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Climate Investment Funds (CIFs)
UK - Department for Energy Security and Net Zero
The $8 billion Climate Investment Funds (CIF) accelerates climate action by empowering transformations in clean technology, energy access, climate resilience, and sustainable forests in developing and middle income countries. The CIF’s large-scale, low-cost, long-term financing lowers the risk and cost of climate financing. It tests new business models, builds track records in unproven markets, and boosts investor confidence to unlock additional sources of finance.
Global Energy Transfer Feed-in Tariff (GETFiT)
UK - Department for Energy Security and Net Zero
The Global Energy Transfer for Feed-in Tariff (GET FiT) Programme was established in 2013 with the main objective of assisting Uganda to pursue a climate resilient low-carbon development path by facilitating private sector investments in renewable electricity generation projects. The support provided was expected to improve access to electricity and promote growth and economic development in Uganda and contribute to climate change mitigation.
Climate Public Private Partnership Programme (CP3)
UK - Department for Energy Security and Net Zero
The Climate Public Private Partnership Programme (CP3) aims to increase low carbon investment in renewable energy, water, energy efficiency and forestry in developing countries. By showing that Low Carbon and Climate Resilient investments can deliver competitive financial returns as well as climate and development impact, CP3 seeks to catalyse new sources of climate finance from institutional investors such as pension funds and sovereign wealth funds.
Clean Energy Innovation Facility (CEIF)
UK - Department for Energy Security and Net Zero
ODA grant funding that supports clean energy research, development & demonstration (RD&D) to help improve the performance of innovative technologies, and to accelerate the clean energy transition to avoid the most severe impacts of climate change in developing countries
Accelerate to Demonstrate (A2D)
UK - Department for Energy Security and Net Zero
The A2D programme contributes to the UK’s £1bn Ayrton Fund commitment to accelerate clean energy innovation in developing countries. A2D will focus on developing innovative technology-based solutions particularly through transformational “lighthouse” pilot demonstration projects in four thematic areas: critical minerals, clean hydrogen, industrial decarbonisation and smart energy.
Energy Catalyst Accelerator Programme (ECAP) Rounds 9 and 10
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
Provides incubator and business accelerator support to help companies to grow and to commercialise their innovations.
Potential of sub-seasonal Operational Weather and climate information for building Energy Resilience in Kenya (POWER-Kenya)
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
Context and Challenges Kenya Vision 2030 identifies energy as a key infrastructural enabler for social and economic development, aiming for universal energy access and 100% renewable energy by 2030. Currently, 54% of Kenyans, and up to 84% in rural areas, lack access to sustainable modern energy, relying on traditional wood fuels for cooking and heating. Kenya's energy generation is particularly sensitive to weather variability, with nearly 50% of electricity coming from weather-sensitive sources like hydro, wind, and solar power. Achieving the ambitious goal of 100% renewables requires doubling the current capacity of these weather-sensitive sources. Despite the growing reliance on renewable energy, Kenya lacks reliable weather and climate information for effective energy planning, particularly on sub-seasonal timescales (weeks to months in advance). This gap impacts crucial decisions such as generator maintenance scheduling, international market trading, water conservation, and future energy storage management. In comparison, other regions like Europe have more advanced user-relevant tools for renewable energy decision-making. Aims and Objectives POWER-Kenya seeks to bridge the gap between Kenya's increasing dependence on weather-sensitive renewable energy and the lack of reliable weather and climate information to support energy planning. The project also aims to build capacity for integrated climate-energy research in Kenya. Its objectives are: Ob1: Deliver a step-change in the underpinning physical science to support affordable, clean energy by advancing understanding of sub-seasonal predictability of weather-sensitive demand and renewables. Ob2: Build combined climate-energy research capacity to continue improvements in maintaining reliable energy supply in Africa, facilitating the creation of risk-informed tools for energy decision-making to benefit both society and the economy. Acknowledging Kenya’s continent-leading capabilities in climate and energy fields individually, the POWER-Kenya project brings together UK and African expertise in electricity demand and renewable energy modelling (Bloomfield, Oludhe, Brayshaw, Olago), with the forefront of research on sub-seasonal predictability (Hirons, Gitau, Woolnough), and expert knowledge of East African climate (Wainwright, Mutemi, Hirons) to