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The increasing integration of large solar PV and wind farms into the power grid has fueled, over the past two decades, growing demands for high-power, high-voltage, utility-scale inverters. Multilevel inverters have emerged as the industry’s choice for megawatt-range inverters because of their reduced voltage stress, capability for generating an almost-sinusoidal voltage, built-in redundancy and other benefits. This paper presents a novel switched-source multilevel inverter (SS MLI) architecture. This new inverter shows superior capabilities when compared to existing topologies. It has reduced voltage stress on the semiconductor, uses fewer switches (i.e., reduced size/weight/cost) and exhibits increased efficiency. The proposed SS MLI is comprised of two voltage sources ( V1,V2 ) and six switches. It is capable of generating five-level output voltage in symmetric mode (i.e., V1=V2 ) and seven-level output voltage in asymmetric mode (i.e., V1≠V2 ). We present simulations results (using MATLAB®/Simulink®) for five- and seven-level output voltages, and they strongly support the validity of the proposed inverter. These positive results are further supported experimentally using a laboratory prototype.
Kennedy Adinbo Aganah; Cristopher Luciano; Mandoye Ndoye; Gregory Murphy. New Switched-Dual-Source Multilevel Inverter for Symmetrical and Asymmetrical Operation. Energies 2018, 11, 984 .
AMA StyleKennedy Adinbo Aganah, Cristopher Luciano, Mandoye Ndoye, Gregory Murphy. New Switched-Dual-Source Multilevel Inverter for Symmetrical and Asymmetrical Operation. Energies. 2018; 11 (4):984.
Chicago/Turabian StyleKennedy Adinbo Aganah; Cristopher Luciano; Mandoye Ndoye; Gregory Murphy. 2018. "New Switched-Dual-Source Multilevel Inverter for Symmetrical and Asymmetrical Operation." Energies 11, no. 4: 984.
The efficiency of a power system is reduced when voltage drops and losses occur along the distribution lines. While the voltage profile across the system buses can be improved by the injection of reactive power, increased line flows and line losses could result due to uncontrolled injections. Also, the determination of global optimal settings for all power-system components in large power grids is difficult to achieve. This paper presents a novel approach to the application of game theory as a method for the distributed control of reactive power and voltage in a power grid. The concept of non-cooperative, extensive = form games is used to model the interaction among power-system components that have the capacity to control reactive power flows in the system. A centralized method of control is formulated using an IEEE 6-bus test system, which is further translated to a method for distributed control using the New England 39-bus system. The determination of optimal generator settings leads to an improvement in load-voltage compliance. Finally, renewable-energy (reactive power) sources are integrated to further improve the voltage-compliance level.
Ikponmwosa Idehen; Shiny Abraham; Gregory V. Murphy. A Method for Distributed Control of Reactive Power and Voltage in a Power Grid: A Game-Theoretic Approach. Energies 2018, 11, 962 .
AMA StyleIkponmwosa Idehen, Shiny Abraham, Gregory V. Murphy. A Method for Distributed Control of Reactive Power and Voltage in a Power Grid: A Game-Theoretic Approach. Energies. 2018; 11 (4):962.
Chicago/Turabian StyleIkponmwosa Idehen; Shiny Abraham; Gregory V. Murphy. 2018. "A Method for Distributed Control of Reactive Power and Voltage in a Power Grid: A Game-Theoretic Approach." Energies 11, no. 4: 962.