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Comprehensive Analysis and Evaluation of DC-DC Converters: Advancements, Applications, and Challenges

Year 2023, Volume: 6 Issue: 4, 557 - 571, 15.10.2023
https://doi.org/10.34248/bsengineering.1357849

Abstract

Power electronics stand as the cornerstone of our electrified world, and versatile DC-DC converters are a key component of this technology. In this comprehensive analysis, we investigate deeply the realm of DC-DC converters, examining their pivotal role in modern power systems. From the evolution of converter topologies to their wide-ranging applications, we explore the advancements that propel this field forward. Whether maintaining continuous power in portable devices or facilitating renewable energy integration, DC-DC converters are the fundamental components. Yet, they face formidable challenges, from complex control strategies to voltage stress management. This study reveals the complex configuration of DC-DC converters, detailing a narrative of adaptability, resilience, and innovation in response to the increasing energy demands of our time.

References

  • Alhurayyis I, Elkhateb A, Morrow J. 2020. Isolated and nonisolated dc-to-dc converters for medium-voltage dc networks: a review. IEEE J Emerg Sel, 9(6): 7486-500.
  • Al-Obaidi NA, Abbas RA, Khazaal HF. 2022. A review of non-isolated bidirectional dc-dc converters for hybrid energy storage system. In: 5th International Conference On Engineering Technology And Its Applications (IICETA), 31 May - 1 June, Al-Najaf, Iraq, pp: 248-253.
  • Bakas P, Harnefors L, Norrga S,Nami A, Ilves K, Dijkhuizen F, Nee HP. 2016. A review of hybrid topologies combining line-commutated and cascaded full-bridge converters. IEEE J Emerg Sel, 32(10): 7435-48.
  • Basso C. 2008. Switch-mode power supplies: spice simulations and practical designs. McGraw-Hill, New York, USA, 2th ed., pp: 321.
  • Chen J, MaksimoviC D, Erickson R. 2001. Buck-boost pwm converters having two independently controlled switches. In: IEEE 32nd Annual Power Electronics Specialists Conference (IEEE Cat. No. 01CH37230), 17-21 June, Vancouver, BC, Canada, pp: 736-741.
  • Chen, W, Lee FC, Jovanovic MM, Sabate JA. 1995. A comparative study of a class of full bridge zero-voltage-switched pwm converters. In: Proceedings of 1995 IEEE Applied Power Electronics Conference and Exposition-APEC'95, 5-9 March, Dallas, TX, USA, pp: 893-899.
  • Chen W, Xu P, Lee FC. 2001. The optimization of asymmetric half bridge converter. In: Sixteenth Annual IEEE Applied Power Electronics Conference and Exposition (Cat. No. 01CH37181), 4-8 March, Anaheim, CA, USA, pp: 703-707.
  • Davari P, Zare F, Ghosh A, Akiyama H. 2012. High-voltage modular power supply using parallel and series configurations of flyback converter for pulsed power applications. IEEE Trans Plasma Sci IEEE Nucl Plasma Sci Soc, 40(10): 2578-87.
  • Erickson R, Madigan M, Singer S. 1990. Design of a simple high-power-factor rectifier based on the flyback converter. In: Fifth Annual Proceedings on Applied Power Electronics Conference and Exposition, 11-16 March, Los Angeles, CA, USA, pp: 792-801.
  • Erickson R, Dragan M. 2007. Fundamentals of power electronics. Springer science & business media, London, UK, 2th ed., pp: 253.
  • Forouzesh M, Siwakoti YP, Gorji SA, Blaabjerg F, Lehman B. 2017. Step-up dc–dc converters: a comprehensive review of voltage-boosting techniques, topologies, and applications. IEEE Trans. Power Electron, 32(12): 9143-78.
  • Gorji SA, Mostaan A, My HT, Ektesabi M. 2019. Non‐isolated buck–boost dc–dc converter with quadratic voltage gain ratio. IET Power Electron, 12(6): 1425-33.
  • Hossain MZ, Rahim NA. 2018. Recent progress and development on power dc-dc converter topology, control, design and applications: a review. Renew. Sust Energ Rev, 81:205-30.
  • İnci M, Büyük M, Demir MH, İlbey G. 2021. A review and research on fuel cell electric vehicles: topologies, power electronic converters, energy management methods, technical challenges, marketing and future aspects. Renew Sust Energ Rev, 137: 110648.
  • Ivanovic Z, Knezic M. 2022. Modeling push–pull converter for efficiency improvement. J Electron, 11(17): 2713.
  • Kazimierczuk MK. 2015. Pulse-width modulated dc-dc power converters: John Wiley & Sons, London, UK, pp: 143.
  • Khaligh A, Onar OC. 2017. Energy harvesting: solar, wind, and ocean energy conversion systems, CRC press, London, UK, pp: 218.
