Interaction of temperature fields in soil massif during abstraction of low-grade heat by U-shaped probes of geothermal heat pump units

D. Saponenko, O. Y. Kuleshov
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Abstract

Research in the field of alternative energy sources use is of relevance due to the limited reserves of fossil fuels, the constant cost increase and flue gas emissions generated by power plants along with fuel combustion. The use of low-grade ground energy with the help of geothermal heat pump stations makes it possible to save fossil fuel and reduce environmental pollution. Since about 50 % of the one-time capital investment is spent on the construction of ground loop, the issues on improving the efficiency of ground heat abstraction are of particular relevance. However, until now there is no unified normative technique to calculate ground probes and to create ground loops of optimal constructions. The absence of calculation methods and intelligible practical dependencies does not allow one to quantify the influence of various factors on the heat extraction process, the intensity of which varies significantly over time. The authors have applied two analytical methods in the developed mathematical model. The first one is a source-sink method adapted to the non-stationary process of heat abstraction away from the soil mass. And the second one is the superposition method which made it possible to quantify the effect of the interaction of temperature fields in the well. The mathematical model has been developed, and calculated dependences have been obtained. The authors have presented a calculation method and the results of mathematical modeling of the non-stationary process of soil heat abstraction by a vertical U-shaped geothermal probe and the internal interaction of the temperature fields of the downcomer and riser pipes. The results of the computational experiment are presented in the form of graphs. The authors have determined three key particular cases of the operation of a ground probe and formulas to define the maximum allowable increment of the temperature of the heated coolant under the condition of maximum efficient use of the heat-receiving surface applicable to various types of soil. The analysis of the obtained results makes it possible to identify the main factors affecting the heat-absorption efficiency (actual heat transfer coefficients and specific heat inflows) for each of the pipes and for the entire probe, considering the interaction of temperature fields around the downcomer and riser pipes during the heating period.
地源热泵机组u型探头抽取低品位热量过程中土体温度场的相互作用
由于化石燃料储量有限,成本不断增加,以及发电厂在燃料燃烧过程中产生的烟气排放,替代能源利用领域的研究具有重要意义。在地源热泵站的帮助下,利用低品位的地面能源,可以节省化石燃料,减少环境污染。由于约50%的一次性资金投资用于地下回环的建设,因此提高地下热提取效率的问题尤为重要。然而,目前还没有统一的规范技术来计算接地探头和创建最优结构的接地回路。由于缺乏计算方法和可理解的实际依赖关系,人们无法量化各种因素对抽热过程的影响,其强度随时间变化很大。作者在建立的数学模型中应用了两种分析方法。第一种是源汇法,适用于非平稳的土体吸热过程。第二种方法是叠加法,它可以量化井内温度场相互作用的影响。建立了数学模型,得到了计算的依赖关系。本文给出了垂直u型地热探头非平稳抽热过程的计算方法和数学建模结果,以及下升管温度场的内部相互作用。计算实验结果以图形的形式给出。作者确定了三个关键的地面探头运行的特殊情况,并确定了适用于各种类型土壤的在最有效利用受热面条件下被加热冷却剂温度的最大允许增量的公式。通过对所得结果的分析,可以确定影响每根管道和整个探头吸热效率的主要因素(实际换热系数和比热流入),同时考虑到加热期间下降管和上升管周围温度场的相互作用。
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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