Latest news with #Gravitricity
The Herald Scotland
11-06-2025
- Business
- The Herald Scotland
Ofgem backs Scottish underground hydrogen storage project
The consortium, National Gas, has secured £500,000 from Ofgem to develop the innovative new type of underground hydrogen storage. The system, known as H2FlexiStore, has been developed by Edinburgh energy storage developer Gravitricity, and is designed to hold up to 100 tonnes of green hydrogen in purpose-built underground lined shafts. The technology can be located where required, for example as part of the National Gas network or next to large industrial users. The Ofgem funding will enable a consortium – which also includes Southern Gas Networks, Guidehouse, Edinburgh University, Energy Reform and Premtech – to design and model a working system over the next six months, ahead of a potential demonstration phase next year. Capacity comparisons. (Image: Gravitricity) The funding comes from Ofgem's Strategic Innovation Fund and follows the successful completion of a National Gas led feasibility study in 2024, which identified H2FlexiStore as the preferred technology to provide locationally flexible hydrogen storage. Once the design project is successfully completed, a third and final project phase could be secured, which would see the delivery of a technical demonstration project, supported by multi-million-pound funding from the Strategic Innovation Fund. A successful demonstrator project would validate the benefits of underground storage to the hydrogen industry and key infrastructure projects such as Project Union, which is investigating the potential to repurpose the existing gas grid for hydrogen to create a UK hydrogen backbone to connect production and storage assets to demand. Martin Wright is a co-founder of the company. (Image: Gravitricity) Martin Wright, Gravitricity co-founder and executive chairman, said: "Given the strategic need for grid scale energy storage both nationally and internationally, it is crucial that enabling hydrogen storage technologies such as H2FlexiStore are commercially mature in time to offer cost effective resilience within current and future energy systems. "This support from Ofgem, enables us to prepare both technically and commercially for the delivery of a demonstration project next year and the early commercial projects within our existing pipeline of opportunities." Kelvin Shillinglaw, innovation analyst at National Gas, said: "This project is a critical step forward in ensuring the UK's gas networks are ready for a hydrogen-powered future. "By embedding resilience with operational hydrogen storage directly into the transmission system, we can maintain operational flexibility, reduce costs for consumers, and support the decarbonisation of heat and power." Airline hails 30 million passengers through Scottish airport A major airline has hailed reaching a total of 30 million passengers through one Scottish airport since it started operating from the site.
The National
11-06-2025
- Business
- The National
Scottish underground hydrogen storage project awarded £500k
National Gas, an independent gas supplier in the UK, was awarded the funds by energy regulator Ofgem to develop the project alongside Edinburgh-based energy storage specialists Gravitricity, and could see a pilot project built as early as next year. The storage system, known as H2FlexiStore, is designed to hold up to 100 tonnes of green hydrogen in purpose-built underground shafts, and can be located anywhere it is required – for example, as part of the National Gas network, or next to large industrial sites which consume a lot of energy. Proposals for the underground hydrogen storage project (Image: Gravitricity) The funding from Ofgem will enable a consortium – which also includes Edinburgh University and Southern Gas Networks, among others – to design and model a working system over the next six months, ahead of a potential demonstration phase in 2026. The funds were awarded from Ofgem's Strategic Innovation Fund and come after a feasibility study carried out by National Gas in 2024 identified the H2FlexiStore as the preferred technology to provide hydrogen storage which can be used in any location. (Image: Peter Dibdin Photographer) Martin Wright (above), co-founder and chief executive chairman of Gravitricity, said: 'Given the strategic need for grid scale energy storage both nationally and internationally, it is crucial that enabling hydrogen storage technologies such as H2FlexiStore are commercially mature in time to offer cost effective resilience within current and future energy systems. 'This support from Ofgem, enables us to prepare both technically and commercially for the delivery of a demonstration project next year and the early commercial projects within our existing pipeline of opportunities.' READ MORE: Historic Scottish castle with 800-year history goes on sale Wright added that the technology could be of particular use in Scotland, "where there are no alternative or existing geological storage solutions". Kevin Shillinglaw, innovation analyst at National Gas, said: 'This project is a critical step forward in ensuring the UK's gas networks are ready for a hydrogen-powered future. 'By embedding resilience with operational hydrogen storage directly into the transmission system, we can maintain operational flexibility, reduce costs for consumers, and support the decarbonisation of heat and power."
