Your search keyword '"direct current-link output voltage"' showing total 3 results

1. Closed-loop control of a single-stage switched-boost inverter in modified DC-interconnected nanogrids

Author

Nourhan Ahmed Maged, Essamudin A. Ebrahim, Naser Abdel-Rahim, and Fahmy Bendary

Subjects

invertors, maximum power point trackers, distributed power generation, photovoltaic power systems, power generation control, closed loop systems, power grids, voltage control, energy management systems, electric current control, robust control, power system interconnection, single-stage switched-boost inverter, modified dc-interconnected nanogrids, sbi, single-stage power converter, solar photovoltaic arrays, expensive complex dead-time circuitry, direct current-link output voltage, dc-link output voltage, normal ac-voltage, off-grid power applications, modified nanogrid, simple closed-loop control technique, transformer-less rated ac-output voltage, stable ac-output voltage, time maximum power point operation, robust controller, voltage stability, pv-maximum power achievement, low-discharging control strategy, bidirectional buck–boost converter, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Switched-boost inverter (SBI) is a single-stage power converter suitable for interfacing between photovoltaic (PV) arrays and loads. Although, it has many advantages such as it's not requiring an expensive complex dead-time circuitry, yet its duty ratio is limited between 0 and 0.5. This means that it has some difficulties in increasing both the DC-link output voltage and its AC-output voltage. So, most researchers proposed it for low-voltage power applications or using with step-up transformers. Accordingly, this study contributes towards improving the performance of the SBI for being used in the modified nanogrid within an open energy system. It introduces a novel approach closed-loop control technique to overcome most of the inverter drawbacks. Also, it enhances both the DC-link and the transformer-less rated AC output voltages to a sufficient value suitable for feeding domestic loads. And in the same time, the proposed robust controller utilizes a hysteresis band for balancing between voltage stability and PV-maximum power achievement. This research also includes a more sophisticated fast-charging slow-discharging control strategy for the battery energy management system that depends on a bidirectional buck-boost converter. Test results ensure the robustness of the proposed controller against sensitivity, nonlinearity, and time-variant parameters of the overall system.

Published

2020

2. Closed-loop control of a single-stage switched-boost inverter in modified DC-interconnected nanogrids.

Author

Maged, Nourhan Ahmed, Ebrahim, Essamudin A., Abdel-Rahim, Naser, and Bendary, Fahmy

Subjects

CLOSED loop systems, ELECTRIC inverters, PHOTOVOLTAIC power generation, ELECTRIC potential, ELECTRICAL load

Abstract

Switched-boost inverter (SBI) is a single-stage power converter suitable for interfacing between photovoltaic (PV) arrays and loads. Although, it has many advantages such as it's not requiring an expensive complex dead-time circuitry, yet its duty ratio is limited between 0 and 0.5. This means that it has some difficulties in increasing both the DC-link output voltage and its AC-output voltage. So, most researchers proposed it for low-voltage power applications or using with step-up transformers. Accordingly, this study contributes towards improving the performance of the SBI for being used in the modified nanogrid within an open energy system. It introduces a novel approach closed-loop control technique to overcome most of the inverter drawbacks. Also, it enhances both the DC-link and the transformer-less rated AC output voltages to a sufficient value suitable for feeding domestic loads. And in the same time, the proposed robust controller utilizes a hysteresis band for balancing between voltage stability and PV-maximum power achievement. This research also includes a more sophisticated fast-charging slow-discharging control strategy for the battery energy management system that depends on a bidirectional buck-boost converter. Test results ensure the robustness of the proposed controller against sensitivity, nonlinearity, and time-variant parameters of the overall system. [ABSTRACT FROM AUTHOR]

Published

2020

3. Closed-loop control of a single-stage switched-boost inverter in modified DC-interconnected nanogrids

Author

Fahmy Bendary, Nourhan Ahmed Maged, N. Abdel-Rahim, and Essamudin A. Ebrahim

Subjects

Computer science, expensive complex dead-time circuitry, 02 engineering and technology, invertors, direct current-link output voltage, pv-maximum power achievement, law.invention, low-discharging control strategy, law, bidirectional buck–boost converter, 0202 electrical engineering, electronic engineering, information engineering, Transformer, robust controller, simple closed-loop control technique, Photovoltaic system, General Engineering, dc-link output voltage, stable ac-output voltage, time maximum power point operation, Robust control, power generation control, 020209 energy, Energy Engineering and Power Technology, power system interconnection, solar photovoltaic arrays, off-grid power applications, distributed power generation, Control theory, energy management systems, photovoltaic power systems, single-stage power converter, 020208 electrical & electronic engineering, voltage control, maximum power point trackers, power grids, normal ac-voltage, modified nanogrid, Nonlinear system, single-stage switched-boost inverter, Interfacing, Duty cycle, sbi, transformer-less rated ac-output voltage, voltage stability, lcsh:TA1-2040, Inverter, lcsh:Engineering (General). Civil engineering (General), Software, electric current control, robust control, modified dc-interconnected nanogrids, Voltage, closed loop systems

Abstract

Switched-boost inverter (SBI) is a single-stage power converter suitable for interfacing between photovoltaic (PV) arrays and loads. Although, it has many advantages such as it's not requiring an expensive complex dead-time circuitry, yet its duty ratio is limited between 0 and 0.5. This means that it has some difficulties in increasing both the DC-link output voltage and its AC-output voltage. So, most researchers proposed it for low-voltage power applications or using with step-up transformers. Accordingly, this study contributes towards improving the performance of the SBI for being used in the modified nanogrid within an open energy system. It introduces a novel approach closed-loop control technique to overcome most of the inverter drawbacks. Also, it enhances both the DC-link and the transformer-less rated AC output voltages to a sufficient value suitable for feeding domestic loads. And in the same time, the proposed robust controller utilizes a hysteresis band for balancing between voltage stability and PV-maximum power achievement. This research also includes a more sophisticated fast-charging slow-discharging control strategy for the battery energy management system that depends on a bidirectional buck-boost converter. Test results ensure the robustness of the proposed controller against sensitivity, nonlinearity, and time-variant parameters of the overall system.

Published

2020