  • Kim EH, Kwon BH. 2009. High step-up resonant push–pull converter with high efficiency. IET Power Electron, 2(1): 79-89.
  • Kim YH, Soo CS, Lee JH, Yong CJ, Chung YW. 2013. Soft-switching current-fed push–pull converter for 250-w ac module applications. IEEE Trans Power Electron, 29(2): 863-872.
  • Krishnan R. 2017. Switched reluctance motor drives: modeling, simulation, analysis, design, and applications: CRC press, London, UK, pp: 142.
  • Kundu U, Yenduri K, Sensarma P. 2016. Accurate zvs analysis for magnetic design and efficiency improvement of full-bridge llc resonant converter. IEEE Trans Power Electron, 32(3): 1703-1706.
  • Li Z, Ruopei Z, Yazhou L, Yan H, Jinming H, Xiaoling Z, Xiao-Ping Z. 2018. Recent developments in HVDC transmission systems to support renewable energy integration. Glob Energy Interconnect, 1(5): 595-607.
  • Lipo TA. 2017. Introduction to ac machine design. John Wiley & Sons, London, UK, pp: 154.
  • Luo FL, Ye H. 2016. Advanced Dc/Dc converters. CRC press, London, UK, pp: 125.
  • Mohan N, Undeland TM, Robbins WP. 2003. Power electronics: converters, applications, and design: John Wiley & Sons, London, UK, pp: 121.
  • Mumtaz F, Yahaya NZ, Meraj ST, Singh B, Kannan R, Ibrahim O. 2021. Review on non-isolated dc-dc converters and their control techniques for renewable energy applications. Ain Shams Eng J, 12(4): 3747-3763.
  • Nouri T, Nouri N, Vosoughi N. 2019. A novel high step-up high efficiency interleaved dc–dc converter with coupled inductor and built-in transformer for renewable energy systems. IEEE Trans Power Electron, 67(8): 6505-6516.
  • Park J, Kim M, Choi S. 2014. Zero‐current switching series loaded resonant converter insensitive to resonant component tolerance for battery charger. IET Power Electron, 7(10): 2517-2524.
  • Pressman A. 2009. Switching power supply design. McGraw-Hill Education, London, UK, pp: 102.
  • Raghavendra KVG, Zeb K, Muthusamy A, Krishna TNV, Kumar SVSVP, Kim DH, Kim MS, Cho HG, Kim HJ. 2019. A comprehensive review of dc–dc converter topologies and modulation strategies with recent advances in solar photovoltaic systems. J Electron, 9(1): 31.
  • Rashid MH. 2010. Power electronics circuits devices and application. Pearson, London, UK, pp: 101.
  • Rashid MH. 2017. Power electronics handbook. Butterworth-heinemann, London, UK, pp: 124.
  • Revathi BS, Prabhakar M. 2016. Non isolated high gain dc-dc converter topologies for pv applications–a comprehensive review. Renew Sust Energ Rev, 66: 920-933.
  • Saeedifard M, Graovac M, Dias RF, Iravani R. 2010. Dc power systems: challenges and opportunities. In: IEEE PES general meeting: IEEE, 25-29 July, Minneapolis, MN, USA, pp: 1-7
  • Skvarenina T. L. 2018. The power electronics handbook. CRC press, London, UK, pp: 97.
  • Steigerwald RL. 1988. A comparison of half-bridge resonant converter topologies. IEEE Trans. Power Electron, 3(2): 174-182.
  • Tan FD. 2002. The forward converter: from the classic to the contemporary. In: APEC. Seventeenth Annual IEEE Applied Power Electronics Conference and Exposition (Cat. No. 02CH37335), 10-14 March, Dallas, TX, USA, pp: 857-863.
  • Tseng KC, Huang CC. 2013. High step-up high-efficiency interleaved converter with voltage multiplier module for renewable energy system. IEEE Trans Ind Electron, 61(3): 1311-1319.
  • Wang K, Lee FC, Lai J. 2000. Operation principles of bi-directional full-bridge dc/dc converter with unified soft-switching scheme and soft-starting capability. In: Fifteenth Annual IEEE Applied Power Electronics Conference and Exposition (Cat. No. 00CH37058), 6-10 Feb, New Orleans, LA, USA, pp: 111-118
  • Wei Y, Luo Q, Mantooth A. 2020. Overview of modulation strategies for llc resonant converter. IEEE Trans. Power Electron, 35(10): 10423-10443.
  • Wu G, Ruan X, Ye Z. 2014. Nonisolated high step-up dc–dc converters adopting switched-capacitor cell. IEEE Trans. Ind Electron, 62(1): 383-393.
  • Yang B, Lee FC, Zhang AJ, Huang G. 2002. Llc resonant converter for front end dc/dc conversion. In: Seventeenth Annual IEEE Applied Power Electronics Conference and Exposition (Cat. No. 02CH37335), 10-14 March, Dallas, TX, pp: 1108-1112.
  • Zeng J, Zhang G, Yu SS, Zhang B, Zhang Y. 2020. LLC resonant converter topologies and industrial applications—a review. Chin J Electr Eng, 6(3): 73-84.
  • Zhang MT, Jovanovic MM, Lee FCY. 1998. Analysis and evaluation of interleaving techniques in forward converters. IEEE Trans Power Electron, 13(4): 690-698.

