Coupled Inductor and Voltage Doubler Circuit for High Step-Up DC-DC Converter

Main Article Content

Abhinav V. Deshpande
https://orcid.org/0000-0002-6114-1830

Abstract

This research paper proposes a novel high step-up dc-dc converter comprising a cascaded assembly of a coupled inductor as well as voltage doubler circuits. A high step-up voltage gain with an appropriate duty ratio as well as low voltage stress on the power switches is achieved by this converter. The output consists of the recycled energy which is stored in the leakage inductor of the coupled inductor. A discussion containing the details of the operating principles as well as steady state analysis of the proposed converter is also included. The performance of the proposed converter is verified in the laboratory by implementing a prototype circuit of the converter that is being proposed finally.

Keywords:
Step up voltage gain, coupled inductor, voltage doubler, DC-DC converter, inverter, buck-boost converter, dc motor, Voltage Regulator Modules (VRM’s)

Article Details

How to Cite
Deshpande, A. V. (2021). Coupled Inductor and Voltage Doubler Circuit for High Step-Up DC-DC Converter. Asian Research Journal of Current Science, 3(1), 109-118. Retrieved from https://globalpresshub.com/index.php/ARJOCS/article/view/1212
Section
Original Research Article

References

Yang LS, Liang TJ, Lee HC, Chen JF. Novel high step-up DC–DC converter with coupled-inductor and voltage-doubler circuits. IEEE Transactions on industrial Electronics. 2010 Dec 10;58(9):4196-206.

Sang-Wha Seo, Joon-Hyoung Ryu, Yong Kim; Han Ho Choi. Non-Isolated High step-up DC/DC converter with coupled inductor and switched capacitor. IEEE Access. December 2020; 8:217108 – 217122.

Yu-En Wu, Jyun-Wei Wang. Novel high-efficiency high step-up DC–DC converter with soft switching and low component voltage stress for photovoltaic system. MDPI-Processes. June 2021;9(1112):01-14.

Yu-En Wu, Jyun-Wei Wang. Novel high-efficiency high step-up DC–DC converter with soft switching and low component voltage stress for photovoltaic system. June 2021;9(1112):01-14.

Martí Cervià Caballé, Anna Calveras Augé, Elena Lopez-Aguilera, Eduard Garcia-Villegas; Ilker Demirko. An alternative to IEEE 802.11ba: Wake-Up Radio with Legacy IEEE 802.11 transmitters. IEEE Access. April 2019; 7:48068 – 48086.

Mumina Uddin, Shareeful Islam, Ameer Al-Nemrat. A dynamic access control model using authorising workflow and task-role-based access control. IEEE Access. October 2019; 7:166676 – 166689.

Yuan Yao, Yujiao Hu, Gang Yang, Xingshe Zhou. On MAC access delay Distribution for IEEE 802.11p broadcast in vehicular networks. IEEE Access. October 2019;7: 149052 – 149067.

Kentaro Kobayashi, Hiraku Okada, Masaaki Katayama. Guaranteed time slot allocation for IEEE 802.15.4-Based wireless feedback control systems. IEEE Access. November 2019; 7:161211 – 161219.

Rukaiya Rukaiya, Muhammad Umar Farooq, Shoab A. Khan, Farhan Hussain, Adnan Akhunzad. CFFD-MAC: A hybrid MAC for collision free full-duplex communication in wireless ad-hoc networks. February 2021; 7:35584 – 35598.

Sohaib Manzoor; Yachao Yin, Yayu Gao; Xiaojun Hei, Wenqing Cheng. A systematic study of IEEE 802.11 DCF Network Optimization from Theory to Testbed. IEEE Access. 8:154114 – 154132.

Dianhan Xie, Jiawei Zhang, Aimin Tang, Xudong Wang. Multi-dimensional busy-tone arbitration for OFDMA Random Access in IEEE 802.11ax”, IEEE Access. March 2020;4080 – 4094.