Creating Resilient Sustainable Microgrids through Hybrid Renewable Energy Systems

Completed

Other Cross-Cutting Technologies or Research(Energy system analysis)
Other Power and Storage Technologies(Electric power conversion)

Basic and strategic applied research

ENVIRONMENTAL SCIENCES (Geography and Environmental Studies)
SOCIAL SCIENCES (Development Studies)
ENGINEERING AND TECHNOLOGY (Electrical and Electronic Engineering)

Systems Analysis related to energy R&D (Other Systems Analysis)

Professor J Lovett
Sch of Geography
University of Leeds

Standard

EPSRC

01 May 2018

31 December 2021

44 months

£1,259,750

Energy

Yorkshire & Humberside

Global Challenges Research Fund - EPSRC

Professor J Lovett, Sch of Geography, University of Leeds

Dr P Aristidou, Electronic and Electrical Engineering, University of Leeds
Dr R Crook, Chemical and Process Engineerin, University of Leeds
Dr V Dupont, Energy Resources Research Unit, University of Leeds
Dr JM Jones, Energy Resources Research Unit, University of Leeds
Dr H Li, Chemical and Process Engineerin, University of Leeds
Dr K Li, Electronics, Electrical Engineering & Computer Science, Queen's University Belfast
Dr A Ross, Energy Resources Research Unit, University of Leeds
Dr J Schiffer, Electronic and Electrical Engineering, University of Leeds
Professor P Taylor, Process, Environmental and Material Eng, University of Leeds

Project Contact, SIRIM Berhad, Malaysia
Project Contact, Defiant Renewables Pvt. Ltd, India

Universal access to affordable modern clean energy is goal 7 of the UN Sustainable Development Goals (SDGs). The SDGs state that "Energy is central to nearly every major challenge and opportunity the world faces today. Be it for jobs, security, climate change, food production or increasing incomes, access to energy for all is essential." In sub-Saharan Africa, more than 625 million people have no access to modern energy services. Most African countries - 42 in all - are net energy importers and fossil-fuel-fired plants account for 81% of total electricity generation, which is mostly in South Africa. Most large infrastructure projects are public investments financed by national budgets. The estimated cost of bringing Africa's energy infrastructure to modern standard is 93 billion USD/ year. There is a huge gap between energy supply and demand in Africa, and other developing countries, that successive efforts have failed to bridge. The envisioned holistic hybrid MGs will lead to a prototype model for the creation of sustainable and resilient distribution networks for off-grid locations. This approach has the potential to enable electrification of millions of households. Both Tanzania and Uganda are low income 'least developed' countries with a high level of rural poverty and very limited grid connectivity. The Republic of Congo is classed as a lower middle income country due to its mineral wealth, but has low grid connectivity away from cities and its research sector suffers from under-investment in research capacity buildingThis proposal focuses on energy distribution in off-grid communities with a population of around 4000 inhabitants, a size that has been recommended by our African project partners as being the practical optimum for implementation. The research has an integrated approach to ensure that the design of the system is maintainable, has good longevity with low cost, meets diverse community energy needs and is resilient to natural hazards. The overall goal is to enable the development of sustainable and resilient energy distribution grids in rural communities of the low- and middle-income countries (LMICs) Tanzania, Uganda and Republic of the Congo, where currently at most 10% of the rural population has access to electricity. We will achieve this by designing a scalable low-cost MG infrastructure based on a novel planning methodology that incorporates real-time operational strategies and sustainable generation flexibility at the system design stage to reduce the investment requirements and increase sustainability. The MG paradigm will ensure that the research outcomes are also applicable to communities with sporadic grid connections. Building on the existing partnership platform created by the PI's five year 1.2M Royal Society renewable energy capacity building project, the present grant will enable us to realise and experimentally validate a unique, integrated, design platform that incorporates electrical network requirements with hybrid renewable energy generation sources as well as socio-economic and local community-driven considerations. This holistic approach is driven by the understanding that the creation of a truly sustainable, reliable, and locally maintainable energy distribution infrastructure needs to be focused on actual needs and local realities, beyond a purely electrical perspective. This will provide innovative distribution system configurations targeted at supporting the scalable and self-sustainable electrification of rural communities in our three partner countries. An advisory panel drawn from partners of our EPSRC Pump Priming for Global Challenge Research project will ensure that the results are also applicable to LMICs globally.

13/11/18