Design and implementation of a current controlled grid connected inverter for thermoelectric generator sources

被引:0
作者
B Bijukumar
G Saravana Ilango
C Nagamani
机构
[1] National Institute of Technology,Department of Electrical and Electronics Engineering
来源
Sādhanā | 2020年 / 45卷
关键词
Current control; grid connected system; thermoelectric generator (TEG); vector control; voltage source inverter (VSI);
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摘要
This paper presents the digital implementation of a current controlled grid connected inverter for Thermoelectric Generator (TEG) sources. Considering the electrical characteristics of a TEG source, several important aspects that a designer has to consider in selecting the rating of power converters for the grid connected operation of TEG source are discussed. The closed loop control of a TEG fed grid connected voltage source inverter (VSI) requires line current control to regulate the power pumped into the grid. Considering the inverter, current sensor and line inductor models, a simplified method is espoused to determine the parameters of the digital current controller. An Altera Cyclone II FPGA board is used to implement the current control strategy in VSI fed with TEG power source. The proposed design approach is validated using simulations and experiments and verified with the time domain specifications.
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[1]  
Risseh AE(2018)Electrical power conditioning system for thermoelectric waste heat recovery in commercial vehicles IEEE Trans. Transport. Electrif. 4 548-562
[2]  
Nee HP(2009)Thermoelectric exhaust heat recovery for hybrid vehicles SAE Int. J. Engines. 2 1132-1142
[3]  
Goupil C(2007)Conversion efficiency of thermoelectric combustion systems IEEE Trans. Energy Conversion 22 528-534
[4]  
Hussain QE(2015)Current-sensorless power estimation and MPPT implementation for thermoelectric generators IEEE Trans. on Industrial Electronics 62 5539-5548
[5]  
Brigham DR(2015)Maximum power point tracking converter based on the open-circuit voltage method for thermoelectric generators IEEE Trans. Power Electronics 30 828-839
[6]  
Maranville CW(2014)Boost converter with dynamic input impedance matching for energy harvesting with multi-array thermoelectric generators IEEE Trans. Ind. Electronics 61 5345-5353
[7]  
Min G(2013)DC–DC boost converter with variation-tolerant MPPT technique and efficient ZCS circuit for thermoelectric energy harvesting applications IEEE Trans. Power Electronics 28 3827-3833
[8]  
Rowe DM(2014)The effect of temperature mismatch on thermoelectric generators electrically connected in series and parallel Applied Energy 123 47-54
[9]  
Bond M(2018)Evaluation on High-efficiency Thermoelectric Generation Systems Based on Differential Power Processing IEEE Trans. Industrial Electronics 65 699-708
[10]  
Park J(1998)Fast current controller in three-phase AC/DC boost converter using d-q axis IEEE Trans. Power Electronics. 13 179-183
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