conduct world-leading energy-climate research to support this step-change in understanding (Ob1) and build partnerships and capacity (Ob2) capable of supporting Kenya’s climate-smart shift to reliable renewables. Applications and Benefits. Universal access to affordable, clean energy helps emerging economies like Kenya progress towards their Sustainable Development Goals by building businesses and societies capable of producing and consuming sustainably for a climate-resilient future. However, access to reliable energy has societal benefits far beyond sustainable economic growth. Reliable energy access can empower women, and other marginalised groups, by improving access to services such as mobile technology, online banking, educational materials, and employment opportunities. Access to clean energy, especially for currently unconnected rural households, can enhance health outcomes by reducing reliance on traditional wood fuels, which are linked to respiratory diseases. Achieving POWER-Kenya aims to ensure Kenya's shift to clean, weather-sensitive renewables is backed by current scientific thinking and proven techniques that will help deliver the country's aim for reliable energy for all businesses and households. Beyond Kenya, POWER-Kenya outcomes will inform and support the aims of the wider Eastern Africa Power Pool (EAPP) - an institution that coordinates regional cross-border power trade and grid interconnection. KenGen, a key project partner and regional leader, is a utilities member of the EAPP. Through iterative dialogue with POWER-Kenya, KenGen will help co-design the research, by defining energy stress case studies, and ensure it remains solutions-orientated and maximises benefits for Kenya and the broader region.
Efficient Photoelectrochemical Green Energy System based on Hematite Photoanodes Heterostructured with Selected 2D Transitional Metal Dichalcogenides
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
This project addresses the urgent need for sustainable energy solutions by enhancing photoelectrochemical (PEC) water-splitting technologies, which convert solar energy into storable hydrogen fuel. With the increasing global focus on mitigating climate change, the development of efficient, renewable energy technologies is paramount. PEC water splitting, a process that uses sunlight to produce hydrogen, presents a promising pathway to this goal. Our initiative centres on improving the efficiency of hematite-based PEC devices through innovative heterostructures incorporating two-dimensional (2D) transition metal dichalcogenides (TMDCs), such as SnS₂, MoS₂, SnSe₂, and MoSe₂. Hematite has long been studied for its potential in solar-driven water splitting due to its strong visible light absorption and favourable theoretical solar-to-hydrogen (STH) conversion efficiency. However, its practical application has been limited by issues such as poor electrical conductivity, slow charge transport, and high recombination rates of electron-hole pairs. By integrating hematite with 2D TMDCs, we aim to overcome these challenges, enhancing the material’s performance through improved charge transfer, reduced recombination losses, and optimised band alignment. This approach promises to boost STH conversion efficiency and achieve the 10% benchmark set for practical applications, making a significant contribution to the development of scalable, clean energy solutions. The project not only advances scientific knowledge but also brings substantial benefits to researchers and institutions in Africa. The collaboration between UK and African institutions facilitates access to cutting-edge facilities and expertise in the UK, which are critical for the successful implementation of this research. African researchers will have the opportunity to train on advanced characterisation tools and gain hands-on experience with state-of-the-art PEC technologies. This exposure is invaluable for building their technical skills and enhancing their research capabilities. Moreover, the project fosters networking and collaborative opportunities between African and UK researchers, promoting the exchange of knowledge and ideas. This international collaboration helps to strengthen research networks, opening doors for future partnerships and joint ventures. African institutions will benefit from the establishment of sustainable partnerships and the development of local expertise in advanced energy technologies. Additionally, the project includes outreach and dissemination activities, which will raise awareness and engage various stakeholders, including the public and industry players. These activities will not only highlight the advancements in PEC technology but also showcase the contributions of African researchers to global scientific progress. In summary, this project is poised to make significant strides in improving PEC water-splitting efficiency, with the added advantage of enhancing research capacity and collaboration between African and UK institutions. By addressing key challenges in renewable energy technology and providing valuable training and networking opportunities, the project aims to contribute to the global transition to clean energy while strengthening the scientific community in Africa.
