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邢唷> []Z欹€ 餜!bjbj80趠趠 n n 8,:[CCCCC裐覼覼覼覼覼覼赸|`Z覼!覼CC鬦jCC裐裐)SCk摆]盪8絑 [0:[閁謄謄p謄覼覼:[謄n  }: D桍N1 D崺R啒遅 Proposals should include one or more of the following research challenge areas and applicants must be able to justify why their programme of work is of importance to UK and China: Thermal Energy Management, Recovery, Storage and Use. 70% of industrial energy demand is in the form of heat, 50% of this heat is wasted as processes are inefficient. Reducing or utilising this waste heat is key to reducing carbon emissions. It was noted that current solutions are considered too expensive. The following areas were highlighted as important: Materials and systems to capture and use or release surplus heat. Energy systems that maximise heat transfer and recovery. High energy density materials; that is, materials that are capable of storing heat in high densities, as it is captured from waste heat streams. Power generation technology that utilises low grade waste heat. Heat storage management methods for short, medium and long term It is expected that research in this area would deliver: New materials and methods to store thermal energy with minimal losses. New methods for waste heat recovery and use including more efficient heat exchangers New ways to upgrade low grade heat to higher temperatures New functional materials for capturing excess environmental energy e.g. in buildings. Recycling and Remanufacturing. 3bn tonnes of waste is generated globally every year at a cost of 23Bn, and the amount and cost is increasing. Life cycle efficiency improvements can be made by recycling and remanufacturing of waste or manufacturing by-products. This area has a strong link to the circular economy which is becoming increasingly important as a research area in the UK. The following areas were identified as important: End of life process technology Intelligent manufacturing for recycle/remanufacture Reverse logistics Re-treatment of recycled wastes to increase adaptability New business models to facilitate recycling and re-manufacture Remanufacturing process optimisation Disassembly for remanufacture Design for recycle and remanufacture based on end of life technologies to improve life cycle resource efficiency It is expected that research in this area would deliver: New, energy efficient technologies and techniques Efficiency improvements in the processes and systems Enable wider recycling of things that currently cannot be recycled New business models and designs that enable recycling and remanufacture Development of internationally acceptable standards Novel Low Carbon Manufacturing Design, Production and Optimised Systems. In order to make a real impact on carbon emissions new systems are needed that will transform traditional processes to innovative low carbon processes and improve process capability. It is also key to ensure that Low carbon is designed in at the system level from the start. This will involve the quantification of existing manufacturing systems, the identification of opportunities for improvement, understanding of new systems and the development of new metrics to understand the systems. The following areas were highlighted as important: Database of knowledge and tools, and using big data to optimise energy efficiency of equipment processes and systems Novel tooling Ultra-high speed manufacturing Manufacturing with light Heat recovery Novel low carbon processes and equipment Modelling of systems optimisation Material behaviour modelling and control Development of more robust and accurate multi scale models for energy footprint in manufacture evalsuation systems that can assess the C footprint of any manufacturing process. Decision making process analysis based on integrating production management and process planning. Modelling the LCA of a process and designing low carbon LCs. Understanding how to evalsuate the system/concept design Integration of LCM tools with CAD CAE platforms Design for reconfiguration/modular design It is expected that research in this area would deliver: Demonstrators and a transferable modelling framework that can be applied globally. Lifecycle design methodology Software tools including database and knowledgebase New Processes which have been systematically designed to be low carbon Material behaviour modelling and control Low Carbon Manufacturing of Bulk Materials and Chemicals. This is an important area as the overall energy efficiency in all materials and chemical production/manufacturing is low and it is a significant CO2 emitter. Bulk materials form the foundation for all infrastructure and will continue to do so, therefore improvements in efficiency of producing those materials can have a big impact on CO2 reduction. The chemical sector currently relies almost totally on fossil fuel for its energy needs and often fossil fuels make the bulk of the raw material feedstocks. Substitution with biodegradable products and by-products can therefore offer significant pollution reduction. The following areas were highlighted as important: Need to make energy efficiency improvements in all aspects of materials and chemical manufacture in order to substantially reduce CO2 emissions, including in the manufacture of Concrete/Cement Ceramics Steel Pharmaceuticals Bulk chemicals Novel utilisation of CO2 or CO2 containing materials including the development of novel biocatalysts Utilisation of industrial waste streams and Integration of the waste cycle into the manufacturing system Methodologies to quantify the carbon intensity of a product/process Catalysis and atomic level understanding of materials and chemicals Process electrification Integrated approach to systems design including technological and empirical advances as well as systems engineering modelling. Biological resources as feedstocks. It is expected that research in this area would deliver: Strong collaboration between the UK and China in low carbon manufacturing research and development that will develop new lower carbon intensity manufacturing processes with lower embedded carbon. 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