- Home
- Aid by Sector
- Industry
- Energy generation, renewable sources
- Energy generation, renewable sources - multiple technologies
Aid by Sector
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.
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.
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.
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
CoolRun Malawi
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
Agriculture is the key industry in Malawi; however, given the sub-tropical, climate, the cold supply chain for fruit, vegetables and other temperature sensitive goods is lacking. In most of Malawi, the electricity supply is unreliable, and the increasing cost of fossil fuels makes it expensive to operate internal combustion driven generators and compressors. The lack of a reliable, affordable, and available cold supply chain leads to high levels of wastage up to 50% of some crops harvested. In rural areas, farming is mostly on a subsistence basis and a female occupation. Farmers either sell their produce directly (or via resellers) at markets or roadside walking up to 2 hours to reach their pitch. Because the crop is not chilled, it cannot be easily sold to shops or supermarkets where higher prices could be realised. Our innovation is to develop a micro, affordable, mobile, sustainable refrigeration system comprising a modular refrigerated box cooled by Phase Change Material (PCM) panels. The crop is pre-cooled at a central location using a solar powered refrigeration unit that also cools the PCM panels. Temperature integrity is monitored via sensors that monitor GPS position and temperature and the data is transmitted to a cloud database for verification by supplier and customer alike. The design and development work will be undertaken by Aston University in conjunction with its SME partners Hubl Logistics, Enterprise Projects Ventures Limited (EPVL), Malawi Fruits and Engineeronics Ltd in the UK and Modern Farming Technology (MFT) in Malawi. EPVL will supply the systems and the prototype will be evaluated in the field by MFT and Malawi Fruits. MFT will assess any gender related issues with the design. A digital twin of the design will be developed at Aston and performance of the prototype will be compared to the digital twin which will inform the final design. Aston University will conduct studies of the impact of the technology on gender and unrepresented groups. Fruit and vegetable farming and selling in Malawi are activities divided based on gender with land ownership male dominated with females relegated to farming and sales. The technology is being developed with farming and selling enterprises in Malawi in mind to empower women to develop their enterprise and social standing by adding value to their activities. CoolRun enables users to cut waste dramatically providing more to sell and reach markets where prices are higher thereby generating greater returns.
Decentralised Energy Market Access And Co-finance (DEMA2C)
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
UNSDG 7 targets to achieve universal energy access by 2030, unfortunately, based on the current trajectory there is still a gap and it may be growing. This is so given that globally, about 789 million people (597 million of whom are in sub-Saharan Africa SSA do not have access to energy. Moreover, limited coverage, high interconnection costs, high energy and unreliable supply are the primary challenges of using conventional grid connections for both rural and urban areas. This would have been the opportunity for decentralised grids e.g. solar to fill the gap, especially off-grid communities completely cut-off from the main grid, unfortunately, renewables intermittency and high upfront costs are strong deterrents, moreover, there is a low affinity for financing micro-grid generation because investors struggle to track their ROI. The current set-up/technologies supporting DERs particularly solar are yet to overcome the peak generation and peak consumption mismatch nor track ROI. The DEMA2C consortium including Innovation Consultancy & Entrepreneurship (lead Partner), OtaskiES, Wave Insight, Moneda, MAD and Edo State Ministry of Infrastructure will be developing a technology that will enable the creation of a unified renewables-based grid that can supply on-demand green energy to off-grid communities. The technology will bridge the intermittency of the renewable delivering on-demand energy supply by optimising the link between generation and consumption without additional panels, high storage bank costs nor resorting to fossil-fuelled generators. It will also offer an energy-as-a-service model supported by an innovative payment platform with real-time ROI tracking for investors. This will stimulate investment into DERs to meet SDG 7 target by attracting investors that up to now have been shying away from investing in renewables-based micro grid. Successful deployment of DEMA2C will also enable prosumers are able to get an ROI 5X faster than when they would be just self-consuming their generated capacity. The clean energy DEMA2C enabled micro-grid will facilitate the avoidance of e1.04CO2kg/kW in emissions by replacing the use of generators.
