智能型太阳能辅助 1 千瓦溴化锂蒸气吸收系统

Murari Lal, P. K. Sadhu, Soumya Das
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引用次数: 0

摘要

智能太阳能辅助 1[配方:见正文]千瓦溴化锂蒸气吸收系统是一种开创性的解决方案,它将太阳能热能与溴化锂蒸气吸收技术相结合,实现了节能制冷和供暖。这一尖端系统利用太阳能为吸收循环提供动力,提供环保且经济可行的热管理。太阳能集热器、溴化锂吸收式制冷机、热能储存装置和复杂的控制算法是该系统的主要组成部分。太阳能集热器捕捉太阳光并将其转化为热能,然后用于为溴化锂吸收式制冷机提供必要的热量。该冷却器利用吸收式制冷循环对指定区域或流程进行高效冷却或加热。如果采用智能控制算法,系统的性能和运行效率会更高。这些算法可以调节热能储存装置,优化太阳能的使用,根据需要持续可靠地提供制冷或制热。系统还内置了先进的监控和诊断功能,可进行远程控制和即时性能评估。其缺点是道德问题、缺乏通用性、可解释性和复杂性、可扩展性和处理资源以及科学协议。为克服这一问题,计划设计一种新颖的基于黑猩猩的循环模型(CbRM),用于预测蒸发管式集热器(ETC)的预期效率。智能太阳能辅助系统与传统的供热和制冷系统相比,有以下几个优点。它最大限度地减少了温室气体排放,降低了对传统能源的依赖,促进了未来的可持续发展。该系统还能利用太阳能节省资金,降低电力成本,提高能源效率。此外,建议的系统实现是在 Matlab 中完成的。该方法实现了较高的 ETC 效率,约为 0.9%,提高了 0.3%;COP 率约为 9.5%,提高了 6%;强溶液浓度水平提高了约 6.5%,提高了近 5%。建议模型中的参数与当前参数进行了对比分析,发现建议模型的呈现效率更高。
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An intelligent solar-assisted 1kW Lithium–Bromide vapor absorption system
A ground-breaking solution that combines solar thermal energy and lithium-bromide vapor absorption technology to produce energy-efficient cooling and heating is the Intelligent Solar Assist 1[Formula: see text]kW Lithium Bromide Vapor Absorption system. This cutting-edge system uses the sun’s energy to power the absorption cycle, offering environmentally friendly and economically viable thermal management. Solar thermal collectors, a lithium bromide absorption chiller, a thermal energy storage device, and sophisticated control algorithms comprise the system’s main parts. Sunlight is captured and converted by solar thermal collectors into thermal energy, which is then used to produce the necessary heat for the lithium bromide absorption chiller. This chiller uses the absorption refrigeration cycle to efficiently cool or heat the specified area or process. When intelligent control algorithms are incorporated, the system performs and operates more effectively and efficiently. These algorithms regulate the thermal energy storage unit and optimize the use of solar energy, delivering a constant and dependable supply of cooling or heating as needed. Advanced monitoring and diagnostics features are also built into the system, allowing for remote control and in-the-moment performance evaluation. Disadvantages are ethical issues, lack of generalization, interpretability and complexity, scalability and processing resources, and scientific agreement. A novel Chimp-based recurrent model (CbRM) has been planned to be designed to predict the desired efficiency from the Evacuated Tube Collector (ETC) to overcome this issue. Comparing the Intelligent Solar Assist system to conventional heating and cooling systems, several benefits must be had. It minimizes greenhouse gas emissions, lessens reliance on traditional energy sources, and promotes a more sustainable future. The system also saves money using solar energy, lowering power costs and enhancing energy efficiency. Moreover, the proposed system implementation is done in Matlab. The method achieves the high efficiency of ETC in the range of about 0.9% which increases by 0.3% and the higher rate of COP was about 9.5% which increases up to 6%, as the increased concentration level of the strong solution was about 6.5% it was nearly 5% increase. The parameters in the suggested model were compared to the current parameters for the comparison analysis, and it was discovered that the proposed model had superior presenting efficiency.
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