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Dhinesh, G.
- Offshore Wind to Meet Increasing Energy Demands in India
Abstract Views :225 |
PDF Views:90
Authors
Satya Kiran Raju Alluri
1,
Trishanu Shit
1,
G. Dhinesh
1,
Devender Gujjula
1,
S. V. S. Phani Kumar
1,
M. V. Ramana Murthy
1
Affiliations
1 National Institute of Ocean Technology, Chennai 600 100, IN
1 National Institute of Ocean Technology, Chennai 600 100, IN
Source
Current Science, Vol 113, No 04 (2017), Pagination: 774-781Abstract
Offshore wind provides a scalable alternative to conventional energy resources. It can be a potential source to meet the increasing energy demand in developing countries like India, for which an attractive policy framework is required. The aim of this study is to provide an insight for evolving onshore wind policy in India and suggest suitable strategies for development of offshore wind sector. Various wind resource maps were reviewed and potential sites identified as Rameswaram and Kanyakumari along Tamil Nadu coast. Suitability analysis was conducted to identify the type of wind turbine recommended at potential sites to achieve high plant load factor, considering the uncertainty in wind speeds. Commercial viability studies were carried out to identify appropriate incentives for development of offshore wind sector in India. Results indicate a levelized cost of energy of Rs 10.8 and Rs 9.6/Kwh at Rameswaram and Kanyakumari for an internal rate of return of 14%.Keywords
Commercial Viability, Offshore Wind Energy, Wind Potential Assessment.References
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Abstract Views :178 |
PDF Views:84
Authors
Satya Kiran Raju Alluri
1,
Devender Gujjula
1,
G. Dhinesh
1,
S. V. S. Phani Kumar
1,
M. V. Ramana Murthy
1
Affiliations
1 National Institute of Ocean Technology, Ministry of Earth Sciences, Chennai 600 100, IN
1 National Institute of Ocean Technology, Ministry of Earth Sciences, Chennai 600 100, IN
Source
Current Science, Vol 118, No 11 (2020), Pagination: 1774-1777Abstract
Offshore wind energy is gaining significance around the world as the most suitable source of renewable energy. India, blessed with 7500 km of coastline has already announced the offshore wind energy policy based on feasibility studies for offshore wind potential. National Institute of Wind Energy (NIWE) and M/s Suzlon Energy Limited have installed first LiDAR-based offshore measurement platform with the technical expertise of the National Institute of Ocean Technology (NIOT), MoES in the Gulf of Khambhat and the Gulf of Kachchh. This article illustrates the analysis, design methodology and various innovative strategies involved in the installation of LiDAR-based measurement platforms.Keywords
Challenges, Installation, LiDAR Platform, Offshore Wind Energy.References
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- Gujjula, D., Alluri, S. K. R., Dhinesh, D., Panneer Selvam, R. and Ramana Murthy, M. V., Developing the installation methodology for monopile of offshore wind turbine in high tidal environment along Indian coast. In International Conference on Ocean Engineering, February 2018.
- Alluri, S. K. R., Gujjula, D., Krishnaveni, B., Ganapathi, D., Phanikumar, S. V. S., Ramana Murthy, M. V. and Atmanand, M. A., Offshore Wind Feasibility Studies in India, Stability Control and Reliable Performance of Wind Turbines, Intech Open, 2019.