Temperature-sensitive Earth-abundant Catalysts for green Hydrogen production
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
Hydrogen production via water electrolysis technology has been a major focus of discussions for practical carbon-neutral transportation fuel and a key component for other chemical syntheses for the past decade. Particularly, Africa’s total announced electrolyser pipeline capacity has reached 114 gigawatts. However, the costs of water electrolysis to be reported in the range of 2-5 £/kg H2, which is still twice as expensive as the existing fossil fuel-based technologies. Among various electrolyser technologies for hydrogen production, alkaline water electrolysis is considered to be the most mature type for industrial scale-up and has strong cost-effectiveness. Despite these advantages, its cold-start nature, unfortunately, requires a certain ramping-up time (approximately 1 hour). This makes it challenging to integrate with renewable energy sources, which are difficult to predict. Alkaline water electrolysis at elevated starting temperatures offers a promising solution to enhance catalytic reactivity and reduce required electric energy, increasing cost-effectiveness. The cobalt- and nickel-based catalysts, known for their prominent temperature dependence, could be the key to enhancing the hydrogen production rate. In this study, we aim to establish a feasible fabrication method of temperature-sensitive catalysts for alkaline water electrolysis and to explore the multi-element catalysts' physical and chemical bonding structure change at elevated temperature conditions. Exploring the underlying mechanism of intrinsic kinetics change is a challenging yet crucial step towards more efficient and cost-effective hydrogen production. The ultimate goal of the proposed collaboration entitled "Temperature-sensitive Earth-abundant Catalysts for green HYDROgen production (TECHydro)" is not to develop new catalysts but to discover new combinations that have a high-temperature sensitivity and explore underlying principles, giving rise to fresh perspectives of the developed catalyst for their application to AWE. The outcomes will provide a methodological achievement in cost-effective catalyst preparation. Moreover, the project will make a rigid bridge for further joint-research funding applications and staff exchange between African (South Africa and Kenya) and UK partners. We believe that the outcomes of this study could set benchmarks for hydrogen production that operates more efficiently in South Africa and Kenya's hot climate, contributing to the global transition towards a hydrogen economy.
Compound-Semiconductor-Enabled Renewable Energy System for Powering Critical Buildings in Africa
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
Africa’s power supply systems for critical loads, such as healthcare facilities, are transitioning to a more sustainable, efficient and reliable future. This is driven by the integration of renewable energy, which includes AC and DC power conversion enabled by power semiconductors switching at increasingly high frequencies (e.g., 10–100 kHz). The semiconductors’ operation causes power loss, reducing energy efficiency, and they are the most vulnerable components, counting for 20%–30% of the failure of power conversion systems. Improving the performance of the semiconductors will thus provide significant benefits in energy saving and system reliability improvement. For example, a 1% increase in efficiency in solar photovoltaic (PV) inverters and a 1% in reliability will make 150 GWh more energy available to critical healthcare facilities in Africa. This project’s overarching aim is to leverage the latest advancements in Silicon Carbon (SiC) semiconductor technology to develop high-efficiency and reliable solar photovoltaic-battery energy storage system (PV-BESS) for critical loads. Such compound semiconductors have low conduction loss, fast switching speed, and high operating temperature, which provides all potential for developing low-carbon PV-BESS. Challenges are that high-frequency switching of SiC semiconductors can increase thermal stress and create electromagnetic interference (EMI) due to their high-speed voltage transients (e.g. dv/dt over 10kV/us), affecting the reliability of the PV-BESS and lifespan of critical components such as capacitors and batteries. SiC semiconductors exhibit various material defects and variability, leading to variations and high non-linearities in their electro-thermal performances. Integrating SiC semiconductors into PV-BESS requires a better understanding of induced parasitic parameters and their coupling with components, including capacitors, inductances and gate drivers. To address these issues, the project has three research work packages (WP1-3): Develop accurate characterisation and modelling methods for semiconductor devices (WP1): Accurate SiC electro-thermal models and lifetime models will provide a new understanding of SiC semiconductors, which will be built to evaluate component efficiency and reliability under various environments. Integration optimisation of SiC-based PV-BESS (WP2): This involves studying and modelling the multiphysics coupling between SiC semiconductors and other components, investigation of induced parasitic parameters and