Projects
Projects: Projects for Investigator |
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| Reference Number | NE/H013903/1 | |
| Title | MULTISCALE SYSTEMS MODELLING FOR CCS ANALYSIS AND OPTIMISATION | |
| Status | Completed | |
| Energy Categories | Fossil Fuels: Oil Gas and Coal(CO2 Capture and Storage, CO2 storage) 34%; Fossil Fuels: Oil Gas and Coal(CO2 Capture and Storage, CO2 capture/separation) 66%; |
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| Research Types | Basic and strategic applied research 100% | |
| Science and Technology Fields | SOCIAL SCIENCES (Economics and Econometrics) 30%; SOCIAL SCIENCES (Business and Management Studies) 35%; SOCIAL SCIENCES (Politics and International Studies) 35%; |
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| UKERC Cross Cutting Characterisation | Systems Analysis related to energy R&D 100% | |
| Principal Investigator |
Prof J (Jim ) Watson No email address given Bartlett Sch of Env, Energy & Resources University College London |
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| Award Type | 1 | |
| Funding Source | NERC | |
| Start Date | 01 June 2010 | |
| End Date | 31 May 2013 | |
| Duration | 36 months | |
| Total Grant Value | £196,391 | |
| Industrial Sectors | Transport Systems and Vehicles | |
| Region | London | |
| Programme | ||
| Investigators | Principal Investigator | Prof J (Jim ) Watson , Bartlett Sch of Env, Energy & Resources, University College London (100.000%) |
| Web Site | ||
| Objectives | The principal aims of the project are to develop a systems modelling framework relevant to CCS and apply this to perform a range of analyses which quantify a series of environmental, economic and safety-related metrics. This is broken down into a number of grouped objectives: 1) Methodology development: a. Development of a multiscale modelling approach to develop and link fit-for-purpose component models such as those relating to power generation, CO2 capture, transport, injection and storage. b. Using aggregations of the integrated model to develop a network design model which supports time-phased development, designing optimal CO2 infrastructure networks that join sources and sinks. c. Development of quantitative performance measures of long-term system performance, including integrated life-cycle based environmental assessments based on a variety of criteria that evaluate whole-chain risks, limitations and impacts and economic evaluation. d. Development and use of dynamic (transient) models of the network and its substructures to assess its performance under transient conditions and evaluate its operability, controllability and safety characteristics. 2) Data acquisition and validation of methodology developed: a. Identification of major current and proposed CO2 point sources in a region (the Forth of Firth region is proposed in agreement and collaboration with Scottish Power), taking into account the evolution of the energy and other CO2 intensive industries. b. Identification of potential CO2 capture technologies for typical UK sources; quantifying the key economic and environmental parameters of the technologies chosen. c. Exploiting information made available by research partners, collaborating industry and parallel research programmes, identification of potential CO2 sinks in the region and quantifying the economic and environmental parameters of the storage options selected. 3) Application of the methodology to a UK system and generation of a wide range of whole-system results and insights: a. The details of the time-phased evolution of the whole system design, including systems integration issues and insights. b. Integrated assessment of proposed designs, quantifying economics, technological risk and long-term environmental performance against a number of metrics including lifecycle GHG emissions and a variety of other impact measures (e.g. acidification, human toxicity). c. Identify and quantify issues and opportunities (e.g. provision of flexible generation) at the interface between the UK's evolving energy system and the CCS infrastructure. d. Characterise and quantify the transient performance of the systemand undertake safety, operability and risk analyses. |
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| Abstract | The UK has challenging GHG reduction targets. It is believed that carbon capture and storage (CCS) will play a critical role in the energy systems of the future, in part to support the decarbonisation objective and in part to provide grid flexibility in a future system including a large fraction ofless responsive low carbon energy systems (e.g. nuclear baseload and intermittent wind). The whole systems modelling and analysis programme proposed here is designed to support wider UK initiatives by reducing technological risk and identifying performance bottlenecks. CCS will require substantial capital investment in capture and transport systems and storage complex management. Although elements of the whole chain have been studied through modelling and experimentation, there is little work on whole system assessment. For complex systems such as CCS, whole system assessment is vital ahead of large scale deployment as it identifies critical integration and interaction issues between the components and evaluates whole system performance as a function of component design parameters. Thus the whole system may be optimised; simply optimising the design of individual components is likely to result in a sub-optimal system design. The proposed research methodology is based on multiscale modelling. This involves the development of fit-for-purpose models of the individual components which describe phenomena that operate over different length and time scales and which support integration and data exchange across scales. The reason for this is that relatively localised phenomena (e.g. mass transfer in an amine scrubber) might affect the overall system transient response by limiting the rate at which the power plant flue gas flowrate can be turned up or down. Similarly, theimportant performance trade-offs in individual component designs must be characterised and used for overall system design. There are a number of important issues to be resolved regarding future CCS systems; the applicants believe that multiscale systems modelling approach is ideal to develop relevant insights and guidance. Examples of the issues to be addressed through whole systems modelling, analysis and optimisation include: - The development and application of a methodology to optimise the time-phased evolution of the whole CCS system design (incorporating its important individualcomponents), including sources to recruit and location of storage sites, balancing long-term and short-term investment imperatives. - Performing integrated assessments of alternative CCS systems, through the application of fit-for-purpose models (e.g. those able to quantify trace emissions of harmful substances) and rigorous life-cycle based analyses. - Characterising the transient performance of the integrated system (how will it perform in actual operation?), understanding whether or not it affects the flexibility of the wider energy system with which it is interfaced, what the safety critical components are and the network's dynamic stability and operability bottlenecks - Understand issues of systems integration - how do the different phenomena associated with the different components in the system cause effects to propagate through the network (e.g. the effect of impurities incaptured CO2, the transport network and the storage complex). What are the important considerations that must be taken into consideration when designing and operating the whole system? The outcome of the programme will be relevant to a very wide range of stakeholders interested in CCS, includingindustry, regulatory and policy agencies and academia. The most important contributions of the project will be: - making available methodologies to design and analyse future CCS systems - generating insights into the most important interactions involved in system design and operation - quantifying (economics, environmental impact, safety & operability) the performance of UK CCS systems |
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| Publications | (none) |
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| Final Report | (none) |
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| Added to Database | 22/03/11 | |
