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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.
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.
GoHubs Mozambique Green Fishing and Cold Chain Hubs
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
GoHubs Mozambique is a transformative network of solar-battery microgrid hubs serving the artisanal fishing sector in coastal communities of Mozambique. The primary objective of GoHubs is to provide smart reliable renewable energy solutions, infrastructure and equipment to unlock market access, reduce fish losses, and bolster the local fishing sector. The artisanal fishing industry plays a crucial role in Mozambique, accounting for 90% of the total catch and with over 15% of households depending on it for their livelihoods. However, inadequate energy and transport infrastructure in coastal areas restrict the availability of resources such as ice, cold storage, and access to non-local markets. These limitations lead to significant fish losses and reduced incomes within the sector. To address these challenges and create new opportunities, GoHubs introduces a pioneering business model that combines significant technological and commercial innovations. From a technical perspective, GoHubs integrates energy-intensive operations like ice production, cold storage, water pumping, and electric refrigerated transport into an integrated hub, powered by an on-site solar-battery microgrid. Smart control and load management system, ensures a reliable and efficient power supply and optimises across the critical loads. The entire systems is also integrated onto a single monitoring platform to simplify operations. From a commercial standpoint, this bundling approach ensures that a continuous reliable cold chain from boat to market is effectively and sustainably established. Furthermore, this strategy facilitates economies of scale, resulting in lower unit costs for ice and services. GoHubs not only sells ice and cold storage services but also supports the trading of local fish, providing electric refrigerated transport to larger markets. The business model also enhances resilience by diversifying revenue streams, and by including electric vehicle charging reduces the impact of volatile fossil fuel costs on transportation. By providing ice and services instead of selling energy units, GoHubs mitigates the uncertainty associated with the current regulatory environment. GoHubs is a pilot deployment in Inhambane Province on a public-private partnership model with a community fish market. GoHubs expects to improve the livelihoods of the fishing sector workers and the broader community through improved catch quality, better and reliable market access, and reduced losses and wastage and replicate the model across Mozambique and other countries where renewable and reliable cold chain can unlock green growth.
Energy Innovation for Reducing Post Harvest Loss
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
The project uses patented heat recovery and airflow technology, coupled with solar thermal technology for agri-processing in Kenya. Working with producers and processors in value chains such as Moringa and mango - the project will deliver value for smallholder farmers by reducing post-harvest losses that occur when products are spoiled before they can reach the market. The project will demonstrate the effectiveness of solar-thermal drying for Moringa processing by designing, building and commissioning a high capacity dryer able to operate 24/7 powered entirely by renewable energy at a Moringa facility that serves 500 farmers. The solar thermal system has considerable benefits in comparison to existing technology - including faster drying, the delivery of a constant temperature that can be remotely monitored; lower cost and ease of installation. This will facilitate the production of higher-quality products that meet the quality requirements of international buyers looking to expand supply chains in the East-African region. Besides this, the project will carry out capacity building and training, including practical demonstrations of the solar thermal drying systems to increase awareness of the potential for renewable energy to deliver economic and social benefits in agricultural value chains.
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.
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.
Powering the Future: Revolutionising Access and Efficiency through Integrated and Sustainable Energy Solutions
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
SureChill and GreenPower Overseas Ltd are leading companies in the off-grid refrigeration and power solutions markets, respectively. SureChill specializes in providing affordable refrigeration solutions using revolutionary technology that ensures consistent cooling even without electricity, while GreenPower focuses on delivering cutting-edge power and energy solutions. Under the joint initiative titled "Powering the Future: Revolutionizing Access and Efficiency through Integrated and Sustainable Energy Solutions," we are dedicated to empowering underserved communities with reliable, clean, and affordable cooling and lighting solutions. Our shared objective is to create transformative impact, stimulate economic growth, foster sustainability, and ultimately create a future that is inclusive for all. In Nigeria, communities in underserved regions in the country face significant challenges in accessing cooling and lighting solutions. World Bank reports from 2020 reveal that in Nigeria, the electrification rate stood at approximately 57%, leaving over 85 million individuals without dependable access to grid electricity. Consequently, these individuals resort to alternative options like generators and other unconventional power sources. This reliance on alternative means underscores the considerable proportion of people who lack access to essential services such as lighting, cooling, phone charging, television, and fans. We recognize these barriers and have developed two innovative solutions to address them. Solution v1 combines the SureChill SDD fridge energy harvesting system with a Solar Home System (SHS), optimizing energy utilization and ensuring reliable access to electricity. This solution diverts excess energy for later use, providing power to essential appliances and improving the quality of life for businesses and communities. Building on the success of solution v1, solution v2 takes energy access and management to the next level. By integrating the energy harvesting system, remote controller, and a unique payment model into an Energy Management System Control Hub, users gain real-time control over their energy consumption, remote access to appliances, and flexible payment options tailored to their specific needs. To achieve our objectives, we will conduct rigorous testing and validation of solution v1 while simultaneously investing in intense research and development for solution v2. By piloting both solutions, we will test the efficiency and effectiveness of the solutions in diverse communities, paving the way for seamless integration. By funding the collaboration between SureChill and GreenPower, Innovate UK will support in creating a future where underserved communities will be empowered, new economic opportunities will be unlocked, and a sustainable and inclusive society for all will be fostered.