system-level topology design of PV-BESS to reduce power conversion stages, thus improving overall efficiency and reliability. Validation and operation optimisation of SiC-based BESS in various operation conditions (WP3): This will investigate integration strategies and verify the benefits brought by SiC devices' advantages to ensuring the BESS’s high-efficiency and reliable operation in both normal and fault conditions. The main deliverables will include validated tools and a testbed for modelling and characterisation of SiC semiconductors (WP1), hardware-in-the-loop demonstrator for validating the SiC-based PV-BESS (WP2), and optimal operation strategies for PV-BESS (WP3). These will be useful to physics R&D institutions, renewable equipment vendors, and power system operators. The project will involve international partnerships with the University of Nairobi, with support from Scottish Power Energy Networks (SPEN) and Toshiba Europe. Researchers involved will benefit from the unique collaboration and training, and the project will help Africa build new physics research capacities in the renewable energy and semiconductor sectors. The project output will boost the PV-BESS’ energy conversion efficiency by 1%–2%, and extend their mean-time-between-failures by 20%. Developed compound semiconductor technologies will have a wider impact across applied industries, including electrified transportation sectors, robotics and aerospace. The integration and BESS technologies can be extended to generic low—and medium-voltage energy systems.
SolarERA (Solar Electrification of Rural Areas)
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
The people of Thar Desert have little to no electricity access. Those that have access, use diesel polluting generators to produce this electricity, while fuel supply is unreliable and intermittent. The Thar is the most populous desert in the world, with approximately 16.6m people living there. Tharis are far behind the Pakistani average on economic skills. They rely predominantly on agriculture/livestock and "Thari crafts" (ornate embroidered/sewn garments such as quilts and cushions) to survive. The Thari women who make these crafts are extremely hardworking and talented, spirited and committed. Empowering women can change the destiny of Tharparkari people. However, the unavailability of electricity needed to power productivity enhancing stitching/sewing machines, means these women must make every stitch painstakingly by hand. As such, garment making is incredibly slow, laborious, and they are unable to leverage their skills to benefit their families and the wider village community. By the end of 2026, SolarERA systems will be ready to provide a unique electrification solution that will benefit these people by affording them access to off-grid electricity and in turn electric sewing/craft machines, and in doing so revolutionise their current economic situation. As a result, Thari-crafts can form the bedrock of the economic model that will provide microfinance institutions with the confidence to offer the initial investment to fund the SolarERA pico-grids. From this key initial electrification enabler, further downstream benefits can flow in relation to Health and Well-being, Education and Learning, Communication and Connectivity etc. Additionally, SolarERA will serve to preserve the age-old Thari crafts skills of these women, passed down by successive generations for centuries. The benefits to project partners are clear, major growth in jobs (25-UK, 125-PAK) and economic activity (£22.5million in revenues) by 2031. Kunwaa Foundation will be able to achieve its aim of improving the lives of the Thar people more easily and faster. SALATEEN will become a leader in the supply and installation of pico-grids across Pakistan and neighbouring countries. Zhyphen will see a significant boost in exports of critical technology for the enablement of low-cost off-grid solar solutions, enhancing it and Brunel-University-London's reputation as leaders in this area
SolarSaver2 (SS2) Low Cost Energy Solution in Africa Energy Catalyst Round 10: Mid Stage
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
SOLARSAVER2 focuses on delivering a sustainable business model for using innovative low carbon off grid drying solutions. The project aims to create value for small- and large-scale sub-Saharan agricultural producers and other stakeholders by adding a new sustainable technical and processing solution delivered at a pricing level suitable for deployment in Africa and Asia to create highly nutritious products and reduce food waste. Fruit and vegetable products are of high moisture content. The key target is to significantly reduce the energy consumption, operating costs and carbon footprint of conventional drying techniques using an innovative low-temperature drying process. The sustainable delivery of low cost drying has a significant impact on the different sections of society such as the poor (majority of farmers) and women (about 50%) are catered for. Extensive operations and trials are planned with partners in Tanzania including local manufacturing. The processing solution is such that it can be easily deployed on-farm at different degrees of decentralisation and in centralised small, medium and large-scale industrial sites.
