Design of PV fed single-switch transformer less topology powered electric vehicle

As a result of an increase in the availability of resources that were not harmful to the environment, solar energy applications shot to popularity. Photovoltaic cells power systems that necessitate DC-DC converters because of their low voltage output. This investigation uses photovoltaic cells (PV)...

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Autores:: Vemula, Jeetender
E. Vidya Sagar
Tellapati Anuradha Devi
Gundala Srinivasa Rao
Rekha Rangam
S. Venkata Rami Reddy

Tipo de recurso:: Article of journal

Fecha de publicación:: 2024

Institución:: Universidad Tecnológica de Bolívar

Repositorio:: Repositorio Institucional UTB

Idioma:: eng

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network_acronym_str	UTB2
network_name_str	Repositorio Institucional UTB
repository_id_str
dc.title.spa.fl_str_mv	Design of PV fed single-switch transformer less topology powered electric vehicle
dc.title.translated.spa.fl_str_mv	Design of PV fed single-switch transformer less topology powered electric vehicle
title	Design of PV fed single-switch transformer less topology powered electric vehicle
spellingShingle	Design of PV fed single-switch transformer less topology powered electric vehicle Solar PV Electric Vehicle Brushless DC Motor Single-Switch
title_short	Design of PV fed single-switch transformer less topology powered electric vehicle
title_full	Design of PV fed single-switch transformer less topology powered electric vehicle
title_fullStr	Design of PV fed single-switch transformer less topology powered electric vehicle
title_full_unstemmed	Design of PV fed single-switch transformer less topology powered electric vehicle
title_sort	Design of PV fed single-switch transformer less topology powered electric vehicle
dc.creator.fl_str_mv	Vemula, Jeetender E. Vidya Sagar Tellapati Anuradha Devi Gundala Srinivasa Rao Rekha Rangam S. Venkata Rami Reddy
dc.contributor.author.eng.fl_str_mv	Vemula, Jeetender E. Vidya Sagar Tellapati Anuradha Devi Gundala Srinivasa Rao Rekha Rangam S. Venkata Rami Reddy
dc.subject.eng.fl_str_mv	Solar PV Electric Vehicle Brushless DC Motor Single-Switch
topic	Solar PV Electric Vehicle Brushless DC Motor Single-Switch
description	As a result of an increase in the availability of resources that were not harmful to the environment, solar energy applications shot to popularity. Photovoltaic cells power systems that necessitate DC-DC converters because of their low voltage output. This investigation uses photovoltaic cells (PV) to power a high-voltage gain design with just one switch and no transformer. The proposed circuit utilizes a single regulated switch, which contributes to a reduction in switching losses. It requires fundamental pulse regulation. The network used a switched capacitor cell and an LC passive filter to provide an accurate step-up voltage. We can obtain the equation for the step-up voltage gain from the steady-state continuous conduction mode. The equations used for the theoretical design of converters include energy. To show that the topology is comparable with other modern converters that have been published, a comparison was made between it and other converters. In order to validate the converter's effectiveness, simulations built in MATLAB and Simulink are used.
publishDate	2024
dc.date.accessioned.none.fl_str_mv	2024-12-24 00:00:00
dc.date.available.none.fl_str_mv	2024-12-24 00:00:00
dc.date.issued.none.fl_str_mv	2024-12-24
dc.type.spa.fl_str_mv	Artículo de revista
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dc.type.driver.eng.fl_str_mv	info:eu-repo/semantics/article
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dc.type.local.eng.fl_str_mv	Journal article
dc.type.content.eng.fl_str_mv	Text
dc.type.version.eng.fl_str_mv	info:eu-repo/semantics/publishedVersion
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dc.identifier.url.none.fl_str_mv	https://doi.org/10.32397/tesea.vol5.n2.571
dc.identifier.doi.none.fl_str_mv	10.32397/tesea.vol5.n2.571
dc.identifier.eissn.none.fl_str_mv	2745-0120
url	https://doi.org/10.32397/tesea.vol5.n2.571
