Journal of Scientific and Industrial Research

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Control Strategy for LVRT Enhancement in Photovoltaic Fuel Cell Hybrid Renewable Energy System


Affiliations
1 National Institute of Electronics and Information Technology, Delhi, India
2 Ajay Kumar Garg Engineering College, Ghaziabad, Uttar Pradesh, India
3 Marathwada Mitra Mandal's Institute of Technology, Pune, India
4 Galgotias University, Greater Noida, Uttar Pradesh, India
5 Government Polytechnic Bighapur Unnao, Department of Technical Education, Uttar Pradesh, India
6 UIET, CSJM University, Kanpur, Uttar Pradesh, India

The present work describes a Low voltage ride through (LVRT) method for optimizing a photovoltaic fuel cell hybrid renewable energy system (HRES). The LVRT control approaches were previously studied to apply them to systems such as Wind Power Generation (WPG) and Solar Energy Generation (SEG), among other things. Photovoltaic (PV) power generation systems have recently drawn significant interest, with the building of large PV systems or groupings of systems related to the utility grid gaining a lot of traction. As a result of the significant penetration of photovoltaic electricity into the system, energy regulatory bodies enact increasingly strict grid rules to preserve grid stability. This paper demonstrates a large-scale grid-connected solar system along with the associated modeling and control approaches that can be utilized to improve DC-based voltage levels which can ride-through capabilities of solar power plants. The grid side inverter is essential for low-voltage driving. In case of overvoltage or under voltage the grid may trip inverter's DC link thereby such variation should be avoided as much as feasible. The purpose of this research is to incorporate DC-link over and under-voltage protection into the control loop without raising the cost of the protective device, which is a significant consideration. In the future, a study of the outcomes using a typical inverter system is also planned. Numerous fault scenarios with increasing severity are analyzed to show that the comprehensive control system is effective. The most recent grid code for the distributed generation system is considered.

Keywords

DC-link, Dynamic voltage recovery, Energy generation, Energy storage system, Grid stability
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  • Control Strategy for LVRT Enhancement in Photovoltaic Fuel Cell Hybrid Renewable Energy System

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Authors

Devvrat Tyagi
National Institute of Electronics and Information Technology, Delhi, India
Ayushi Prakash
Ajay Kumar Garg Engineering College, Ghaziabad, Uttar Pradesh, India
Amita Pal
Marathwada Mitra Mandal's Institute of Technology, Pune, India
Sonu Kumar Jha
Galgotias University, Greater Noida, Uttar Pradesh, India
Vikash Yadav
Government Polytechnic Bighapur Unnao, Department of Technical Education, Uttar Pradesh, India
Mayur Rahul
UIET, CSJM University, Kanpur, Uttar Pradesh, India

Abstract


The present work describes a Low voltage ride through (LVRT) method for optimizing a photovoltaic fuel cell hybrid renewable energy system (HRES). The LVRT control approaches were previously studied to apply them to systems such as Wind Power Generation (WPG) and Solar Energy Generation (SEG), among other things. Photovoltaic (PV) power generation systems have recently drawn significant interest, with the building of large PV systems or groupings of systems related to the utility grid gaining a lot of traction. As a result of the significant penetration of photovoltaic electricity into the system, energy regulatory bodies enact increasingly strict grid rules to preserve grid stability. This paper demonstrates a large-scale grid-connected solar system along with the associated modeling and control approaches that can be utilized to improve DC-based voltage levels which can ride-through capabilities of solar power plants. The grid side inverter is essential for low-voltage driving. In case of overvoltage or under voltage the grid may trip inverter's DC link thereby such variation should be avoided as much as feasible. The purpose of this research is to incorporate DC-link over and under-voltage protection into the control loop without raising the cost of the protective device, which is a significant consideration. In the future, a study of the outcomes using a typical inverter system is also planned. Numerous fault scenarios with increasing severity are analyzed to show that the comprehensive control system is effective. The most recent grid code for the distributed generation system is considered.

Keywords


DC-link, Dynamic voltage recovery, Energy generation, Energy storage system, Grid stability