Li-Ion Battery Storage Circularity For Africa By Africa for Low-Carbon E-Mobility E-Agriculture and Minigrids
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
Kampala, Uganda has the 17th worst air pollution in the world, with an abundance of motorcycles contributing with unregulated emissions. 75% of Ugandans are rural farmers, living off of subsistence farming with energy access rates below 10%. Meanwhile, the two-wheeled EV (2WEV) market is taking off in the region, poised to help reduce air pollution but introducing a looming e-waste problem caused when their lithium-ion batteries reach the end of their service life. Taken separately, these are problems. But together they represent an opportunity to turn e-waste into e-resources, increase energy access and agricultural productivity, and boost the uptake of clean energy solutions. To this end, Soleil Power and STI4D are implementing a project to build high-quality 2WEV batteries designed for efficient repurposing into affordable and scalable 2nd-life products for energy access customers. We want to get ahead of the curve by enabling a circular battery value chain right from the start. Li-Ion batteries have a long total life-span but they are removed from EV service once they are depleted to 80% of their original capacity. Thereafter, whilst they are no longer optimal for EV use, they still have very high potential value in stationary applications such as mini-grids and institutional ESS. To capture this value, STI4D and Soleil will also design affordable 2nd-life products that can be deployed off-grid or as backup-power. Soleil will build on existing partnerships to test these innovative products. E-mobility company Zembo, building 2WEVs and battery swapping/charging infrastructure, sees high value in procuring their batteries domestically as well as having a partner to offtake them after they have completed their service. E-Ag partner Regenerators, who are working to increase smallholder productivity through the introduction of an electric tractor will also pilot the EV battery. Soleil's experience shows that much of the cost associated with the repurposing of EV battery products depends on the complexity of disassembly, testing and rebuilding used battery-modules. The new designs will streamline and accelerate this process to reduce e-waste and facilitate circularity whilst increasing access to clean and affordable energy. A better understanding of the battery circular economy in East Africa is critical to finding optimal ways to incentivize commercial investment, so STI4D and Soleil will also use the project as a case study on which to conduct a value-chain analysis, developing and collecting data on sustainable business models including for combining energy access systems with battery-charging as anchor loads.
VUTSELA: Sustainable Farm-based Biogas Systems with Community Impact in Eswatini
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
VUTSELA means "keep burning" in Siswati. Energy access in Eswatini is limited and very dependent on neighbouring countries with 80% of electricity being imported from South Africa and Mozambique. Liquefied petroleum gas availability is declining sharply with production facilities in South Africa closing down. The bulk of the population (78%) are based in rural areas, contributing to the crisis of ensuring viable and sustainable supply of energy to households. Decentralised energy supply solutions such as solar PV and biogas are suitable solutions to this problem. Biogas may be particularly well suited for adoption in Eswatini as 71% of the land is agricultural and feedstock for digestion is readily available. Biogas generated sustainably from waste could satisfy household or light-industrial heating requirements, which form the majority of energy needs. Farms would be an appropriate route to market entry as digestion provides the added benefit of waste disposal and fertilser production in addition to energy savings from biogas production. As 37% of the economically active population of Eswatini is employed in agriculture, targeting farms aids the economic survival of a backbone of employment in the country. Moreover, it effectively exposes a large proportion of the population to a new technology (biogas generation through anaerobic digestion) which aids in education and wider scale later adoption. This project aims to roll out 100 digesters (plus an initial 15 prototypes) to low income farms in Eswatini and the bordering regions of South Africa. Eswatini is targeted due to the reasons stated, and South Africa is seen as a potential market expansion in neighbouring regions with a similar context. This project period will be used to gain valuable market feedback through community engagement and the established methods of Smart Villages Research Group to understand and define the real needs of the local farms and communities and use this information for design revisions before future commercial rollout and continued operation. The project will be executed with a local tertiary training centre, STREEC, aimed at equipping Eswatini youth with technical skills in renewable energy and entrepreneurship. Small commercial farms will be chosen for initial sites within a 100km radius of the training centre for ease of monitoring, training, and engagement hubs for wider groups of low income farmers to introduce the technology and understand the specific needs and value to the community. Innovation will be largely focused on technology adoption and developing a viable and sustainable business model.