Comprehensive Analysis and Evaluation of DC-DC Converters: Advancements, Applications, and Challenges

Year 2023, Volume: 6 Issue: 4, 557 - 571, 15.10.2023
https://doi.org/10.34248/bsengineering.1357849

Abstract

Power electronics stand as the cornerstone of our electrified world, and versatile DC-DC converters are a key component of this technology. In this comprehensive analysis, we investigate deeply the realm of DC-DC converters, examining their pivotal role in modern power systems. From the evolution of converter topologies to their wide-ranging applications, we explore the advancements that propel this field forward. Whether maintaining continuous power in portable devices or facilitating renewable energy integration, DC-DC converters are the fundamental components. Yet, they face formidable challenges, from complex control strategies to voltage stress management. This study reveals the complex configuration of DC-DC converters, detailing a narrative of adaptability, resilience, and innovation in response to the increasing energy demands of our time.

References

  • Alhurayyis I, Elkhateb A, Morrow J. 2020. Isolated and nonisolated dc-to-dc converters for medium-voltage dc networks: a review. IEEE J Emerg Sel, 9(6): 7486-500.
  • Al-Obaidi NA, Abbas RA, Khazaal HF. 2022. A review of non-isolated bidirectional dc-dc converters for hybrid energy storage system. In: 5th International Conference On Engineering Technology And Its Applications (IICETA), 31 May - 1 June, Al-Najaf, Iraq, pp: 248-253.
  • Bakas P, Harnefors L, Norrga S,Nami A, Ilves K, Dijkhuizen F, Nee HP. 2016. A review of hybrid topologies combining line-commutated and cascaded full-bridge converters. IEEE J Emerg Sel, 32(10): 7435-48.
  • Basso C. 2008. Switch-mode power supplies: spice simulations and practical designs. McGraw-Hill, New York, USA, 2th ed., pp: 321.
  • Chen J, MaksimoviC D, Erickson R. 2001. Buck-boost pwm converters having two independently controlled switches. In: IEEE 32nd Annual Power Electronics Specialists Conference (IEEE Cat. No. 01CH37230), 17-21 June, Vancouver, BC, Canada, pp: 736-741.
  • Chen, W, Lee FC, Jovanovic MM, Sabate JA. 1995. A comparative study of a class of full bridge zero-voltage-switched pwm converters. In: Proceedings of 1995 IEEE Applied Power Electronics Conference and Exposition-APEC'95, 5-9 March, Dallas, TX, USA, pp: 893-899.
  • Chen W, Xu P, Lee FC. 2001. The optimization of asymmetric half bridge converter. In: Sixteenth Annual IEEE Applied Power Electronics Conference and Exposition (Cat. No. 01CH37181), 4-8 March, Anaheim, CA, USA, pp: 703-707.
  • Davari P, Zare F, Ghosh A, Akiyama H. 2012. High-voltage modular power supply using parallel and series configurations of flyback converter for pulsed power applications. IEEE Trans Plasma Sci IEEE Nucl Plasma Sci Soc, 40(10): 2578-87.
  • Erickson R, Madigan M, Singer S. 1990. Design of a simple high-power-factor rectifier based on the flyback converter. In: Fifth Annual Proceedings on Applied Power Electronics Conference and Exposition, 11-16 March, Los Angeles, CA, USA, pp: 792-801.
  • Erickson R, Dragan M. 2007. Fundamentals of power electronics. Springer science & business media, London, UK, 2th ed., pp: 253.
  • Forouzesh M, Siwakoti YP, Gorji SA, Blaabjerg F, Lehman B. 2017. Step-up dc–dc converters: a comprehensive review of voltage-boosting techniques, topologies, and applications. IEEE Trans. Power Electron, 32(12): 9143-78.
  • Gorji SA, Mostaan A, My HT, Ektesabi M. 2019. Non‐isolated buck–boost dc–dc converter with quadratic voltage gain ratio. IET Power Electron, 12(6): 1425-33.
  • Hossain MZ, Rahim NA. 2018. Recent progress and development on power dc-dc converter topology, control, design and applications: a review. Renew. Sust Energ Rev, 81:205-30.
  • İnci M, Büyük M, Demir MH, İlbey G. 2021. A review and research on fuel cell electric vehicles: topologies, power electronic converters, energy management methods, technical challenges, marketing and future aspects. Renew Sust Energ Rev, 137: 110648.
  • Ivanovic Z, Knezic M. 2022. Modeling push–pull converter for efficiency improvement. J Electron, 11(17): 2713.
  • Kazimierczuk MK. 2015. Pulse-width modulated dc-dc power converters: John Wiley & Sons, London, UK, pp: 143.
  • Khaligh A, Onar OC. 2017. Energy harvesting: solar, wind, and ocean energy conversion systems, CRC press, London, UK, pp: 218.