identifier_str_mv	10.32397/tesea.vol5.n2.571 2745-0120
dc.language.iso.eng.fl_str_mv	eng
language	eng
dc.relation.references.eng.fl_str_mv	Wuhua Li and Xiangning He. Review of nonisolated high-step-up dc/dc converters in photovoltaic grid-connected applications. IEEE Transactions on Industrial Electronics, 58(4):1239–1250, April 2011. [2] T. Sreekanth, N. Lakshminarasamma, and Mahesh K. Mishra. A single-stage grid-connected high gain buck–boost inverter with maximum power point tracking. IEEE Transactions on Energy Conversion, 32(1):330–339, March 2017. [3] Sandeep Anand, Saikrishna Kashyap Gundlapalli, and B. G. Fernandes. Transformer-less grid feeding current source inverter for solar photovoltaic system. IEEE Transactions on Industrial Electronics, 61(10):5334–5344, October 2014. [4] Rohit Suryadevara and Leila Parsa. Full-bridge zcs-converter-based high-gain modular dc-dc converter for pv integration with medium-voltage dc grids. IEEE Transactions on Energy Conversion, 34(1):302–312, March 2019. [5] Roger Gules, Walter Meneghette Dos Santos, Flavio Aparecido Dos Reis, Eduardo Felix Ribeiro Romaneli, and Alceu Andre Badin. A modified sepic converter with high static gain for renewable applications. IEEE Transactions on Power Electronics, 29(11):5860–5871, November 2014. [6] Neyyala Raju, N. Murali Mohan, and Vijay Kumar. A switched-inductor switched-capacitor based ultra-gain boost converter: analysis and design. TESEA, Transactions on Energy Systems and Engineering Applications, 5(1):1–20, February 2024. [7] Gang Wu, Xinbo Ruan, and Zhihong Ye. Nonisolated high step-up dc–dc converters adopting switched-capacitor cell. IEEE Transactions on Industrial Electronics, 62(1):383–393, January 2015. [8] L Sri Sivani, L Nagi Reddy, BK SubbaRao, and A Pandian. A new single switch ac/dc converter with extended voltage conversion ratio for smps applications. Int. Journal of Innovative Technology and Exploring Engineering, 8(3):68–72, 2019. [9] Farzad Mohammadzadeh Shahir, Ebrahim Babaei, and Murtaza Farsadi. Voltage-lift technique based nonisolated boost dc–dc converter: Analysis and design. IEEE Transactions on Power Electronics, 33(7):5917–5926, July 2018. [10] Qian Li, Yigeng Huangfu, Liangcai Xu, Jiang Wei, Rui Ma, Dongdong Zhao, and Fei Gao. An improved floating interleaved boost converter with the zero-ripple input current for fuel cell applications. IEEE Transactions on Energy Conversion, 34(4):2168–2179, December 2019. [11] M. Lakshmi and S. Hemamalini. Nonisolated high gain dc–dc converter for dc microgrids. IEEE Transactions on Industrial Electronics, 65(2):1205–1212, February 2018. [12] B. Nagi Reddy, K. Badrinath Shetty, Radhika Jalli, K. Akhila, K. Sai Prudhviraj, and Vadthya Jagan. Reduced redundant power processing in dc-dc converters: A comprehensive review. February 2024. [13] J.C. Rosas-Caro, J.M. Ramirez, F.Z. Peng, and A. Valderrabano. A dc–dc multilevel boost converter. IET Power Electronics, 3(1):129, January 2010. [14] Mohammad Reza Banaei, Hossein Ardi, and Amir Farakhor. Analysis and implementation of a new single-switch buck–boost dc/dc converter. IET Power Electronics, 7(7):1906–1914, July 2014. [15] Ping Wang, Lei Zhou, Yun Zhang, Jing Li, and Mark Sumner. Input-parallel output-series dc-dc boost converter with a wide input voltage range, for fuel cell vehicles. IEEE Transactions on Vehicular Technology, 66(9):7771–7781, September 2017. [16] Lukas Muller and Jonathan W. Kimball. High gain dc–dc converter based on the cockcroft–walton multiplier. IEEE Transactions on Power Electronics, 31(9):6405–6415, September 2016. [17] Nagi Reddy B, Sahithi Priya Kosika, Manish Patel Gadam, Jagadhishwar Banoth, Ashok Banoth, and Srikanth Koundinya. Analysis of positive output buck-boost topology with extended conversion ratio. Journal of Energy Systems, 6(1):62–83, March 2022. [18] Kerui Li, Yafei Hu, and Adrian Ioinovici. Generation of the large dc gain step-up nonisolated converters in conjunction with renewable energy sources starting from a proposed geometric structure. IEEE Transactions on Power Electronics, 32(7):5323–5340, July 2017. [19] Faqiang Wang. A novel quadratic boost converter