Novel Manufacturing for Resource Efficient Electrochemical Storage (NoRESt)

资源高效电化学存储的新型制造（NoRESt）

• 批准号: EP/S03711X/1
• 负责人: Jenny Baker
• 金额: $ 139.07万
• 依托单位: Swansea University
• 依托单位国家: 英国
• 项目类别: Fellowship
• 财政年份: 2019
• 资助国家: 英国
• 起止时间: 2019 至 无数据
• 项目状态: 未结题
• 来源: https://gtr.ukri.org/projects?ref=EP%2FS03711X%2F1
• 关键词: Novel; Manufacturing; Resource; Efficient; Electrochemical

With an increasing level of renewable electricity generation there is a requirement for electro-chemical storage incorporated into the grid to minimise costs and decrease the amount of fossil fuels needed to balance electricity supply and demand. Currently lithium ion batteries, which have been designed for portable applications have not been optimised for fixed applications where weight and density of the battery are not as critical as cost effective storage.The NoRESt fellowship is based at Swansea University leading a team working on new manufacturing processes for energy storage applications, within the Materials Engineering department. Swansea University is undertaking internationally leading research within the field of processing of materials for energy application through the SPECIFIC IKC. The NoRESt fellowship will develop novel processing methods for the production of solid state batteries, for the application of fixed energy storage, to improve their energy storage performance by reducing inter-facial resistances. This will be achieved by developing active solid electrolyte pastes which can be printed and co-sintered onto the battery anodes. Prior efforts in this field have primarily focused on new chemistry for the active battery components rather than processing methods. By combining new chemistry with novel processing this fellowship will take advantage of advances in the field of solid state printed photovoltaics and apply them to the field of electro-chemical storage.Solid state sodium batteries will have the following advantages over liquid lithium ion batteries: - Lower cost - No cobalt or lithium used in manufacture - reducing reliance on single production locations- Reduced environmental impact of the battery production.- Lower recycling costs - Reduced fire risks (during waste processing and in use)By supporting a greater proportion of renewable electricity generations fixed storage batteries will reduce energy costs and help to meet the UK targets for limiting the catastrophic affects of climate change. This research will support complementary research in battery chemistry by providing an alternative architecture and method of manufacture. The environmental cost of production will also be analysed during this fellowship, ensuring that energy storage is developed with the smallest environmental footprint possible, with materials and processes with high environmental impact highlighted for further research to develop alternatives. Alongside materials manufacture and processing end of life will be considered in order to understand and mitigate early in the development process the impacts of end of life.Alongside developing novel processing methods the environmental, cost and performances of these batteries will be bench-marked against current (lithium ion) and other emerging technologies (salt-water batteries, flow cells and modern NiFe). Demonstrators will be manufactured before the end of the fellowship and be tested within zero carbon buildings built as part of the SPECFIC IKC project, this will accelerate the commercialisation of this project.

随着可再生能源发电水平的不断提高，需要将电化学存储纳入电网，以最大限度地降低成本并减少平衡电力供需所需的化石燃料量。目前，锂离子电池，这已经被设计用于便携式应用还没有被优化为固定的应用程序，其中电池的重量和密度是不作为关键的成本效益存储。NoRESt奖学金是总部设在斯旺西大学领导一个团队工作的新的制造工艺的能量存储应用，在材料工程系。斯旺西大学正在通过特定IKC进行能源应用材料加工领域的国际领先研究。NoRESt奖学金将为固态电池的生产开发新的加工方法，用于固定储能，通过降低界面电阻来提高其储能性能。这将通过开发可以印刷和共烧结到电池阳极上的活性固体电解质浆料来实现。该领域的先前努力主要集中在用于活性电池组件的新化学物质上，而不是处理方法。通过将新化学与新工艺相结合，该奖学金将利用固态印刷光致发光领域的进展，并将其应用于电化学存储领域。固态钠电池将比液体锂离子电池具有以下优势：- 更低的成本-在制造中不使用钴或锂-减少对单一生产地点的依赖-减少电池生产对环境的影响。降低回收成本-降低火灾风险（在废物处理和使用过程中）通过支持更大比例的可再生发电，固定蓄电池将降低能源成本，并有助于实现英国限制气候变化灾难性影响的目标。这项研究将通过提供替代架构和制造方法来支持电池化学的补充研究。在该奖学金期间还将分析生产的环境成本，确保以尽可能小的环境足迹开发能源存储，并强调对环境影响大的材料和工艺，以进一步研究开发替代品。除了材料制造和加工外，还将考虑寿命终止，以便在开发过程的早期了解和减轻寿命终止的影响。除了开发新的加工方法外，这些电池的环境，成本和性能将以当前（锂离子）和其他新兴技术（盐水电池，液流电池和现代镍铁）为基准。示范板将在奖学金结束前制造，并在作为SPECFIC IKC项目一部分建造的零碳建筑内进行测试，这将加速该项目的商业化。

项目成果

Life cycle assessment of soluble lead redox flow battery

• DOI: 10.1016/j.jclepro.2022.130503
• 发表时间: 2022-01
• 期刊: Journal of Cleaner Production
• 影响因子: 11.1
• 作者: E. Shittu;Rathod Suman;M. Ravikumar;A. Shukla;Guangling Zhao;Satish Patil;Jenny Baker

Comparative Study of Radiative Heating Techniques for Fast Processing of Functional Coatings for Sustainable Energy Applications Applications of radiative mechanisms in solar energy, battery storage and fuel cells

可持续能源应用功能涂层快速加工的辐射加热技术比较研究辐射机制在太阳能、电池存储和燃料电池中的应用

• DOI: 10.1595/205651322x16260797478755
• 发表时间: 2022
• 期刊: Johnson Matthey Technology Review
• 影响因子: 2.3
• 作者: Griffin R

Process-Structure-Formulation Interactions for Enhanced Sodium Ion Battery Development: A Review.

• DOI: 10.1002/cphc.202100860
• 发表时间: 2022-03-04
• 期刊: CHEMPHYSCHEM
• 影响因子: 2.9
• 作者: Sawhney, M. Anne;Wahid, Malik;Muhkerjee, Santanu;Griffin, Rebecca;Roberts, Alexander;Ogale, Satishchandra;Baker, Jenny
• 通讯作者: Baker, Jenny

Environmental Analysis of Integrating Photovoltaics and Energy Storage in Building

• DOI: 10.1016/j.procir.2022.02.102
• 发表时间: 2022
• 期刊: Procedia CIRP
• 作者: Guangling Zhao;J. Searle;Joanna Clarke;M. Roberts;S. Allen;Jenny Baker

Economic analysis of integrating photovoltaics and battery energy storage system in an office building

• DOI: 10.1016/j.enbuild.2023.112885
• 发表时间: 2023-02
• 期刊: Energy and Buildings
• 影响因子: 6.7
• 作者: Guangling Zhao;Joanna Clarke;J. Searle;Richard P. Lewis;Jenny Baker