Isolated electric AC power grids are feasible solutions to energize remote communities, usually based on renewables and energy storage devices, interfaced by power electronics converters that require high reliability. The key element of such a system is the grid-forming converter that provides the voltage magnitude and frequency to other devices, such as loads. Therefore, this dissertation proposes the two-phase three-wire (2Φ3W) xyn-converter applied in a case study of isolated riverside communities in the Brazilian Amazon region. This dissertation compares the current stresses of grid-forming converters (GFC) under an isolated grid mission profile, considering three different grid configurations in terms of the displacement angle between the voltage in the phases: 90◦ (αβn-GFC); 120◦ (abn-GFC) and 180◦ (xyn-GFC). Additionally, analytical expressions for current stress through the semiconductors and the DC-link capacitor are obtained for each converter under balanced and unbalanced load conditions. The lifetime analysis of the grid-forming converter indicates that the xyn-GFC has the lowest wear-out. Furthermore, this work highlights the influence of high-frequency components on the RMS current of the DC-link capacitor. The xyn-GFC demonstrates a lower probability of capacitor failure compared to the other converters, even with higher low-frequency components. A sensitivity analysis shows that the xyn-GFC can increase its output power in 12% or reduce its heatsink volume in 25% to achieve the same wear-out B10 lifetime as the abn-GFC (i.e., benchmark) under nominal conditions. An experiment is conducted using a full-bridge converter and discrete IGBTs to measure the power losses in the semiconductors and the case temperature of the IGBTs. Compared with the αβn-converter, the xyn-converter shows 44% lower power losses, and the abn-converter shows 18% lower power losses. Finally, the thermal stress analysis is validated by means of a 2Φ3W converter prototype with an open semiconductor module. For the evaluated converters, the xyn-GFC has the lowest thermal stress for balanced and unbalanced load conditions and therefore the longest lifetime. Experimental validation shows that the average temperature of the xyn-GFC is 19.4% and 23.3% lower than both the abn-GFC and the αβn-GFC under balanced load conditions.engUniversidade Federal de Minas GeraisConversor formador de redeRedes isoladas CAConfiabilidadeRedes elétricasConversores eletrônicosConfiabilidade (Engenharia)Potência reativa (Engenharia elétrica)SemicondutoresXyn-converter used in isolated two-phase three-wire AC power gridsinfo:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/doctoralThesisJoão Henrique de Oliveirainfo:eu-repo/semantics/openAccessreponame:Repositório Institucional da UFMGinstname:Universidade Federal de Minas Gerais (UFMG)instacron:UFMGhttps://lattes.cnpq.br/0394982647829977Danilo Iglesias Brandãohttp://lattes.cnpq.br/0819806116588254Allan Fagner CupertinoPedro Gomes BarbosaFabrício BradaschiaLenin Martins Ferreira MoraisVictor Flores MendesRedes elétricas CA isoladas são soluções viáveis para energizar comunidades remotas, geralmente baseadas em energias renováveis e armazenadores de energia, conectadas por conversores eletrônicos de potência que exigem alta confiabilidade. O elemento-chave de tal sistema é o conversor formador de rede, que fornece magnitude de tensão e