with low current and voltage stress on power switch for fuel-cell system applications. Renewable Energy, 115:836–845, January 2018. [20] Neng Zhang, Guidong Zhang, KhayWai See, and Bo Zhang. A single-switch quadratic buck–boost converter with continuous input port current and continuous output port current. IEEE Transactions on Power Electronics, 33(5):4157–4166, May 2018. [21] Yun Zhang, Heyu Liu, Jing Li, Mark Sumner, and Changliang Xia. Dc–dc boost converter with a wide input range and high voltage gain for fuel cell vehicles. IEEE Transactions on Power Electronics, 34(5):4100–4111, May 2019. [22] Yuanwei Gu, Yanfeng Chen, Bo Zhang, Dongyuan Qiu, and Fan Xie. High step-up dc-dc converter with active switched lc-network for photovoltaic systems. IEEE Transactions on Energy Conversion, 34(1):321–329, 2018. [23] Marcos Antonio Salvador, Telles Brunelli Lazzarin, and Roberto Francisco Coelho. High step-up dc–dc converter with active switched-inductor and passive switched-capacitor networks. IEEE Transactions on Industrial Electronics, 65(7):5644–5654, July 2018. [24] Ebrahim Babaei, Hamed Mashinchi Maheri, Mehran Sabahi, and Seyed Hossein Hosseini. Extendable nonisolated high gain dc–dc converter based on active–passive inductor cells. IEEE Transactions on Industrial Electronics, 65(12):9478–9487, December 2018. [25] B. Nagi Reddy, G. Vinay Kumar, B. Vinay Kumar, B. Jhansi, B. Sandeep, and K. Sarada. Fuel cell based ultra-voltage gain boost converter for electric vehicle applications. TESEA, Transactions on Energy Systems and Engineering Applications, 4(1):68–90, June 2023. [26] Mohammad Maalandish, Seyed Hossein Hosseini, Tohid Jalilzadeh, and Naser Vosoughi. High step-up dc–dc converter using one switch and lower losses for photovoltaic applications. IET Power Electronics, 11(13):2081–2092, September 2018. [27] Farzad Mohammadzadeh Shahir, Ebrahim Babaei, and Murtaza Farsadi. Extended topology for a boost dc–dc converter. IEEE Transactions on Power Electronics, 34(3):2375–2384, March 2019.
dc.relation.ispartofjournal.eng.fl_str_mv	Transactions on Energy Systems and Engineering Applications
dc.relation.citationvolume.eng.fl_str_mv	5
dc.relation.citationstartpage.none.fl_str_mv	1
dc.relation.citationendpage.none.fl_str_mv	23
dc.relation.bitstream.none.fl_str_mv	https://revistas.utb.edu.co/tesea/article/download/571/401
dc.relation.citationedition.eng.fl_str_mv	Núm. 2 , Año 2024 : Transactions on Energy Systems and Engineering Applications
dc.relation.citationissue.eng.fl_str_mv	2
dc.rights.uri.eng.fl_str_mv	https://creativecommons.org/licenses/by/4.0
dc.rights.accessrights.eng.fl_str_mv	info:eu-repo/semantics/openAccess
dc.rights.creativecommons.eng.fl_str_mv	This work is licensed under a Creative Commons Attribution 4.0 International License.
dc.rights.coar.eng.fl_str_mv	http://purl.org/coar/access_right/c_abf2
rights_invalid_str_mv	https://creativecommons.org/licenses/by/4.0 This work is licensed under a Creative Commons Attribution 4.0 International License. http://purl.org/coar/access_right/c_abf2
eu_rights_str_mv	openAccess
dc.format.mimetype.eng.fl_str_mv	application/pdf
dc.publisher.eng.fl_str_mv	Universidad Tecnológica de Bolívar
dc.source.eng.fl_str_mv	https://revistas.utb.edu.co/tesea/article/view/571
institution	Universidad Tecnológica de Bolívar
repository.name.fl_str_mv	Repositorio Digital Universidad Tecnológica de Bolívar
repository.mail.fl_str_mv	bdigital@metabiblioteca.com
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spelling	Vemula, JeetenderE. Vidya SagarTellapati Anuradha DeviGundala Srinivasa RaoRekha RangamS. Venkata Rami Reddy2024-12-24 00:00:002024-12-24 00:00:002024-12-24As a result of an increase in the availability of resources that were not harmful to the environment, solar energy applications shot to popularity. Photovoltaic cells power systems that necessitate DC-DC converters because of their low voltage output. This investigation uses photovoltaic cells (PV) to power a high-voltage gain design with just one switch and no transformer. The proposed circuit utilizes a single regulated switch, which contributes to a reduction in switching losses. It