  • Kim EH, Kwon BH. 2009. High step-up resonant push–pull converter with high efficiency. IET Power Electron, 2(1): 79-89.
  • Kim YH, Soo CS, Lee JH, Yong CJ, Chung YW. 2013. Soft-switching current-fed push–pull converter for 250-w ac module applications. IEEE Trans Power Electron, 29(2): 863-872.
  • Krishnan R. 2017. Switched reluctance motor drives: modeling, simulation, analysis, design, and applications: CRC press, London, UK, pp: 142.
  • Kundu U, Yenduri K, Sensarma P. 2016. Accurate zvs analysis for magnetic design and efficiency improvement of full-bridge llc resonant converter. IEEE Trans Power Electron, 32(3): 1703-1706.
  • Li Z, Ruopei Z, Yazhou L, Yan H, Jinming H, Xiaoling Z, Xiao-Ping Z. 2018. Recent developments in HVDC transmission systems to support renewable energy integration. Glob Energy Interconnect, 1(5): 595-607.
  • Lipo TA. 2017. Introduction to ac machine design. John Wiley & Sons, London, UK, pp: 154.
  • Luo FL, Ye H. 2016. Advanced Dc/Dc converters. CRC press, London, UK, pp: 125.
  • Mohan N, Undeland TM, Robbins WP. 2003. Power electronics: converters, applications, and design: John Wiley & Sons, London, UK, pp: 121.
  • Mumtaz F, Yahaya NZ, Meraj ST, Singh B, Kannan R, Ibrahim O. 2021. Review on non-isolated dc-dc converters and their control techniques for renewable energy applications. Ain Shams Eng J, 12(4): 3747-3763.
  • Nouri T, Nouri N, Vosoughi N. 2019. A novel high step-up high efficiency interleaved dc–dc converter with coupled inductor and built-in transformer for renewable energy systems. IEEE Trans Power Electron, 67(8): 6505-6516.
  • Park J, Kim M, Choi S. 2014. Zero‐current switching series loaded resonant converter insensitive to resonant component tolerance for battery charger. IET Power Electron, 7(10): 2517-2524.
  • Pressman A. 2009. Switching power supply design. McGraw-Hill Education, London, UK, pp: 102.
  • Raghavendra KVG, Zeb K, Muthusamy A, Krishna TNV, Kumar SVSVP, Kim DH, Kim MS, Cho HG, Kim HJ. 2019. A comprehensive review of dc–dc converter topologies and modulation strategies with recent advances in solar photovoltaic systems. J Electron, 9(1): 31.
  • Rashid MH. 2010. Power electronics circuits devices and application. Pearson, London, UK, pp: 101.
  • Rashid MH. 2017. Power electronics handbook. Butterworth-heinemann, London, UK, pp: 124.
  • Revathi BS, Prabhakar M. 2016. Non isolated high gain dc-dc converter topologies for pv applications–a comprehensive review. Renew Sust Energ Rev, 66: 920-933.
  • Saeedifard M, Graovac M, Dias RF, Iravani R. 2010. Dc power systems: challenges and opportunities. In: IEEE PES general meeting: IEEE, 25-29 July, Minneapolis, MN, USA, pp: 1-7
  • Skvarenina T. L. 2018. The power electronics handbook. CRC press, London, UK, pp: 97.
  • Steigerwald RL. 1988. A comparison of half-bridge resonant converter topologies. IEEE Trans. Power Electron, 3(2): 174-182.
  • Tan FD. 2002. The forward converter: from the classic to the contemporary. In: APEC. Seventeenth Annual IEEE Applied Power Electronics Conference and Exposition (Cat. No. 02CH37335), 10-14 March, Dallas, TX, USA, pp: 857-863.
  • Tseng KC, Huang CC. 2013. High step-up high-efficiency interleaved converter with voltage multiplier module for renewable energy system. IEEE Trans Ind Electron, 61(3): 1311-1319.
  • Wang K, Lee FC, Lai J. 2000. Operation principles of bi-directional full-bridge dc/dc converter with unified soft-switching scheme and soft-starting capability. In: Fifteenth Annual IEEE Applied Power Electronics Conference and Exposition (Cat. No. 00CH37058), 6-10 Feb, New Orleans, LA, USA, pp: 111-118
  • Wei Y, Luo Q, Mantooth A. 2020. Overview of modulation strategies for llc resonant converter. IEEE Trans. Power Electron, 35(10): 10423-10443.
  • Wu G, Ruan X, Ye Z. 2014. Nonisolated high step-up dc–dc converters adopting switched-capacitor cell. IEEE Trans. Ind Electron, 62(1): 383-393.
  • Yang B, Lee FC, Zhang AJ, Huang G. 2002. Llc resonant converter for front end dc/dc conversion. In: Seventeenth Annual IEEE Applied Power Electronics Conference and Exposition (Cat. No. 02CH37335), 10-14 March, Dallas, TX, pp: 1108-1112.
  • Zeng J, Zhang G, Yu SS, Zhang B, Zhang Y. 2020. LLC resonant converter topologies and industrial applications—a review. Chin J Electr Eng, 6(3): 73-84.
  • Zhang MT, Jovanovic MM, Lee FCY. 1998. Analysis and evaluation of interleaving techniques in forward converters. IEEE Trans Power Electron, 13(4): 690-698.
There are 44 citations in total.