Renewable ENergy Demand Assessment and eNtrepreneurial Growth (RENDANG) for Energy Access in Malaysia
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
Our project addresses challenges and opportunities in rural electrification, particularly for remote Orang Asli communities in West Malaysia. Despite the country's considerable urban development and high electrification rates, about 200 of these villages remain under-electrified. A critical challenge in deploying distributed systems in communities is assessing and growing demand for electricity. Current approaches in distributed systems involve surveying communities, then designing and installing systems such as mini-grids based on this initial assessment. Mini-grid construction can be a slow process, and during the wait, communities may lose interest or trust in the electrification process. When the mini-grid eventually comes online, demand can be disappointingly low, as the community is only just starting to develop their productive use businesses and grow their payment behaviour. We propose to address this problem by integrating the Community Energy Toolkit (COMET), a community engagement software tool to assess demand, and a mobile mini-grid to provide quick and temporary electrification to build demand, while deploying more permanent solutions. Our project involves a collaboration between Smart Villages Research Group (SVRG), Energy Action Partners (ENACT), and the COMET team, to develop an integrated model that merges COMET's predictive capabilities with the immediacy of mobile mini-grids in Pos Titom located in the state of Pahang, Malaysia. This approach will accurately assess energy needs to be met by cost-effective Clustered Solar Home Systems (CSHSes), foster demand for productive uses of energy using the mobile mini-grid, and encourage sustainable income via targeted capacity building for village-based enterprises enabled by these systems. This innovative model aims to bridge the gap between the initial community engagement and the installation and commissioning of a distributed energy system. It will help maintain community interest and grow energy demand gradually, a crucial step for scaling distributed energy systems sustainably. We expect the combination of the two technologies to be widely scalable. Whilst we will be validating the approach in Malaysia, the successful demonstration of the impact will allow us to apply this innovative suite of tools to improving minigrid and energy access development worldwide, where for example latest estimates (World Bank ESMAP, 2022) forecasts a need for at least 200,000 more minigrids to be able to meet SDG energy access targets in Africa alone.
Electrical Storage Systems for Sustainable Uninterrupted Clean Energy and Water Supply to Hospitals and Communities in South Sudan
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
This is a combined ElectricalStorageSystem (ESS) and SolarWaterPumping project. It will supply 24/7 power and water to 2 hospitals and 1 school in selected countries. We are combining the service to the institution with community based water kiosks, and the earnings from water sales will pay for system upkeep and cover lifetime replacement costs. The innovation of this project is to test the combination of different existing technologies to provide services with excellent social returns, and with a sustainable finance model included. Installing solar energy systems means schools and hospitals have uninterrupted daily energy; sufficient ESS capacity ensures 24/7 availability. Solar powered water pumping, with ESS backup, provides clean water 24/7, from multiple access points, supplying the local community as well as the schools and hospitals in this project. The erratic costs of running and maintaining diesel generators are eliminated by the minimal maintenance requirements, and these costs are covered by income from sales of water. The project will be delivered in South Sudan. We have selected this country because of the implementation challenges posed due to recent socio-political activity, and because this is a place with the greatest need. This technology will be a model for hardest-to-reach countries and locations. Aptech has a strong presence in South Sudan, and is one of the few companies that has the capacity to implement this project in partnership with SVRG. South Sudan has been devastated by war and disease. Access to clean energy and water is critical to the improvement of educational and medical services within South Sudan, where less than 50% of people have access to water resulting in low life expectancy and very high infant mortality rates. Access to electricity and water in institutions in these countries is under 20% resulting in load sharing and power outages of at least 8 hours, which disrupt services. We will monitor the impact of the project on the community and establish the sustainability and replicability of the system in additional institutions. Aptech has consulted with both the government of South Sudan and local NGOs to identify institutions to launch this pilot project, and they are very supportive of our plans. Once we have proof of concept, we will present our findings to NGOs, private institutions, and the governments to promote the replication of the system, through collaborative partnerships, and to expand access to electricity and water for institutions all across each respective country.