requires fundamental pulse regulation. The network used a switched capacitor cell and an LC passive filter to provide an accurate step-up voltage. We can obtain the equation for the step-up voltage gain from the steady-state continuous conduction mode. The equations used for the theoretical design of converters include energy. To show that the topology is comparable with other modern converters that have been published, a comparison was made between it and other converters. In order to validate the converter's effectiveness, simulations built in MATLAB and Simulink are used.application/pdfengUniversidad Tecnológica de BolívarJeetender Vemula, E. Vidya Sagar, Tellapati Anuradha Devi, Gundala Srinivasa Rao, Rekha Rangam, S. Venkata Rami Reddy - 2024https://creativecommons.org/licenses/by/4.0info:eu-repo/semantics/openAccessThis work is licensed under a Creative Commons Attribution 4.0 International License.http://purl.org/coar/access_right/c_abf2https://revistas.utb.edu.co/tesea/article/view/571Solar PVElectric VehicleBrushless DC MotorSingle-SwitchDesign of PV fed single-switch transformer less topology powered electric vehicleDesign of PV fed single-switch transformer less topology powered electric vehicleArtículo de revistainfo:eu-repo/semantics/articlehttp://purl.org/coar/resource_type/c_6501http://purl.org/coar/resource_type/c_2df8fbb1Journal articleTextinfo:eu-repo/semantics/publishedVersionhttp://purl.org/coar/version/c_970fb48d4fbd8a85https://doi.org/10.32397/tesea.vol5.n2.57110.32397/tesea.vol5.n2.5712745-0120Wuhua Li and Xiangning He. Review of nonisolated high-step-up dc/dc converters in photovoltaic grid-connected applications. IEEE Transactions on Industrial Electronics, 58(4):1239–1250, April 2011. [2] T. Sreekanth, N. Lakshminarasamma, and Mahesh K. Mishra. A single-stage grid-connected high gain buck–boost inverter with maximum power point tracking. IEEE Transactions on Energy Conversion, 32(1):330–339, March 2017. [3] Sandeep Anand, Saikrishna Kashyap Gundlapalli, and B. G. Fernandes. Transformer-less grid feeding current source inverter for solar photovoltaic system. IEEE Transactions on Industrial Electronics, 61(10):5334–5344, October 2014. [4] Rohit Suryadevara and Leila Parsa. Full-bridge zcs-converter-based high-gain modular dc-dc converter for pv integration with medium-voltage dc grids. IEEE Transactions on Energy Conversion, 34(1):302–312, March 2019. [5] Roger Gules, Walter Meneghette Dos Santos, Flavio Aparecido Dos Reis, Eduardo Felix Ribeiro Romaneli, and Alceu Andre Badin. A modified sepic converter with high static gain for renewable applications. IEEE Transactions on Power Electronics, 29(11):5860–5871, November 2014. [6] Neyyala Raju, N. Murali Mohan, and Vijay Kumar. A switched-inductor switched-capacitor based ultra-gain boost converter: analysis and design. TESEA, Transactions on Energy Systems and Engineering Applications, 5(1):1–20, February 2024. [7] Gang Wu, Xinbo Ruan, and Zhihong Ye. Nonisolated high step-up dc–dc converters adopting switched-capacitor cell. IEEE Transactions on Industrial Electronics, 62(1):383–393, January 2015. [8] L Sri Sivani, L Nagi Reddy, BK SubbaRao, and A Pandian. A new single switch ac/dc converter with extended voltage conversion ratio for smps applications. Int. Journal of Innovative Technology and Exploring Engineering, 8(3):68–72, 2019. [9] Farzad Mohammadzadeh Shahir, Ebrahim Babaei, and Murtaza Farsadi. Voltage-lift technique based nonisolated boost dc–dc converter: Analysis and design. IEEE Transactions on Power Electronics, 33(7):5917–5926, July 2018. [10] Qian Li, Yigeng Huangfu, Liangcai Xu, Jiang Wei, Rui Ma, Dongdong Zhao, and Fei Gao. An improved floating interleaved boost converter with the zero-ripple input current for fuel cell applications. IEEE Transactions on Energy Conversion, 34(4):2168–2179, December 2019. [11] M. Lakshmi and S. Hemamalini. Nonisolated high gain dc–dc converter for dc microgrids. IEEE Transactions on Industrial Electronics, 65(2):1205–1212, February 2018. [12] B. Nagi Reddy, K. Badrinath Shetty, Radhika Jalli, K. Akhila, K. Sai Prudhviraj, and Vadthya Jagan. Reduced redundant