Details

Primary Language English
Subjects Electrical Circuits and Systems, Electrical Machines and Drives
Journal Section Research Articles
Authors

Fuad Alhaj Omar 0000-0001-5969-2513

Early Pub Date October 4, 2023
Publication Date October 15, 2023
Submission Date September 9, 2023
Acceptance Date September 29, 2023
Published in Issue Year 2023 Volume: 6 Issue: 4

Cite

APA Alhaj Omar, F. (2023). Comprehensive Analysis and Evaluation of DC-DC Converters: Advancements, Applications, and Challenges. Black Sea Journal of Engineering and Science, 6(4), 557-571. https://doi.org/10.34248/bsengineering.1357849
AMA Alhaj Omar F. Comprehensive Analysis and Evaluation of DC-DC Converters: Advancements, Applications, and Challenges. BSJ Eng. Sci. October 2023;6(4):557-571. doi:10.34248/bsengineering.1357849
Chicago Alhaj Omar, Fuad. “Comprehensive Analysis and Evaluation of DC-DC Converters: Advancements, Applications, and Challenges”. Black Sea Journal of Engineering and Science 6, no. 4 (October 2023): 557-71. https://doi.org/10.34248/bsengineering.1357849.
EndNote Alhaj Omar F (October 1, 2023) Comprehensive Analysis and Evaluation of DC-DC Converters: Advancements, Applications, and Challenges. Black Sea Journal of Engineering and Science 6 4 557–571.
IEEE F. Alhaj Omar, “Comprehensive Analysis and Evaluation of DC-DC Converters: Advancements, Applications, and Challenges”, BSJ Eng. Sci., vol. 6, no. 4, pp. 557–571, 2023, doi: 10.34248/bsengineering.1357849.
ISNAD Alhaj Omar, Fuad. “Comprehensive Analysis and Evaluation of DC-DC Converters: Advancements, Applications, and Challenges”. Black Sea Journal of Engineering and Science 6/4 (October 2023), 557-571. https://doi.org/10.34248/bsengineering.1357849.
JAMA Alhaj Omar F. Comprehensive Analysis and Evaluation of DC-DC Converters: Advancements, Applications, and Challenges. BSJ Eng. Sci. 2023;6:557–571.
MLA Alhaj Omar, Fuad. “Comprehensive Analysis and Evaluation of DC-DC Converters: Advancements, Applications, and Challenges”. Black Sea Journal of Engineering and Science, vol. 6, no. 4, 2023, pp. 557-71, doi:10.34248/bsengineering.1357849.
Vancouver Alhaj Omar F. Comprehensive Analysis and Evaluation of DC-DC Converters: Advancements, Applications, and Challenges. BSJ Eng. Sci. 2023;6(4):557-71.

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