Achieving Climate Control With Renewable Energy

D. Bower, M. Bielski, E. Mangan, D. Schell, K. Ghahremani, D. Gee
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Abstract

The purpose of this project was to explore the feasibility of powering a climate control system solely from a renewable energy source. The off-the-shelf cooling system components were taken from a ca. 1986 R-12 residential refrigerator and then reassembled onto a custom enclosure which was constructed to serve as the climate-controlled compartment. The enclosure design was purposefully simple: a rectangular shaped box constructed out of plywood and mounted on wheels together with a plexiglass door which was substituted for the front face. The overall design provided for enhanced mobility while also allowing for easy observation of the interior temperature via an interior-mounted, digital, commercial residential thermostat integrated into the control system. The system, nominally, is triggered by incident solar radiation; the initial set-point temperature was 21 °C. Compressor power was derived solely from renewable energy. Specifically, a pair of 100W 12V monocrystalline silicon photovoltaic solar panels was used to generate electricity which was subsequently stored in a deep-cycle battery. Under steady-state AC operation, the compressor draws approximately 2.1A. Due to system inefficiencies, the corresponding DC current draw is necessarily higher and approaches 22.3A. For a compressor duty cycle ranging from 50–100%, the current draw over a model 9 hr day would range from between 100.1–200.3 A-H. The lower limit is within the energy storage capacity for the fully-charged system, as currently designed.
利用可再生能源实现气候控制
该项目的目的是探索完全由可再生能源为气候控制系统供电的可行性。现成的冷却系统组件取自一台大约1986年的R-12家用冰箱,然后重新组装到一个定制的外壳上,作为气候控制隔间。外壳的设计非常简单:一个由胶合板制成的矩形盒子,安装在轮子上,有机玻璃门代替了前面的面板。整体设计提供了增强的机动性,同时也允许通过集成到控制系统中的内部安装的数字商业住宅恒温器轻松观察室内温度。名义上,该系统是由入射太阳辐射触发的;初始设定点温度为21℃。压缩机的动力完全来自可再生能源。具体来说,使用一对100W 12V单晶硅光伏太阳能电池板发电,随后将其存储在深循环电池中。在交流稳态运行下,压缩机的耗电约为2.1A。由于系统效率低下,相应的直流电流消耗必然更高,接近22.3A。对于压缩机占空比范围为50-100%,模型9小时每天的电流消耗范围为100.1-200.3 a - h。下限是在目前设计的完全充电系统的能量存储容量范围内。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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