An integrated bayes soft switching interleaved and sliding window PWM for DC-DC boost converter
-
2018-07-04 https://doi.org/10.14419/ijet.v7i3.6.14982 -
Pulse width modulation (PWM), bayes interleaved, sliding window, photovoltaic panels, maximum power point tracking and Dc-Dc boost converter. -
Abstract
In order to develop the efficient dc-dc boost converter in high output power application, an Integrated Bayes Interleaved and Sliding Window (IBI-SW) based PWM framework is proposed. Initially, the integration of interleaving and PWM improves the power factor correction in very high output power applications (photovoltaic panels) and near optimal voltage and current losses. Multiple phase shifts with soft switched Bayes interleaving technique maximizes the power generated in photovoltaic panels and the optimization of power conversion is achieved with sliding window based PWM that performs Maximum Power Point Tracking (MPPT) algorithm on the PV cells connected to the converter. The proposed dc-dc boost converter is efficiently tested on various load conditions for measuring the scalability of IBI-SW framework in multiple high power demanded application. When compared with traditional model, the simulation result of proposed IBI-SW based PWM framework demonstrates that the dc-dc converter improves the power generated in photovoltaic panels accurately and rapidly.
Â
Â
-
References
[1] Chen YC, Hsu JD, Ang YA & Yang TY, “A new phase shedding scheme for improved transient behavior of interleaved Boost PFC convertersâ€, Twenty-Ninth Annual IEEE Applied Power Electronics Conference and Exposition (APEC), (2014), pp. 1916-1919.
[2] Zhang S, Garner R, Zhang Y & Bakre S, “Quantification Analysis of Input / Output Current of Interleaved Power Factor Correction (PFC) Boost Converterâ€, IEEE Applied Power Electronics Conference and Exposition, (2014), pp.1902-1908.
[3] Gopi A & Saravanakumar R, “High step-up isolated efficient single switch DC-DC converter for renewable energy sourceâ€, Ain Shams Engineering Journal, Vol.5, No.4, (2014), pp.1115–1127.
[4] Shiva Kumar S, Panda AK & Ramesh T, “A ZVT–ZCT PWM synchronous buck converter with a simple passive auxiliary circuit for reduction of losses and efficiency enhancementâ€, Ain Shams Engineering Journal, Vol.6, No.2,(2015), pp.491–500.
[5] Mohammadpour A, Parsa L, Todorovic MH, Lai R, Datta R & Garces L, “Series-input parallel-output modular-phase dc–dc converter with soft-switching and high-frequency isolationâ€, IEEE Transactions on Power Electronics, Vol.31, No.1,(2016), pp.111-119.
[6] Hu Y, Wu J, Cao W, Xiao W, Li P, Finney SJ & Li Y, “Ultrahigh step-up DC–DC converter for distributed generation by three degrees of freedom (3DoF) approachâ€, IEEE Transactions on Power Electronics, Vol.31, No.7,(2016), pp.4930-4941.
[7] Yuvaraju M & Sheela Sobana Rani K, “Maximum Power Point Tracking For Photovoltaic Optimization Using Seeker Algorithmâ€, International Journal of Advanced Engineering Research and Science (IJAERS), Vol.1, No.2, (2014), pp.6-9.
[8] Kong TH, Hong SW & Cho GH, “A 0.791 mm On-Chip Self-Aligned Comparator Controller for Boost DC-DC Converter Using Switching Noise Robust Charge-Pumpâ€, IEEE Journal of Solid-State Circuits, Vol.49, No.2,(2014), pp.502-512.
[9] Lu Y, Xing Y & Wu H, “A PWM plus phase-shift controlled interleaved isolated boost converter based on semiactive quadrupler rectifier for high step-up applicationsâ€, IEEE Transactions on Industrial Electronics, Vol.63, No.7,(2016), pp.4211-4221.
[10] Shi Y & Yang X, “Wide Range Soft Switching PWM Three-Level DC-DC Converters Suitable for Industrial Applicationsâ€, IEEE Transactions on Power Electronics, Vol.29, No.2,(2013), pp. 603 – 616.
[11] Das P, Pahlevaninezhad M & Singh AK, “A Novel Load Adaptive ZVS Auxiliary Circuit for PWM Three-Level DC-DC Convertersâ€, IEEE Transactions on Power Electronics, Vol.30, No.4,(2014), pp. 2108–2126.
[12] Kim W, Duong VH, Nguyen TT & Choi W, “Analysis of the effects of inverter ripple current on a photovoltaic power system by using an AC impedance model of the solar cellâ€, Renewable Energy, Vol.59, (2013), pp.150–157.
[13] Matsumura K & Koizumi H, “Interleaved Soft-Switching Multilevel Boost Converterâ€, 39th Annual Conference of the IEEE Industrial Electronics Society, IECON, (2013), pp.936-941.
[14] Hwu KI, Tu WC &Wang CR., “Photovoltaic Energy Conversion System Constructed by High Step-Up Converter with Hybrid Maximum Power Point Trackingâ€, International Journal of Photo energy, (2013), pp.1-10.
[15] Natarajan S & Natarajan R, “An FPGA Chaos-Based PWM Technique Combined with Simple Passive Filter for Effective EMI Spectral Peak Reduction in DC-DC Converterâ€, Advances in Power Electronics, (2014), pp.1-12.
[16] Panda AK, Pattnaik S & Mohapatra KK, “A Novel Soft-Switching Synchronous Buck Converter for Portable Applicationsâ€, International Journal of Power Management Electronics, (2008), pp. 1-10.
[17] Dudrik J & Oetter J, “High-Frequency Soft-Switching DC-DC Converters for Voltage and Current DC Power Sourcesâ€, Acta Polytechnica Hungarica, Vol.4, No.2, (2016), pp.29-46.
[18] Mahor A & Sharma P, “Modelling of New PWM Based Soft Switching for DC/DC Converters Incorporated with PID Controllerâ€, International Journal of Electrical, Electronics and Computer Engineering, Vol.1, No.1,(2012), pp.66-68.
[19] Pattnaik S, Panda AK & Mahapatra KK., “A Novel Improved Soft Switching PWM DC-DC Converterâ€, Annual IEEE India Conference, (2008), pp. 92–97.
[20] Nigam S, Baul P, Sharma SK, Elangovan D & Saravanakumar R, “Soft Switched Low Stress High Efficient ZVT PWM Dc-Dc Converter for Renewable Energy Applicationsâ€, International Conference on Energy Efficient Technologies for Sustainability (ICEETS), (2013), pp.1189–1194.
-
Downloads
-
How to Cite
Puviarasi, R., & Dhanasekaran, D. (2018). An integrated bayes soft switching interleaved and sliding window PWM for DC-DC boost converter. International Journal of Engineering & Technology, 7(3.6), 249-254. https://doi.org/10.14419/ijet.v7i3.6.14982Received date: 2018-07-02
Accepted date: 2018-07-02
Published date: 2018-07-04