power processing in dc-dc converters: A comprehensive review. February 2024. [13] J.C. Rosas-Caro, J.M. Ramirez, F.Z. Peng, and A. Valderrabano. A dc–dc multilevel boost converter. IET Power Electronics, 3(1):129, January 2010. [14] Mohammad Reza Banaei, Hossein Ardi, and Amir Farakhor. Analysis and implementation of a new single-switch buck–boost dc/dc converter. IET Power Electronics, 7(7):1906–1914, July 2014. [15] Ping Wang, Lei Zhou, Yun Zhang, Jing Li, and Mark Sumner. Input-parallel output-series dc-dc boost converter with a wide input voltage range, for fuel cell vehicles. IEEE Transactions on Vehicular Technology, 66(9):7771–7781, September 2017. [16] Lukas Muller and Jonathan W. Kimball. High gain dc–dc converter based on the cockcroft–walton multiplier. IEEE Transactions on Power Electronics, 31(9):6405–6415, September 2016. [17] Nagi Reddy B, Sahithi Priya Kosika, Manish Patel Gadam, Jagadhishwar Banoth, Ashok Banoth, and Srikanth Koundinya. Analysis of positive output buck-boost topology with extended conversion ratio. Journal of Energy Systems, 6(1):62–83, March 2022. [18] Kerui Li, Yafei Hu, and Adrian Ioinovici. Generation of the large dc gain step-up nonisolated converters in conjunction with renewable energy sources starting from a proposed geometric structure. IEEE Transactions on Power Electronics, 32(7):5323–5340, July 2017. [19] Faqiang Wang. A novel quadratic boost converter with low current and voltage stress on power switch for fuel-cell system applications. Renewable Energy, 115:836–845, January 2018. [20] Neng Zhang, Guidong Zhang, KhayWai See, and Bo Zhang. A single-switch quadratic buck–boost converter with continuous input port current and continuous output port current. IEEE Transactions on Power Electronics, 33(5):4157–4166, May 2018. [21] Yun Zhang, Heyu Liu, Jing Li, Mark Sumner, and Changliang Xia. Dc–dc boost converter with a wide input range and high voltage gain for fuel cell vehicles. IEEE Transactions on Power Electronics, 34(5):4100–4111, May 2019. [22] Yuanwei Gu, Yanfeng Chen, Bo Zhang, Dongyuan Qiu, and Fan Xie. High step-up dc-dc converter with active switched lc-network for photovoltaic systems. IEEE Transactions on Energy Conversion, 34(1):321–329, 2018. [23] Marcos Antonio Salvador, Telles Brunelli Lazzarin, and Roberto Francisco Coelho. High step-up dc–dc converter with active switched-inductor and passive switched-capacitor networks. IEEE Transactions on Industrial Electronics, 65(7):5644–5654, July 2018. [24] Ebrahim Babaei, Hamed Mashinchi Maheri, Mehran Sabahi, and Seyed Hossein Hosseini. Extendable nonisolated high gain dc–dc converter based on active–passive inductor cells. IEEE Transactions on Industrial Electronics, 65(12):9478–9487, December 2018. [25] B. Nagi Reddy, G. Vinay Kumar, B. Vinay Kumar, B. Jhansi, B. Sandeep, and K. Sarada. Fuel cell based ultra-voltage gain boost converter for electric vehicle applications. TESEA, Transactions on Energy Systems and Engineering Applications, 4(1):68–90, June 2023. [26] Mohammad Maalandish, Seyed Hossein Hosseini, Tohid Jalilzadeh, and Naser Vosoughi. High step-up dc–dc converter using one switch and lower losses for photovoltaic applications. IET Power Electronics, 11(13):2081–2092, September 2018. [27] Farzad Mohammadzadeh Shahir, Ebrahim Babaei, and Murtaza Farsadi. Extended topology for a boost dc–dc converter. IEEE Transactions on Power Electronics, 34(3):2375–2384, March 2019.Transactions on Energy Systems and Engineering Applications5123https://revistas.utb.edu.co/tesea/article/download/571/401Núm. 2 , Año 2024 : Transactions on Energy Systems and Engineering Applications220.500.12585/13531oai:repositorio.utb.edu.co:20.500.12585/135312025-09-16 09:15:12.881https://creativecommons.org/licenses/by/4.0Jeetender Vemula, E. Vidya Sagar, Tellapati Anuradha Devi, Gundala Srinivasa Rao, Rekha Rangam, S. Venkata Rami Reddy - 2024metadata.onlyhttps://repositorio.utb.edu.coRepositorio Digital Universidad Tecnológica de Bolívarbdigital@metabiblioteca.com

Design of PV fed single-switch transformer less topology powered electric vehicle

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