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.
Islanded Wave Powered Microgrid Pilot for Remote Islands in Thailand
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
This project is a building on and adding to our successful Energy Catalyst R8 early-stage project, demonstrating good feasibility of the proposed concepts in enhancing the efficiency of onshore wave energy converters (WECs) and developing advanced wave-powered microgrids (WPMG) in the selected remote islands of Thailand with limited or no grid access which currently use expensive, polluting diesel generators (DEGs) as the main supply. The unit cost of the electricity generated by WPMGs can be significantly reduced by advanced predictive optimal control strategies to improve the wave power output of the WECs in a range of sea states with state-of-the-art power electronic components and novel microgrid energy management systems (EMS). The EMS can significantly reduce the power conversion/distribution losses and use deep-learning-based algorithms to forecast the stochastic loads in varying weather and wave conditions. Moreover, the microgrid provides a reliable and secure source of electricity using distributed and remote EMS services. In this mid-stage project, we aim to systematically demonstrate the efficacies of the whole concept to pave the way for sea-trial testing validation at the final stage. The consortia will integrate all the key components into one hybrid system-level wave-to-wire (W2W) WPMG simulator to validate the functionalities of the microgrid efficiently and economically in various scenarios close to real sea conditions. The wave prediction will be enabled by the latest Radar-based technology to provide shutdown signals for detrimental waves and to increase the survivability of the WECs. We aim to increase the technology readiness level (TRL) of the proposed WPMG technologies to build up a stand-alone microgrid in the final stage. Overall, the project aims to provide inclusive community-based renewable energy (sensitive to gender equality and social inclusiveness) that addresses the lack of energy access in Thailand's remote and isolated islands and eventually in other SE Asia countries like the Philippines and Indonesia. The project consortia include key industrial players, including Aquatera, Hitachi Energy, Toshiba, EcoWavePower, and major universities QMUL, Manchester & Exeter, for successfully delivering the project objectives. Following our successful workshops in the early-stage project, we will hold further technical and training workshops for the technology transfer in the SE Asia region, especially for female professionals, to promote gender equality in the renewable energy sector.
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.
ACE DELIVERS: Distribution of Energy to the Last-Mile through an Inclusive Value-Chain Ensuring Responsible Services
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
African Clean Energy (ACE), in collaboration with The Challenges Group, seek to establish a scalable, decentralised and digitised distribution model for transitioning households from harmful charcoal usage to sustainable local fuel options. ACE has demonstrable demand for its sustainable briquettes, however, the existing method of ordering and delivering fuels through local agents becomes impractical and unsustainable as ACE expands its geographical market penetration. This project will demonstrate the advantages of developing an inclusive approach to reconfiguring and incentivising Uganda's current physical infrastructure -- including local retailers serving as satellite suppliers, and motorcycle riders -- to promote efficient and cost effective decentralised last-mile delivery. By then overlaying this infrastructure with a digital framework, the approach will enhance access to affordable sustainable cooking options. This will, in large part, be accomplished by further enhancing ACE's proprietary app, ACE Connect. The project's innovativeness revolves around the following three components: 1. Digital Technology: Inspired by companies like Jumia Foods, ACE will utilise digital technology to engage and incentivise decentralised distribution value chain players and drive the transition to sustainable energy. 2. Hybrid Finance Model: ACE will implement a hybrid finance model that utilizes measured carbon offset revenue and scalable digital systems. By utilising digital tools to measure, collect, and monetise impact data, the project aims to disrupt existing practices by introducing positive incentives and commercial operations that consider both the "ability to pay" of end consumers and the "willingness to pay" of Carbon Offset Buyers.This approach aims to alleviate the financial burden on the poorest households while ensuring their active engagement in the project. 3. Value Chain Replication: The project will ensure replication the innovative decentralised and digitised value chain approach in different contexts (including humanitarian, development and conservation) through partnerships with third parties. This strategy enables scalability and financial viability in multiple locations, promoting sustainable growth. Given 92% of energy consumed in Uganda comes from biomass, primarily charcoal, used for home cooking, this project is extremely timely. Uganda has experienced a significant loss in tree cover due to charcoal production, prompting recent executive orders to ban charcoal production in Northern Uganda. ACE's responsible approach to catalysing a just transition from the charcoal value chain will have a lasting impact on affordable, reliable and low carbon energy access in sub-Saharan Africa and beyond.