frequência aos demais elementos, como cargas. Assim, esta tese propõe o conversor-xyn bifásico a três fios (2Φ3W) aplicado a um estudo de caso em comunidades isoladas ribeirinhas na região amazônica brasileira. A tese compara o estresse de corrente de conversores formadores de rede (GFC), considerando três configurações diferentes de rede em termos de ângulos de deslocamento entre as tensões de fase: 90 (αβn-GFC); 120◦ (abn-GFC) and 180◦(xyn-GFC). Além disso, são obtidas expressões analíticas para o estresse de corrente nos semicondutores e no capacitor do barramento CC para cada conversor em condições de carga generalizada, i.e., balanceada e desbalanceada. A análise de vida útil do conversor formador de rede indica que o xyn-GFC tem o menor desgaste. Além disso, este trabalho destaca a influência de componentes harmônicas de alta frequência na corrente RMS do capacitor do barramento CC. O xyn-GFC demonstra uma menor probabilidade de falha do capacitor em comparação com os outros conversores, mesmo apresentando componentes de corrente de baixa frequência mais altos. Uma análise de sensibilidade mostra que o conversor formador de rede xyn-GFC pode aumentar sua potência de saída em 12% ou reduzir o volume do dissipador de calor em 25% para atingir a mesma vida útil B10 que o abn-GFC (considerado como referência) em condições nominais. Um experimento é conduzido usando um conversor de ponte completa e IGBTs discretos para medir as perdas de potência nos semicondutores e a temperatura de case dos IGBTs. Em comparação com o αβn-GFC, o xyn-GFC mostra perdas de potência 44% menores, e o abn-GFC mostra perdas de potência 18% inferiores. Por fim, a análise de estresse térmico é validada por meio de um protótipo de conversor 2Φ3W com módulo semicondutor aberto. Para os conversores avaliados, o xyn-GFC tem o menor estresse térmico para condições de carga balanceada e desbalanceada, portanto, indicando uma vida útil mais longa. A validação experimental mostra que a temperatura média do xyn-GFC é 19,4% e 23,3% menor do que os conversores abn-GFC e αβn-GFC em condições de carga balanceada, respectivamente.BrasilENG - DEPARTAMENTO DE ENGENHARIA ELÉTRICAPrograma de Pós-Graduação em Engenharia ElétricaUFMGORIGINALtese_jhdeoliveira_vf.pdfapplication/pdf58715559https://repositorio.ufmg.br//bitstreams/bafa90b5-a093-4ba7-a9ca-ec0dcfad25a3/downloade7c3c886ff72131bfa9ebe424789f048MD51trueAnonymousREADLICENSElicense.txttext/plain2118https://repositorio.ufmg.br//bitstreams/8d6c172e-9b64-4a8b-98ca-ca407f1cc57f/downloadcda590c95a0b51b4d15f60c9642ca272MD52falseAnonymousREAD1843/760152025-09-08 22:30:51.012open.accessoai:repositorio.ufmg.br:1843/76015https://repositorio.ufmg.br/Repositório InstitucionalPUBhttps://repositorio.ufmg.br/oairepositorio@ufmg.bropendoar:2025-09-09T01:30:51Repositório Institucional da UFMG - Universidade Federal de Minas Gerais (UFMG)falseTElDRU7Dh0EgREUgRElTVFJJQlVJw4fDg08gTsODTy1FWENMVVNJVkEgRE8gUkVQT1NJVMOTUklPIElOU1RJVFVDSU9OQUwgREEgVUZNRwoKQ29tIGEgYXByZXNlbnRhw6fDo28gZGVzdGEgbGljZW7Dp2EsIHZvY8OqIChvIGF1dG9yIChlcykgb3UgbyB0aXR1bGFyIGRvcyBkaXJlaXRvcyBkZSBhdXRvcikgY29uY2VkZSBhbyBSZXBvc2l0w7NyaW8gSW5zdGl0dWNpb25hbCBkYSBVRk1HIChSSS1VRk1HKSBvIGRpcmVpdG8gbsOjbyBleGNsdXNpdm8gZSBpcnJldm9nw6F2ZWwgZGUgcmVwcm9kdXppciBlL291IGRpc3RyaWJ1aXIgYSBzdWEgcHVibGljYcOnw6NvIChpbmNsdWluZG8gbyByZXN1bW8pIHBvciB0b2RvIG8gbXVuZG8gbm8gZm9ybWF0byBpbXByZXNzbyBlIGVsZXRyw7RuaWNvIGUgZW0gcXVhbHF1ZXIgbWVpbywgaW5jbHVpbmRvIG9zIGZvcm1hdG9zIMOhdWRpbyBvdSB2w61kZW8uCgpWb2PDqiBkZWNsYXJhIHF1ZSBjb25oZWNlIGEgcG9sw610aWNhIGRlIGNvcHlyaWdodCBkYSBlZGl0b3JhIGRvIHNldSBkb2N1bWVudG8gZSBxdWUgY29uaGVjZSBlIGFjZWl0YSBhcyBEaXJldHJpemVzIGRvIFJJLVVGTUcuCgpWb2PDqiBjb25jb3JkYSBxdWUgbyBSZXBvc2l0w7NyaW8gSW5zdGl0dWNpb25hbCBkYSBVRk1HIHBvZGUsIHNlbSBhbHRlcmFyIG8gY29udGXDumRvLCB0cmFuc3BvciBhIHN1YSBwdWJsaWNhw6fDo28gcGFyYSBxdWFscXVlciBtZWlvIG91IGZvcm1hdG8gcGFyYSBmaW5zIGRlIHByZXNlcnZhw6fDo28uCgpWb2PDqiB0YW1iw6ltIGNvbmNvcmRhIHF1ZSBvIFJlcG9zaXTDs3JpbyBJbnN0aXR1Y2lvbmFsIGRhIFVGTUcgcG9kZSBtYW50ZXIgbWFpcyBkZSB1bWEgY8OzcGlhIGRlIHN1YSBwdWJsaWNhw6fDo28gcGFyYSBmaW5zIGRlIHNlZ3VyYW7Dp2EsIGJhY2stdXAgZSBwcmVzZXJ2YcOnw6NvLgoKVm9jw6ogZGVjbGFyYSBxdWUgYSBzdWEgcHVibGljYcOnw6NvIMOpIG9yaWdpbmFsIGUgcXVlIHZvY8OqIHRlbSBvIHBvZGVyIGRlIGNvbmNlZGVyIG9zIGRpcmVpdG9zIGNvbnRpZG9zIG5lc3RhIGxpY2Vuw6dhLiBWb2PDqiB0YW1iw6ltIGRlY2xhcmEgcXVlIG8gZGVww7NzaXRvIGRlIHN1YSBwdWJsaWNhw6fDo28gbsOjbywgcXVlIHNlamEgZGUgc2V1IGNvbmhlY2ltZW50bywgaW5mcmluZ2UgZGlyZWl0b3MgYXV0b3JhaXMgZGUgbmluZ3XDqW0uCgpDYXNvIGEgc3VhIHB1YmxpY2HDp8OjbyBjb250ZW5oYSBtYXRlcmlhbCBxdWUgdm9jw6ogbsOjbyBwb3NzdWkgYSB0aXR1bGFyaWRhZGUgZG9zIGRpcmVpdG9zIGF1dG9yYWlzLCB2b2PDqiBkZWNsYXJhIHF1ZSBvYnRldmUgYSBwZXJtaXNzw6NvIGlycmVzdHJpdGEgZG8gZGV0ZW50b3IgZG9zIGRpcmVpdG9zIGF1dG9yYWlzIHBhcmEgY29uY2VkZXIgYW8gUmVwb3NpdMOzcmlvIEluc3RpdHVjaW9uYWwgZGEgVUZNRyBvcyBkaXJlaXRvcyBhcHJlc2VudGFkb3MgbmVzdGEgbGljZW7Dp2EsIGUgcXVlIGVzc2UgbWF0ZXJpYWwgZGUgcHJvcHJpZWRhZGUgZGUgdGVyY2Vpcm9zIGVzdMOhIGNsYXJhbWVudGUgaWRlbnRpZmljYWRvIGUgcmVjb25oZWNpZG8gbm8gdGV4dG8gb3Ugbm8gY29udGXDumRvIGRhIHB1YmxpY2HDp8OjbyBvcmEgZGVwb3NpdGFkYS4KCkNBU08gQSBQVUJMSUNBw4fDg08gT1JBIERFUE9TSVRBREEgVEVOSEEgU0lETyBSRVNVTFRBRE8gREUgVU0gUEFUUk9Dw41OSU8gT1UgQVBPSU8gREUgVU1BIEFHw4pOQ0lBIERFIEZPTUVOVE8gT1UgT1VUUk8gT1JHQU5JU01PLCBWT0PDiiBERUNMQVJBIFFVRSBSRVNQRUlUT1UgVE9ET1MgRSBRVUFJU1FVRVIgRElSRUlUT1MgREUgUkVWSVPDg08gQ09NTyBUQU1Cw4lNIEFTIERFTUFJUyBPQlJJR0HDh8OVRVMgRVhJR0lEQVMgUE9SIENPTlRSQVRPIE9VIEFDT1JETy4KCk8gUmVwb3NpdMOzcmlvIEluc3RpdHVjaW9uYWwgZGEgVUZNRyBzZSBjb21wcm9tZXRlIGEgaWRlbnRpZmljYXIgY2xhcmFtZW50ZSBvIHNldSBub21lKHMpIG91IG8ocykgbm9tZXMocykgZG8ocykgZGV0ZW50b3IoZXMpIGRvcyBkaXJlaXRvcyBhdXRvcmFpcyBkYSBwdWJsaWNhw6fDo28sIGUgbsOjbyBmYXLDoSBxdWFscXVlciBhbHRlcmHDp8OjbywgYWzDqW0gZGFxdWVsYXMgY29uY2VkaWRhcyBwb3IgZXN0YSBsaWNlbsOnYS4K |
| dc.title.none.fl_str_mv |
Xyn-converter used in isolated two-phase three-wire AC power grids |
| title |
Xyn-converter used in isolated two-phase three-wire AC power grids |
| spellingShingle |
Xyn-converter used in isolated two-phase three-wire AC power grids João Henrique de Oliveira Redes elétricas Conversores eletrônicos Confiabilidade (Engenharia) Potência reativa (Engenharia elétrica) Semicondutores Conversor formador de rede Redes isoladas CA Confiabilidade |
| title_short |
Xyn-converter used in isolated two-phase three-wire AC power grids |
| title_full |
Xyn-converter used in isolated two-phase three-wire AC power grids |
| title_fullStr |
Xyn-converter used in isolated two-phase three-wire AC power grids |
| title_full_unstemmed |
Xyn-converter used in isolated two-phase three-wire AC power grids |
| title_sort |
Xyn-converter used in isolated two-phase three-wire AC power grids |
| author |
João Henrique de Oliveira |
| author_facet |
João Henrique de Oliveira |
| author_role |
author |
| dc.contributor.author.fl_str_mv |
João Henrique de Oliveira |
| dc.subject.por.fl_str_mv |