Ubuntu Energy
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
This project aims to build community resilience in sub-Saharan Africa using Energy Ubuntu as a vehicle. It is akin to the 'Uber of Energy', democratising power sharing, transforming wasted energy into community power, and empowering communities to drive their development through sustainable means. It seeks to transform waste energy to community power for productive use. It addresses the developmental challenges of lack of modern and clean energy access, energy poverty and the harmful effects of global warming by improving access to clean and reliable electricity and deriving new business and economic change models, and building capabilities and contributing to SDGs 1,3,4,5,7,8,9,11,12,13. Nigeria's electricity sector faces a problem. Its Distributed Energy Resources (DERs) are sub-optimally utilized and substantially wasteful, while it has deficient electricity access of ~60%. Solar photovoltaic (PV) systems are up to 400% oversized or lack the mechanism required to utilize their generation potential. Some PV systems are up to 80% used during the weekdays but are 20% utilized on weekends. Rural communities only utilize about 5% of the potential PV energy. Yet, 85 million Nigerians have no electricity access, costing Nigeria $26 billion annually for self-generation using carbon-intensive generators, causing excessive carbon emissions and energy waste because excess generation cannot be fed into the grid. To address this challenge, Energy Ubuntu delivers a design and pilot of a smart grid (SG) peer-to-peer (P2P) energy-sharing framework that enables the distribution of excess generation potential to energy consumers to enhance PV capacity utilization and minimize energy waste while providing clean and affordable electricity. It improves PV usage by incentivizing individuals or businesses to sell energy to potential consumers in a peer-to-peer system. The consumers will be SMEs and homes near solar PV systems in rural and urban communities. The project will be implemented over two years with critical deliverables of smart grid design, energy trading software, energy data mining and machine learning models for energy supply, deployment of smart circuitry in 200 sites, energy trade, and the evolution of new business models and community resilience initiatives. It will be implemented by four teams, Greenage Technologies (Technical lead), Nithio (Technical partner), Oxford EPG (research lead), and DRE Partners Ltd (formerly Kula Foods) (Admin Lead). Some co-benefits can be derived from Energy Ubuntu, including sustainable community development and carbon emission reduction leading to improved standards of living while significantly decreasing CO2 emissions.
Improving access to sustainable energy in rural Pakistan using food and fiber agro-waste as a renewable fuel (SAFER)
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
Our project, "Improving access to sustainable energy in rural Pakistan using food and fiber agro-waste as a renewable fuel (SAFER)," is a bold initiative aimed at tackling the dire lack of electricity in rural areas of Pakistan especially for off-grid communities. It harnesses the immense potential of agro-waste generated from fiber production to create a sustainable and accessible source of energy. Despite Pakistan's abundant renewable energy resources, more than 50% of people in rural areas still live without electricity, heavily reliant on energy imports and fossil fuels. With only 7% of energy generation coming from renewables, there exists a significant deficit in meeting the country's energy needs. Our innovative approach combines two cutting-edge technologies to establish a true sandpit technology, forging a circular model based on food, fiber, and energy while generating zero waste. SAFER leverages NTU Pakistan's indigenous technology, which efficiently produces high-quality textile fibers using agro-waste from bananas. Remarkably, the fiber production process generates a second round of agro-waste, allowing us to maximize resource utilisation. SAFER utilises ERL UK's Patent-pending and advanced thermo-chemical conversion technologies to deploy sustainable and clean energy solutions in remote areas of Pakistan. By converting agro-waste into renewable fuel, our project offers affordable and accessible energy to local industries and communities, alleviating the burden on Pakistan's overstretched energy sector. Through gasification technology, we harness the power of agro-waste to generate syngas, which are then used to produce electricity. Beyond energy production, SAFER also targets the improvement of Pakistan's textile sector, a vital industry that serves as the country's largest exporter and employs millions of individuals. In SAFER, we utilize agro-waste, such as banana peels, to manufacture high-quality textile fibers, biochar/biofertilisers, and electricity. This not only creates value-added commodities but also facilitates effective waste management. Our approach curbs the industry's environmental footprint while mitigating the adverse effects of declining cotton production caused by environmental changes. To ensure the commercial viability of our solution and effectively address Pakistan's energy crisis, we adopt a holistic approach to integrate systems (Food, Fiber, fertiliser, Energy) and ensure compatibility with multiple market routes and technical solutions. With SAFER, we envision a brighter future for rural Pakistan, where access to sustainable energy becomes a reality through the transformation of agro-waste into value-added products. Through these efforts, we empower local communities, contribute to Pakistan's sustainable development, and pave the way toward a brighter and more prosperous future for all.
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.
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.
RASSCOL Nepal: Retrofit Application of Spectrally Selective Coatings to Overhead Lines
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
The project aims to demonstrate discontinuous cost savings in upgrading transmission and distribution capacity via the application of capacity-enhancing coatings to overhead lines.