Energy Intelligence: smart insights for affordable clean energy
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
enee.io increases access to reliable and affordable energy by improving the life and efficiency of energy systems. Through plug-and-play sensors, mobile phone applications and web-based reporting, enee.io provides customers with the information they need to optimize energy usage, improve energy system health and safeguard backup power supplies. We focus on helping people in developing countries who pay disproportionately high amounts for energy and suffering from pollution caused by diesel generators. enee.io is the fitness tracker for energy systems The enee.io product is a low-cost plug-and-play intelligent energy monitoring system (iEMS). The iEMS consists of simple proprietary IoT sensors that are installed on each source of energy generation (solar, grid and diesel generators), storage (batteries) and consumption (residential or commercial & industrial premises). The collected data from the sensors is transmitted to the enee.io cloud based servers where data analysis is provided through our proprietary algorithms. Alerts, insights, and energy performance information is provided through our mobile and web applications. The EC10 project will incorporate AI into our platform to combine data to allow users to fully optimise their energy system. These include how to increase energy availability and resilience; identification of maintenance required to extend asset life and improve performance and total energy cost analysis. The iEMS is affordable and simple to use, representing a quantum leap as a data-driven enabler for households and businesses. We estimate savings of $1900 over 5 years for an $160 investment. The iEMS will increase access for millions of people, to reliable, affordable, and clean energy by providing users with the information they need to optimise their energy system. Allowing them to 'right size' their energy assets and minimise operational costs. Ultimately reducing the reliance on costly and highly polluting diesel generators. There are no other products available on the market that provide this combination of low-cost and cutting-edge technology
Piloting Basic Solar Energy Grants for Equitable Access to Energy
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
Like many emerging markets, South Africa has a fast-growing urban population, resulting in the proliferation of informal settlements on land often unsuitable for grid electrification. Nevertheless, under South African law, municipalities have a legal obligation to provide basic services, including energy, to all households but prioritising the poor. While existing national policies do allow for alternative (off-grid) energy services, these policies were not initially intended for urban informal settlements and are thus not fit for that demographic. A number of municipalities are thus exploring how to develop their own policies to meet this need. For example, the City of Cape Town is considering implementing a grant for eligible low-income households that do not have grid electricity. The monthly grant could be put toward an energy service of each household's choice. An advantage of such a grant is that it would provide affordable and varied options for consumers, and would stimulate innovation and competition amongst potential service-providers. Before implementing such a policy the city is seeking evidence to help establish an optimal grant-value that ensures a high level of inclusivity. iShack and Zonke Energy have been providing off-grid solar energy services (via Solar Home Systems and Solar-Towers, respectively) for a number of years in various informal settlements around Cape Town. They have tested a range of financial and operating models, and have shown conclusively that for the South African informal settlement context, private enterprise alone cannot fill the gap of energy access due to a lack of affordability. Thus, some form of state support is needed. In this project a Basic Energy Grant (funded by Energy Catalyst Round 10) will be implemented in one large community in order to demonstrate its effect on inclusivity, as well as build the case for viable business models. iShack and Zonke will collaborate to provide a choice of basic solar energy services. The project will run for two years, during which each participating household will have the benefit of the grant, which they can use towards the purchase of a Solar Home System or access to Solar-Tower electricity. A programmatic community engagement element will support a co-productive relationship with the community as well as promote energy democracy and capacity building, gender equality and inclusivity. Progress and outcomes will be monitored by Future Advisory Ltd who will conduct communications to disseminate the results of the pilot to relevant stakeholders, in particular to municipalities.
UNIQUE STEAM TO POWER GENERATOR SYSTEMS FOR DECENTRALISED THERMAL PLANTS AND SMALL WASTE INCINERATORS
DEPARTMENT FOR SCIENCE, INNOVATION AND TECHNOLOGY
Nigeria and other ODA countries have limited and unreliable grid electricity supply which limits industrial growth and productivity. As a result of power intermittency and being offgrid, many industries are reliant on highly polluting costly diesel generators. Heliex Power manufactures a unique energy recovery technology based on twin-screw steam turbine, which is easy to retrofit, install and operate in industrial applications that produce waste heat. Saturated wet steam is common in these thermal processes, and industries benefit from a Heliex TST unit as its innovative expander technology is unique in working with saturated wet steam to generate power. Current version of Heliex has sold over 85 units across Europe, but requires reliable grid connectivity to operate, and so is unsuitable for ODA countries. The aim of this project is develop the electrical and control systems to allow offgrid/decentralised operation. Project developments include modifications to the electrical part of the unit, its control to the new system requirements, modifying steam components as identified during an engineering review, plus testing and certification of the equipment. The solution offers an alternative to replace or reduce the power generated from diesel generators by industry with clean power generated by the Heliex unit. This cost-effective solution will also make it affordable for industrial customers to run their factories, especially with the removal of government diesel subsidies in Nigeria. Long term, Heliex with our local distributor in Nigeria, and in other ODA countries will further promote the installation of our equipment in industry significantly reducing carbon emissions.
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