Increase in fault ride through capability of direct drive permanent magnet based wind farm using VSC-HVDC
Burning of fossil fuels and green house gasses causes global warming. This has led to governments to explore the use of green energies instead of fossil fuels. The availability of wind has made wind technology a viable alternative for generating electrical power. Hence, many parts of the world, espe...
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my.uniten.dspace-301242023-12-29T15:44:43Z Increase in fault ride through capability of direct drive permanent magnet based wind farm using VSC-HVDC Maleki H. Ramachandaramurthy V.K. Lak M. 56747561600 6602912020 55414325000 Europe Electric utilities Fossil fuels Global warming Greenhouse gases HVDC power transmission Power converters Wind power Control strategies Direct drive Electrical power Fault ride through capability Green energy Grid code requirements Output voltages Wind technology conference proceeding electrical power global warming greenhouse gas magnetic field renewable resource sustainable development wind farm wind power Electric power transmission networks Burning of fossil fuels and green house gasses causes global warming. This has led to governments to explore the use of green energies instead of fossil fuels. The availability of wind has made wind technology a viable alternative for generating electrical power. Hence, many parts of the world, especially Europe are experiencing a growth in wind farms. However, by increasing the number of wind farms connected to the grid, power quality and voltage stability of grid becomes a matter of concern. In this paper, VSC-HVDC control strategy which enables the wind farm to ride-through faults and regulate voltage for fault types is proposed. The results show that the wind turbine output voltage fulfills the E.ON grid code requirements, when subjected to three phase to ground fault. Hence, continues operation of the wind farm is achieved. � Published under licence by IOP Publishing Ltd. Final 2023-12-29T07:44:43Z 2023-12-29T07:44:43Z 2013 Conference paper 10.1088/1755-1315/16/1/012027 2-s2.0-84881113897 https://www.scopus.com/inward/record.uri?eid=2-s2.0-84881113897&doi=10.1088%2f1755-1315%2f16%2f1%2f012027&partnerID=40&md5=ca114ac853b46c54ae769f2e7aa65fb8 https://irepository.uniten.edu.my/handle/123456789/30124 16 1 12027 All Open Access; Bronze Open Access Institute of Physics Publishing Scopus |
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Europe Electric utilities Fossil fuels Global warming Greenhouse gases HVDC power transmission Power converters Wind power Control strategies Direct drive Electrical power Fault ride through capability Green energy Grid code requirements Output voltages Wind technology conference proceeding electrical power global warming greenhouse gas magnetic field renewable resource sustainable development wind farm wind power Electric power transmission networks |
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Europe Electric utilities Fossil fuels Global warming Greenhouse gases HVDC power transmission Power converters Wind power Control strategies Direct drive Electrical power Fault ride through capability Green energy Grid code requirements Output voltages Wind technology conference proceeding electrical power global warming greenhouse gas magnetic field renewable resource sustainable development wind farm wind power Electric power transmission networks Maleki H. Ramachandaramurthy V.K. Lak M. Increase in fault ride through capability of direct drive permanent magnet based wind farm using VSC-HVDC |
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Burning of fossil fuels and green house gasses causes global warming. This has led to governments to explore the use of green energies instead of fossil fuels. The availability of wind has made wind technology a viable alternative for generating electrical power. Hence, many parts of the world, especially Europe are experiencing a growth in wind farms. However, by increasing the number of wind farms connected to the grid, power quality and voltage stability of grid becomes a matter of concern. In this paper, VSC-HVDC control strategy which enables the wind farm to ride-through faults and regulate voltage for fault types is proposed. The results show that the wind turbine output voltage fulfills the E.ON grid code requirements, when subjected to three phase to ground fault. Hence, continues operation of the wind farm is achieved. � Published under licence by IOP Publishing Ltd. |
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56747561600 |
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56747561600 Maleki H. Ramachandaramurthy V.K. Lak M. |
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Conference paper |
author |
Maleki H. Ramachandaramurthy V.K. Lak M. |
author_sort |
Maleki H. |
title |
Increase in fault ride through capability of direct drive permanent magnet based wind farm using VSC-HVDC |
title_short |
Increase in fault ride through capability of direct drive permanent magnet based wind farm using VSC-HVDC |
title_full |
Increase in fault ride through capability of direct drive permanent magnet based wind farm using VSC-HVDC |
title_fullStr |
Increase in fault ride through capability of direct drive permanent magnet based wind farm using VSC-HVDC |
title_full_unstemmed |
Increase in fault ride through capability of direct drive permanent magnet based wind farm using VSC-HVDC |
title_sort |
increase in fault ride through capability of direct drive permanent magnet based wind farm using vsc-hvdc |
publisher |
Institute of Physics Publishing |
publishDate |
2023 |
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1806428057904349184 |
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13.222552 |