Innovative Low Voltage Single Wire Earth Return (SWER) for Affordable Microgrid Distribution Infrastructure in Africa
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
A typical village in rural Uganda might have 225 houses, consume an average of 0.3kWh per day from a minigrid, and require 8km of distribution infrastructure (poles and cables) to connect all the spread out houses. The village in the UK in which we are based has 1250 houses, consuming (conservatively) 10kWh a day, and requiring just 4km of (identical) distribution infrastructure because of our high housing density. Our electricity tariffs are roughly the same (at $0.20/kWh). The UK village pays a combined total of just over $900k a year for electricity, which repays the cost of the distribution system within 2 weeks. The households in Uganda pay just under $5000 a year for electricity usage, and will therefore need more than 16 years to repay just the cost of the poles and cables, without even factoring in the cost of the electricity generation itself. More than anything else, it is the cost of distribution that kills the commercial viability of minigrids, and prevents remote households from being connected to electricity systems in offgrid rural communities in Africa. There has been little to no innovation in distribution to match the significant recent advances in generation and storage technologies and affordability. Single Wire Earth Return is a promising technology used for high voltage rural connections in the electricity grid in the US, Canada, South Africa, Mozambique, Laos, Brazil, Australia and New Zealand. In this feasibility study we propose to adapt the technology to low voltage (230V) use in last mile connectivity in rural minigrids and test its performance in multiple locations and climate/soil conditions, collecting data to demonstrate its cost effectiveness and safety for users and the community in rural energy access. We estimate the technology could save as much as 70% of the cost of traditional distribution systems. We will also engage with local regulators and the international energy access community to introduce them to this technology, and encourage its uptake to enable wider energy access in remote communities and households, and lower energy tariffs in these communities. Partners SVRG (\>20 innovative rural energy systems in sub-Saharan Africa), MOSCET (foremost sustainable energy company and minigrid installed in Lesotho), Kiima Foods and OMASI (rural development NGOs with experience of \>40 community technology solutions) and electrical engineering experts National University of Lesotho Energy Research Centre are collaborating on this project to trial the technology in three communities and evaluate safety and cost-benefit.
Innovative Agricultural Cross-Subsidised Financing of Access to Clean Energy and Sustainable Cooling with Smart Agri-Centres in Uganda
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
In an EnergyCatalyst7 project, SVRG with Ugandan partners developed a game-changing approach to rural energy-access, economic-empowerment and agricultural-productivity. The SmartAgri-Centre(SAC) combines a50kW centralised solar-power plant with an integrated set of community productive use and agri-value-addition services, in a large central community hub. Feedback from the local community shows the social impact the Centre has brought, including improved environment, knowledge of farming practices, income, savings and positive impact on family life and education. In the first year of operation, analysis showed that the SAC services helped farmers quadruple average annual earnings (up from $800 to $3100), increase yields across a variety of crops, and reduce input costs by 30%. Across the community, in that year, the centre generated additional value of $211,500. GESI impacts were also apparent: the majority of the 110members of the newly-formed agricultural cooperative are women, and female farmers reported positive impacts from the SAC. 40% of Co-op board members, and 40% of the business committee are female. The SAC is designed to address specific priorities and needs of a community, so each is subtly different. But the average cost to SVRG and partners of providing the infrastructure, and years of community support/training is around$250,000. The data we have collected suggests that communities should be able to afford to repay this cost in less than 2 years from their increased earnings. Our challenge in scaling this solution is to determine the best business model and community engagement strategy for the community to be able to repay the costs of providing the SAC from their agricultural income. According to the data we have collected, the community earns enough to repay the costs in under 2 years. However, the mechanism for this is far from obvious. Individual farmers in these communities are highly risk-averse (as well as lacking financial skills and creditworthiness). Entering into contractual arrangements with 100+ separate farmers to ensure repayment would be unworkable. Alternative models (operating the centres ourselves and collecting revenues and taking a cut of agricultural earnings as a "benign middleman", or establishing/empowering a community cooperative to do the same, have other risk factors and disadvantages). In this project, SVRG and partners will construct and operate 6 of the SACs in new communities, trialling different business/repayment models, to establish the ones that will allow us to scale the roll-out of the technology to rural communities with the highest amount of success, impact and commercial return.
