Gabriel E. Mejía-Ruiz scite author profile

ABSTRACT:This paper proposes a model of the bridgeless PFC (Power Factor Correction) boost rectifier for control purposes based on an averaged small-signal analysis. From circuital laws, four operation modes are defined and explained, ensuring a relationship of physical variables in the converter. Based on the proposed model, two-loop cascade control structures composed of Proportional-Integral (PI) lineal controllers are proposed. Design consideration for dimensioning reactive elements is included, providing minimum values for their inductance and capacitance. Implementation of a laboratory prototype of 900 W and experimental results are presented to validate and reaffirm the proposed model. Experimental results demonstrate that the use of the bridgeless PFC boost converter model allows the Power Factor (PF) to be elevated up to 0.99, to reduce the THD i (Total Harmonic Distortion of the Current) to 3.9% and to control the DC voltage level on output. Compliance of standards of power quality EN 61000-3-2 (IEC 1000-3-2) are experimentally verified.

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Modeling, analysis and design procedure of LCL filter for grid connected converters

Mejía-Ruiz

Muñoz

Cano

2015

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This paper presents the mathematical deduction of models for LCL filters with and without the damping resistor, the criteria for designing LCL filter, a systematic procedure for designing LCL filter and experimental tests with an isolated load. Experimental tests demonstrate the relevance of propose procedure for the design of LCL filter. Usually, power inverter is the interface between renewable energy sources such as wind, solar and hydrogen fuel cells, and utility grid. However, high frequency PWM modulation generated in power inverter causes harmonic injection to the utility grid and reduces quality of the injected energy. LCL filter can reduce harmonic injection to the utility grid. Inappropriate design of LCL filter can cause excessive voltage attenuation at the output of the power inverter, resonances and oscillations that can increase total harmonic distortion, instability in power system and slow dynamic response.

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Coordinated Optimal Volt/Var Control for Distribution Networks via D-PMUs and EV Chargers by Exploiting the Eigensystem Realization

Mejía-Ruiz

Cárdenas-Javier

Paternina

et al. 2021

IEEE Trans. Smart Grid

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Design methodologies and programmable devices used in power electronic converters — A survey

Mejía-Ruiz

Muñoz

Cano

2015

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A Sliding Surface for Controlling a Semi-Bridgeless Boost Converter with Power Factor Correction and Adaptive Hysteresis Band

et al. 2021

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This paper proposes a new sliding surface for controlling a Semi-Bridgeless Boost Converter (SBBC) which simultaneously performs Power Factor Correction (PFC) and DC bus regulation. The proposed sliding surface is composed of three terms: First, a normalized DC voltage error term controls the DC bus and rejects DC voltage disturbances. In this case, the normalization was performed for increasing system robustness during start-up and large disturbances. Second, an AC current error term implements a PFC scheme and guarantees fast current stabilization during disturbances. Third, an integral of the AC current error term increases stability of the overall system. In addition, an Adaptive Hysteresis Band (AHB) is implemented for keeping the switching frequency constant and reducing the distortion in zero crossings. Previous papers usually include the first and/or the second terms of the proposed sliding surface, and none consider the AHB. To be best of the author’s knowledge, the proposed Sliding Mode Control (SMC) is the first control strategy for SBBCs that does not require a cascade PI or a hybrid PI-Sliding Mode Control (PI-SMC) for simultaneously controlling AC voltage and DC current, which gives the best dynamic behavior removing DC overvoltages and responding fast to DC voltage changes or DC load current perturbations. Several simulations were carried out to compare the performance of the proposed surface with a cascade PI control, a hybrid PI-SMC and the proposed SMC. Furthermore, a stability analysis of the proposed surface in start-up and under large perturbations was performed. Experimental results for PI-SMC and SMC implemented in a SBBC prototype are also presented.

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