远程河流能源系统:一个开源的低维护涡轮设计的偏远地区

IF 1 4区工程技术 Q4 ENERGY & FUELS

Proceedings of the Institution of Civil Engineers-Energy Pub Date : 2022-01-04 DOI:10.1680/jener.21.00101

I. Masters, J. Bird, Benjamin Birch, Maximilian Reader, W. Turner, Tom Holland, Thomas Lake, A. Williams

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引用次数: 1

摘要

轴流水力涡轮机将流动流体的动能转化为电能，并且可以设计用于在广泛的位置部署。作为相对较新的技术，这些设计通常成本高，复杂，需要专业的维护和材料。这对发展中国家的许多社区来说是不可行的，这些社区随后可能继续依赖化石燃料。设计了一个远程河流能源系统，使用最小的设备建造和维护，组件可以很容易地获得。设计评审和反馈阶段采用了正式的设计流程;设计工具包括Simulink建模、FEA、CFD、节点分析和水槽测试。只有涡轮叶片等少数部件需要专业加工和维护。研究结果表明，理论上可以生产和维护一台输出功率为3kW的高效水轮机，而无需过度依赖专门的组件和工具，从而生产出一种经济上更可行的水轮机，供发展中国家使用。设计图纸的开源分发将促进其他利益相关者对设计的应用和改进。这里提出的设计研究是一个原型技术试验的平台，以进一步发展这个概念。

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Remote River Energy System: An open source low maintenance turbine design for remote areas

Axial flow hydro-kinetic turbines convert the kinetic energy of a flowing fluid into electrical energy, and can be designed for deployment in a wide range of locations. As relatively recent technology, these designs are often high in cost, complex, and require specialist maintenance and materials. This is not viable for many communities in developing countries, which may subsequently remain reliant on fossil fuels. A remote river energy system has been designed to be built and maintained using minimal equipment, with components that can be readily obtained. A formal design process has been used with design review and feedback stages; design tools included Simulink modelling, FEA, CFD, nodal analysis and flume testing. Only a handful of components such as the turbine blades require specialist machining and maintenance. The results demonstrate how an effective water turbine with a 3kW output can be theoretically produced and maintained without an over-reliance on specialised components and tools, thereby producing a more economically viable water turbine for use in developing countries. Open source distribution of the design drawings will facilitate application of the design and improvements by other stakeholders. The design study presented here is a platform for prototype technology trials to further develop the concept.

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来源期刊

Proceedings of the Institution of Civil Engineers-Energy ENERGY & FUELS-

CiteScore

3.00

自引率

18.20%

发文量

期刊介绍： Energy addresses the challenges of energy engineering in the 21st century. The journal publishes groundbreaking papers on energy provision by leading figures in industry and academia and provides a unique forum for discussion on everything from underground coal gasification to the practical implications of biofuels. The journal is a key resource for engineers and researchers working to meet the challenges of energy engineering. Topics addressed include: development of sustainable energy policy, energy efficiency in buildings, infrastructure and transport systems, renewable energy sources, operation and decommissioning of projects, and energy conservation.