This study aims at evaluating the feasibility of an installation for space heating and cooling the building of the university in the center of the city Aachen, Germany, with a 2500 m deep coaxial borehole heat exchanger (BHE). Direct heating the building in winter requires temperatures of 40°C. In summer, cooling the university building uses a climatic control adsorption unit, which requires a temperature of minimum 55°C. The drilled rocks of the 2500 m deep borehole have extremely low permeabilities and porosities less than 1%. Their thermal conductivity varies between 2.2 W/(m·K) and 8.9 W/(m·K). The high values are related to the quartzite sandstones. The maximum temperature in the borehole is 85°C at 2500 m depth, which corresponds to a mean specific heat flow of 85 mW/m2–90 mW/m2. Results indicate that for a short period, the borehole may deliver the required temperature. But after a 20-year period of operation, temperatures are too low to drive the adsorption unit for cooling. In winter, however, the borehole heat exchanger may still supply the building with sufficient heat, with temperatures varying between 25 and 55°C and a circulation flow rate of 10 m3/h at maximum.
展开▼
机译:这项研究旨在评估在德国亚琛市中心使用2500 m同轴深孔换热器(BHE)对大学建筑进行空间加热和冷却的装置的可行性。冬季直接给建筑物供暖需要40°C的温度。在夏季,为大学大楼降温时,使用了一个气候控制吸附单元,该单元的最低温度要求为55°C。 2500 m深的钻孔岩石的渗透率极低,孔隙率不到1%。它们的热导率在2.2 W /(m·K)和8.9 W /(m·K)之间变化。高值与石英岩砂岩有关。钻孔的最高温度在2500 m深度为85°C,这对应于85 mW / m2–90 mW / m2的平均比热流。结果表明,在很短的时间内,钻孔可能会达到所需的温度。但是运行20年后,温度过低,无法驱动吸附装置进行冷却。但是,在冬季,钻孔热交换器仍可为建筑物提供足够的热量,温度在25至55°C之间变化,最大循环流量为10立方米/小时。
展开▼
