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Details of Grant 

EPSRC Reference: EP/R030294/1
Title: TERSE: Techno-Economic framework for Resilient and Sustainable Electrification
Principal Investigator: Mancarella, Professor P
Other Investigators:
Zhang, Professor F Liang, Professor Q Shaw, Professor D
Gan, Dr C Dawson, Professor RJ Panteli, Dr M
Researcher Co-Investigators:
Project Partners:
University of Chile
Department: Electrical and Electronic Engineering
Organisation: University of Manchester, The
Scheme: GCRF (EPSRC)
Starts: 01 May 2018 Ends: 31 December 2021 Value (£): 1,024,786
EPSRC Research Topic Classifications:
Sustainable Energy Networks
EPSRC Industrial Sector Classifications:
Energy
Related Grants:
Panel History:
Panel DatePanel NameOutcome
07 Feb 2018 GCRF 3 - Energy Networks Call Announced
Summary on Grant Application Form
Rural electrification is fundamental for the social and economic development and well-being of developing countries, as it supports the development of vital critical infrastructures (e.g. communication and transportation) and it provides energy to critical services to peoples' quality of everyday life, such as home appliances, health and water supply. The lack or limited and highly unreliable access to electricity still remains one of the key challenges that rural and remote communities face in these countries. In order though for the electrification to go beyond lightning, it is critical to develop energy networks that are sustainable, cost-effective, and scalable, as well as resilient, particularly in areas that are frequently exposed to natural hazards, such as floods, monsoons, etc.



In this context, the ambition of this project is to develop a novel holistic techno-economic framework for supporting and enabling the decision, policy and regulatory making towards the design of transformative energy networks in developing countries. This holistic framework will be supported by the development of an options portfolio for sustainable electrification, including a mixture of infrastructure solutions (e.g. building new or upgrading existing infrastructure) and emerging low-carbon distributed energy resources that will focus on the development of sustainable microgrids (both grid-connected and off-grid). Further, integrated system simulation models will be developed to analyse the vulnerability and quantify the risk and resilience profile of these energy solutions to natural hazards and extreme weather. This is is highly timely given the latest evidence of the impact of such events worldwide and also highly critical if the rural communities are to withstand and quickly recover from such catastrophic events. Following these analyses, stochastic optimization planning techniques will be developed to support the optimal design of these energy networks, considering transformative energy technologies, to maximize the impact on the well-being of local communities.

Building on this last point, the research team has developed a well-structured user-engagement strategy, bridging to wider socio-economic aspects of communities facing electrification challenges. The aims of this strategy are to get an in-depth understanding of the electricity needs of rural communities in the partner countries (China and Malaysia), enable their active role in the project and provide briefing and training sessions on the use of the new energy technologies to be applied in these communities. The UK and overseas research teams will jointly work with the local industrial partners to facilitate this active involvement of remote villages, communities and their local authorities.

This project will aim to complement and further strengthen the current electrification plans of the partner countries, i.e. Malaysia and China. The research team will work closely with Sarawak Energy and other authorities in Malaysia to review and improve its Rural Power Supply Scheme that was formulated in 2015, as well as evaluate and improve the design, operability and maintenance planning of existing microgrids in Zhoushan islands, China, which also serve as excellent testbeds for validating the simulation models developed by the project. Within this context, this project will also aim to develop recommendations for changes and improvements in standards, regulatory and policy-making frameworks. We will aim to make the key findings and recommendations of this work of generic applicability and validity to accommodate its international development importance. This would also be of UK national importance, where building sustainable energy networks for reducing its carbon footprint, while being resilient to extreme weather (e.g., the storms of 1987, 2007 and 2015 which resulted in major power outages) is key for safeguarding the social and economic well-being of the country.
Key Findings
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Potential use in non-academic contexts
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Organisation Website: http://www.man.ac.uk