Redes elétricas Conversores eletrônicos Confiabilidade (Engenharia) Potência reativa (Engenharia elétrica) Semicondutores |
| topic |
Redes elétricas Conversores eletrônicos Confiabilidade (Engenharia) Potência reativa (Engenharia elétrica) Semicondutores Conversor formador de rede Redes isoladas CA Confiabilidade |
| dc.subject.other.none.fl_str_mv |
Conversor formador de rede Redes isoladas CA Confiabilidade |
| description |
Isolated electric AC power grids are feasible solutions to energize remote communities, usually based on renewables and energy storage devices, interfaced by power electronics converters that require high reliability. The key element of such a system is the grid-forming converter that provides the voltage magnitude and frequency to other devices, such as loads. Therefore, this dissertation proposes the two-phase three-wire (2Φ3W) xyn-converter applied in a case study of isolated riverside communities in the Brazilian Amazon region. This dissertation compares the current stresses of grid-forming converters (GFC) under an isolated grid mission profile, considering three different grid configurations in terms of the displacement angle between the voltage in the phases: 90◦ (αβn-GFC); 120◦ (abn-GFC) and 180◦ (xyn-GFC). Additionally, analytical expressions for current stress through the semiconductors and the DC-link capacitor are obtained for each converter under balanced and unbalanced load conditions. The lifetime analysis of the grid-forming converter indicates that the xyn-GFC has the lowest wear-out. Furthermore, this work highlights the influence of high-frequency components on the RMS current of the DC-link capacitor. The xyn-GFC demonstrates a lower probability of capacitor failure compared to the other converters, even with higher low-frequency components. A sensitivity analysis shows that the xyn-GFC can increase its output power in 12% or reduce its heatsink volume in 25% to achieve the same wear-out B10 lifetime as the abn-GFC (i.e., benchmark) under nominal conditions. An experiment is conducted using a full-bridge converter and discrete IGBTs to measure the power losses in the semiconductors and the case temperature of the IGBTs. Compared with the αβn-converter, the xyn-converter shows 44% lower power losses, and the abn-converter shows 18% lower power losses. Finally, the thermal stress analysis is validated by means of a 2Φ3W converter prototype with an open semiconductor module. For the evaluated converters, the xyn-GFC has the lowest thermal stress for balanced and unbalanced load conditions and therefore the longest lifetime. Experimental validation shows that the average temperature of the xyn-GFC is 19.4% and 23.3% lower than both the abn-GFC and the αβn-GFC under balanced load conditions. |
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2024 |
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2024-09-09T15:17:31Z 2025-09-09T01:30:51Z |
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2024-09-09T15:17:31Z |
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2024-02-29 |
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info:eu-repo/semantics/doctoralThesis |
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Universidade Federal de Minas Gerais |
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Universidade Federal de Minas Gerais |
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