Renewable Energy-Based Mini-Grid for Rural Electrification: Case Study of an Indian Village

Chapter
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Part of the Green Energy and Technology book series (GREEN)

Abstract

Although off-grid electrification has become a cost-effective and convenient option for many non-electrified areas, generally stand-alone individual options receive greater attention; and when mini-grid-based solutions are considered, traditionally a single technology-based limited level of supply is often considered, without paying attention to reliable round-the-clock supply of electricity. This chapter considers a hybrid combination of renewable energy technologies (RETs) as an alternative to grid extension for remote areas. Applying HOMER software, this study presents an analysis for choosing the best hybrid RET system for an Indian village and compares the result with conventional grid extension. It provides a systematic load demand analysis of the village, simulates optimal sizing of a hybrid system, calculates the economical distance limit (EDL) beyond which the use of the grid extension is not cost-effective and shows that the use of decentralised RET systems at an off-grid location can be a relevant option. HOMER results show that the solution is sustainable and techno-economically viable and environmentally sound.

Keywords

Wind Turbine Hybrid System Load Demand Replacement Cost Renewable Energy Technology 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

Abbreviations

COE

Cost of Energy

Km

Kilometre

EDL

Economical Distance Limit

RET

Renewable Energy Technology

RES

Renewable Energy Sources

GHG

Green House Gases

LCC

Life-Cycle Cost

LUCE

Levelised Unit Cost of Electricity

NPC

Net Present Cost

O&M

Operation and Maintenance

BET

Bioenergy Technology

T&D

Transmission and Distribution

SPV

Solar Photovoltaics

BDG

Biodiesel Generator

SHP

Small Hydropower

B100

100 % Pure Biodiesel

DG

Diesel Generator

MNRE

Ministry of New and Renewable Energy, India

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Copyright information

© Springer International Publishing Switzerland 2014

Authors and Affiliations

  1. 1.TERI—The Energy and Resources InstituteNew DelhiIndia
  2. 2.Institute of Energy and Sustainable Development, De Montfort UniversityLeicesterUK

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