Renewable Energy Agro-Processing Hubs for Energy Access and Economic Development in Rural Rwanda
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
Our project, REAP (Renewable Energy Agro-Processing) hub, is a transformative initiative aimed at empowering rural communities by providing sustainable access to renewable energy and enhancing their food production capacities. Through the integration of innovative technologies and community-driven approaches, we seek to create lasting social, economic, and environmental impact in underserved regions. At the heart of our project is the vision to address the energy poverty prevalent in remote rural areas, where communities face challenges due to lack of reliable and affordable energy. Bby harnessing the power of renewable energy, we can unlock tremendous potential, enabling these communities to improve their quality of life and drive sustainable development. We begin with robust community engagement and needs assessment to truly understand the energy requirements and aspirations users. By working closely with the target communities, we ensure that our solutions are tailored to their specific needs and integrate seamlessly into their daily lives. Through strategic partnerships (Smart Villages Research Group and NjordFrey), we will deploy renewable energy technologies to support high yield fish/vegetable production with value addition (cooling/food drying). Intelligently monitored and coordinated through a digital monitoring system, the REAP hub will automatically balance the energy and production demands to increase efficiency and reduce energy and production costs. The REAP project extends beyond energy access. We recognise the vital role of productive systems in rural communities, such as agriculture and small-scale enterprises. By incorporating energy into these systems, we unlock new opportunities for income generation, value-chain development, and market access. This integrated approach fosters economic growth, creates employment, and reduces poverty, ensuring long-term sustainability. Furthermore, our project aligns closely with the Sustainable Development Goals, particularly SDG 7 (Affordable and Clean Energy) and SDG 13 (Climate Action). By promoting renewable solutions and mitigating greenhouse gas emissions, we contribute to combating climate change. The impact of the REAP project last far longer than our project implementation. The knowledge, skills, and partnerships developed throughout the project will serve as a catalyst for replication and scaling up to 2,000 hubs across Sub-Saharan Africa, fostering widespread adoption of renewable energy solutions and transformative development models. Through collaboration, innovation, and a deep commitment to sustainable development, REAP aims to empower rural communities, unlock their potential, and create a brighter future for all. Together, we can build resilient communities, promote Gender and Social inclusivity, and achieve a greener and more prosperous world.
Empowering impactful development across rural Malawi through clean Energy HUBs
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
Malawi is one of the poorest countries in the world, and the country faces severe challenges in multiple aspects of the society. Only around 16% of the population aged 25 and above have completed secondary school, 70% of Malawi's population between 15 and 29 are not employed by formal organisations. Only 18% of the Malawi population has access to electricity services. And the lack of a culture for operation and maintenance often results in that for instance installed solar energy systems are not taken care of and stop functioning after just 2-3 years while their technical life-time is often 15-20 years. Differ Community Power is specialised in providing reliable energy services to schools and health facilities in developing countries. In Malawi, DCP, with SteamaCo, has more than 100 sites in operation, and at all of these sites there is excess energy available during daytime that currently is not used. This project seeks ways to use this excess energy to solve some of the challenges mentioned above, including earning money to do O&M on the solar energy systems at the health facilities. We are doing this by selling electricity services to off-takers. These off-takers must afford paying for the energy, and this ability to pay is the main risk to whether we are able to create a viable business. Examples of off-takers and related businesses are: Water Services for agriculture irrigation: Using excess energy to pump water into water tanks during daytime and farmers can use irrigation systems and gravity for water feeding the soil during nighttime. 80% of the population is involved of agricultural activities, and providing water so that the farmers potentially can have more than one harvesting season, is promising. Cooling service for agriculture proceeds: Using excess energy to offer cooling services for the agriculture proceeds. The loss of proceeds and value will be significantly reduced Energy services for households: Using excess energy to charge batteries that are rented out to households that cannot afford their own solar home system. Milling services for farmers: Using excess energy to run maize mills the farmer so far have been using diesel generators for. All of these services imply selling electricity and if successful, the impact will be very positive on several of the SDGs, e.g. on health services (SDG3), education (SDG4), clean energy (SDG7), economic growth (SDG8) and climate change (SDG13).
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