Modeling, Simulation and Development of Grid-Connected Voltage Source Converter with Selective Harmonic Mitigation: HiL and Experimental Validations

• Main Authors: Amorndechaphon, D. (Author), Kaewchum, T. (Author), Kamnarn, U. (Author), Phattanasak, M. (Author), Rakwichian, W. (Author), Somkun, S. (Author), Srita, S. (Author), Thongpron, J. (Author), Zacharias, P. (Author)
• Format: Article
• Language: English
• Published: MDPI 2022
• Subjects: C (programming language); Continuous time systems; Controllers; Costs; discrete-time control; Discrete-time control; Electric inverters; Grid-connected; Grid-connected inverte; grid-connected inverter; Harmonic analysis; Harmonic orders; harmonics; MATLAB; Model development; modeling; Modeling; Modeling simulation; Resonance; Resonant controller; Simulation platform; Time domain analysis; Two term control systems; Voltage source; voltage source converter; Voltage source converter
• Online Access: View Fulltext in Publisher

 This paper elaborates on a development technique for the grid-connected voltage source converter (VSC). We propose a simulation technique in the MATLAB/Simulink environment that emulates the operation of the discrete-time controlled grid-connected VSC. The switched-circuit modeling approach is used for simulation of the power stage in the continuous-time domain with the physical unit scale. The discrete-time control algorithm is implemented in an interpreted MATLAB function in the per-unit scale, which synchronizes with the switching period. Such a control algorithm is easily translated into the C language for programing of the 32-bit C2000 DSP controller with the same regulators’ parameters. The proposed platform was validated with a hardware-in-the-loop real-time simulator and with a 5-kVA 3-phase LCL-filtered grid-connected VSC. The discrete-time control scheme was implemented in the synchronous reference frame control with proportional-integral with multi-resonant controllers at harmonic orders 6th and 12th for suppression of the grid voltage harmonic orders 5th, 7th, 11th, and 13th. The experimental results closely agreed with the simulation results. The experimental grid currents complied with the IEEE 1547 standard thanks to the multi-resonant controllers. The proposed platform provides a smooth transition from implementation to a near-commercial prototype with a low investment cost in simulation and rapid prototyping tools. A MATLAB/Simulink VSC model is provided as an attachment of this paper. © 2022 by the authors. Licensee MDPI, Basel, Switzerland.