Development of a HIGH Capacity FLEXible Energy Storage System for Mini-Grid Application in Sub-Sahara Africa (High ESS)
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
This collaborative project will develop and demonstrate a new technology (HIGHFLEX) that consists of a high-capacity flexible energy storage systems (HIGHFLEX ESS) integrated with innovative Battery Management System (BMS); Power Conditioning Unit (PCU) and intelligent monitoring and performance management system (Digital Twin) for mini grid applications in hot climates. The new technology is a portable and scalable system that facilitates: Quick development of mini grids in SSA. Storage of high-capacity energy generated from clean power sources during peak hours for off-peak utilisation. Delivering reliable and affordable power system through innovative solutions e.g., Digital twin, second life battery, real-time performance management and heat control system. The project's vision is to rapidly accelerate access to affordable off-grid electricity from clean energy sources in SSA. The project taps into the expanding global mini grid markets to offer affordable energy access for social mobility and inclusion in SSA communities not served by main power grids. HIGHFLEX will facilitate steady supply of electricity to rural and unserved areas and reduce energy access gaps between rural and urban communities in SSA where inaccessibility to affordable electricity is one of the main drivers of poverty to over 600 million people. This project has chosen Nigeria as a case for deployment of HIGHFLEX technology because of its over 200 million population and majority of its rural population (48% of its total population) do not have access to affordable and low carbon electricity. The project addresses barrier (access to electricity) to adoption of advancements in healthcare system; developing new technologies for agriculture, commerce, education; and entrepreneurship. HIGHFLEX makes it possible to deliver low carbon electricity to unlock sustainable economic development in SSA communities. This will empower women and children to lead more productive lives and have a better wellbeing. This will in turn encourage gender equality by learning digital and modern skills, which gives girls and women equal access to education, healthcare and enterprise. Furthermore, access to clean energy via mini grid will reduce crime and social unrest, since majority of the population would be productively engaged (Bloomberg 2020). This will lead to improved human security and cohesive communities and societies driven by mutual objective for sustainable development. HIGHFLEX will accelerate access to affordable and low carbon clean energy from bio-diesel, solar and wind (SDG 7), which lower environmental impacts from continued use of diesel-powered generators in Nigeria (world's leading generator consumer) to combat climate change effects (SDG 13).
Solar And Biogas Off-grid Power (SABOP) for Rwenjeru Agrotourism and Demonstration Farm, Mbarara, Uganda.
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
In this project, we will integrate of 2 well-established technologies (solar photovoltaic power and biomethane from biodigestion of waste biomass) to create a 24-hours' all-weather electricity supply minigrid that will tackle the colossal lack of access to energy in Uganda (particularly Rwenjeru Agrotourism and Demonstration Farm). Also, we will implement a renewable milk chiller as a productive use of energy at Rwenjeru. Furthermore, we will conduct a market analysis and develop a business plan for the viable and affordable deployment of the project outcome and for future scale-up beyond the project. Our waste-to-energy anaerobic digestion system will help to process food and agricultural waste that will otherwise pollute the environment, into clean renewable energy (24hrs) for an agrotourism business and \>1,000 farmer's household. By performing initial socio-economic appraisal, we will access the affordability of potential end-users and the viability of the SABOP energy platform. We will leverage on the intrinsic waste-to-energy approach of the SABOP system to match the affordability of Ugandans. The implementation of a smart minigrid allows us to accurately measure loading and generation capacity of SABOP and to effectively plan for expansion into neighbouring communities. We will engage with local and national stakeholders to ensure buy-in and share outcomes from the project to improve energy policy in Uganda. The use of biomethane as an alternative to gasoil is expected to improve local air quality, with regards to NOx and particulate matter. We will reduce Rwenjeru's dependence on highly polluting diesel and petrol powered electricity generators. By generating electricity with solar power instead of fossil fuels, we can dramatically reduce greenhouse gas emissions, particularly carbon dioxide (CO2). Our stakeholders and community engagement (workshops, social media, and flyers) will increase environmental awareness and prompt end-users to be more resource efficient in other parts of their daily life. Reliable electricity supply from the SABOP system will improved street and community lighting which will enhance security in Rwenjeru. By increasing the productivity and profitability through energy access, as well as providing cheaper biofertilizer to farmers (76% women), households will be able to improve the quality and quantity of food in the homes with positive impact on the general health and well-being of people.
Cotton Footprint: transitioning the carbon intensive cotton and textiles industry to renewable infrastructure through a whole supply chain approach
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
A collaboration to deliver affordable energy solutions in rural Pakistan communities who are integral to the farming and production of global cotton supplies. The Affordable Clean Energy Farm (ACE-Farm) is a novel insetting scheme that aims to redistribute capital via investments by fashion brands, textiles manufacturers and clean cotton networks to reduce the impact of their own carbon consumption. This project will continue the work delivered by UK energy management company, Pilio, and Pakistan energy infrastructure company, SAMA^Verte, under an Energy Catalyst 8 funded feasibility study. Within this continuation project, we will demonstrate the economic model that aims to bring clean and affordable energy access to Pakistan's 10m cotton workers. Our focus is on creating a multiplier effect via a range of ecosystem services, including household energy access, productive energy on industrial cotton farms (ginners) and enabling micro-enterprises to offer energy services and create new markets. Within this project Pilio will develop our technology platform, that measures the investment brands make in terms of carbon reduction and affordable energy uptake, as well as economic terms including ROI. This project will be delivered in close working partnership with WWF Pakistan and global sustainability experts, Better Cotton.
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
Advanced filters
To search for Programmes in a specific time period, please enter the start and end dates.