Sustainability Times
10-06-2025
- Science
- Sustainability Times
'China Builds 40-Story Giants': These Gravity Batteries Could Crush Lithium's Dominance and Trigger a Global Energy Power Shift
IN A NUTSHELL 🌍 Gravity batteries offer a sustainable alternative to lithium-ion technology, utilizing the natural force of gravity for energy storage. offer a sustainable alternative to lithium-ion technology, utilizing the natural force of gravity for energy storage. 🔋 China's ambitious EVx project demonstrates the potential of gravity storage with its towering structure that lifts 24-ton blocks to store energy. ⛏️ Gravitricity in Scotland repurposes abandoned mine shafts for energy storage, providing a cost-effective solution that revitalizes local economies. 💡 Despite challenges such as high upfront costs, gravity batteries promise a resilient future, balancing renewable energy flows without reliance on rare metals. In the evolving landscape of renewable energy, the quest for efficient storage solutions is more critical than ever. As the world pivots from fossil fuels to cleaner energy sources like solar and wind, the need for innovative technologies that can stabilize power supply is paramount. Among these innovations, gravity batteries emerge as a promising alternative, leveraging the natural force of gravity to store and release energy. Unlike lithium-ion batteries, which rely on rare metals, gravity-based storage offers a cleaner, more sustainable option. This article delves into the workings of gravity batteries, their potential to revolutionize energy storage, and the pioneering projects leading this transformation. The Urgent Need for Massive Energy Storage The transition to renewable energy is reshaping global energy systems, but it comes with its challenges. Renewable sources like solar and wind are inherently intermittent, causing fluctuations in energy production. This variability can lead to significant power discrepancies, especially when natural conditions are not conducive. For instance, solar power drops when the sun sets, and wind energy diminishes when the air is still. As the adoption of electric vehicles (EVs) and AI technologies accelerates, the demand for electricity is poised to soar. These trends underscore the need for large-scale energy storage solutions that can ensure a steady supply of electricity. Traditionally, lithium-ion batteries have been the go-to solution for energy storage. However, they come with their own set of problems, including environmental and geopolitical concerns. The extraction of lithium and other rare Earth elements is resource-intensive and often harmful to the environment. Moreover, the global supply chain is heavily dependent on a few countries, with China controlling a significant portion of the market. As governments and companies seek alternatives, gravity batteries offer a compelling solution that mitigates these issues. 'China Tightens Solar Grip': Already Dominating the Market, Beijing Unveils New Tech to Cement Total Global Control How Gravity Batteries Work At the heart of gravity batteries is a simple yet powerful concept: potential energy. When a mass is lifted, energy is stored in it due to gravity. This energy can be released when the mass is allowed to fall, driving a generator or turbine to convert the kinetic energy back into electricity. Unlike chemical batteries, which degrade over time, the potential energy in gravity systems remains constant, provided the mechanical components are maintained. Historically, pumped hydroelectric systems have utilized gravity for energy storage by moving water between reservoirs at different elevations. While effective, these systems require specific geographical features and large bodies of water. In contrast, modern gravity batteries use solid masses, such as large blocks, which can be raised and lowered in various settings, offering greater flexibility and scalability. 'China Risks $117 Billion Collapse': This Scientist's Rare-Earth-Free Super Magnet Could Wreck an Entire National Industry China's Bold Initiative with EVx China is at the forefront of gravity battery innovation with its ambitious EVx project in Rudong. In collaboration with Swiss company Energy Vault, China has constructed a towering 120-meter-high structure designed to lift massive 24-ton blocks. During periods of energy surplus, these blocks are elevated, storing energy for later use. When electricity demand peaks, the blocks are lowered, and their potential energy is converted back into power. This system boasts a peak output of 25 MW and a total capacity of 100 MWh, with an impressive round-trip efficiency of over 80%. The EVx project highlights the potential of gravity storage to meet large-scale energy needs without the environmental and geopolitical challenges associated with lithium-ion batteries. By utilizing locally sourced materials for construction, China is setting a precedent for sustainable energy solutions that could be adopted worldwide. 'U.S. Caught Off Guard': France's New Nuclear Submarine With 620-Mile Missiles Triggers Panic Inside Pentagon War Rooms The Gravitricity Approach In Scotland, the startup Gravitricity is exploring a novel approach to gravity storage by utilizing abandoned mine shafts. Their pilot project at the Port of Leith successfully demonstrated the feasibility of lifting and lowering heavy weights to generate electricity. This method capitalizes on existing infrastructure, reducing the need for new construction and minimizing environmental impact. By repurposing disused mines, Gravitricity aims to provide a cost-effective and efficient energy storage solution that also revitalizes local economies. This approach is particularly well-suited to regions with a history of mining, offering a new lease on life for these sites and a stable energy source for surrounding communities. Challenges and Practical Limitations Despite their potential, gravity batteries are not a one-size-fits-all solution. For small-scale or residential applications, the physics involved makes them impractical. The significant upfront costs and the need for tall structures or deep shafts can be barriers to widespread adoption. However, for large-scale grid applications, gravity storage offers a promising alternative to traditional battery technologies. As energy demands continue to rise, finding solutions that are sustainable, efficient, and geopolitically neutral is crucial. Gravity batteries hold the promise of addressing these needs, but their success will depend on overcoming initial financial and logistical hurdles. As the energy landscape evolves, could gravity batteries become the cornerstone of a balanced and resilient energy future? Our author used artificial intelligence to enhance this article. Did you like it? 4.4/5 (23)
