International Journal of Scientific & Technology Research

IJSTR@Facebook IJSTR@Twitter IJSTR@Linkedin
Home About Us Scope Editorial Board Blog/Latest News Contact Us

IJSTR >> Volume 6 - Issue 7, July 2017 Edition

International Journal of Scientific & Technology Research  
International Journal of Scientific & Technology Research

Website: http://www.ijstr.org

ISSN 2277-8616

Future Demand Of Localized Renewable Energy Generation Policy For Zero Carbon Footprints

[Full Text]



Swapnakumari Patil, Dr. Anwar Mubarak Mulla



carbon foot printing, localized generation, energy policy, green energy



The Indian power system is probably going to face extraordinary technical and institutional shifts in the future. Present-day Indian energy policy targets the demand for a clean, economical along with safeguarded energy supply. Decentralization of the electricity system is known as one technique of realizing effective and renewable energy supply and dealing with factors over aging electricity facilities and potential limitations. With this paper, we offer a dialogue about of the economics of elevated use of Localized energy generation. We discover that there is a broad scope for exploration considering the private Localized generation solutions. In this view, we offer strategies for the forthcoming stage of policy development and research which are likely to be necessary to focus on public policy on local generation and its role in the future of Indian energy supply.



[1] Yadav, Gulab Singh, et al. "Energy budgeting for designing sustainable and environmentally clean/safer cropping systems for rainfed rice fallow lands in India." Journal of Cleaner Production 158 (2017): 29-37.

[2] Manju, S., and Netramani Sagar. "Progressing towards the development of sustainable energy: A critical review on the current status, applications, developmental barriers and prospects of solar photovoltaic systems in India." Renewable and Sustainable Energy Reviews 70 (2017): 298-313.

[3] Džamarija, Mario, and Andrew Keane. "Autonomous Curtailment Control in Distributed Generation Planning." IEEE Transactions on Smart Grid 7.3 (2016): 1337-1345.

[4] Ma, Tengfei, Junyong Wu, and Liangliang Hao. "Energy flow modeling and optimal operation analysis of the micro energy grid based on energy hub." Energy Conversion and Management 133 (2017): 292-306.

[5] Berwal, Anil K., et al. "Design and analysis of rooftop grid tied 50kW capacity Solar Photovoltaic (SPV) power plant." Renewable and Sustainable Energy Reviews (2017).

[6] Shrimali, Gireesh, Shreya Pusarla, and Saurabh Trivedi. "Did accelerated depreciation result in lower generation efficiencies for wind plants in India: An empirical analysis." Energy Policy 102 (2017): 154-163.

[7] Saharia, Barnam Jyoti, and Munish Manas. "Viability Analysis of Photovoltaic/Wind Hybrid Distributed Generation in an Isolated Community of Northeastern India." Distributed Generation & Alternative Energy Journal 32.1 (2017): 49-80.

[8] Walls, Margaret, et al. "Is energy efficiency capitalized into home prices? Evidence from three US cities." Journal of Environmental Economics and Management 82 (2017): 104-124.

[9] Barman, Mayur, et al. "Performance and impact evaluation of solar home lighting systems on the rural livelihood in Assam, India." Energy for Sustainable Development 38 (2017): 10-20.

[10] Wang, Linyuan, et al. "Way to accomplish low carbon development transformation: A bibliometric analysis during 1995–2014." Renewable and Sustainable Energy Reviews 68 (2017): 57-69.

[11] E.E. Reber, R.L. Nunan, Fiona, ed. Making climate compatible development happen. Taylor & Francis, 2017.