期刊名称:Bulletin of the Institute of Heat Engineering
印刷版ISSN:2083-4187
出版年度:2018
卷号:98
期号:4
页码:345-351*
语种:English
出版社:Warsaw University of Technology
摘要:Designed for utilizing the ground-source systems for heating and cooling, the use of energy piles in commercial and residential buildings has increased exponentially especially in Europe. The heat transfer efficiency of energy piles may directly influence the energy-saving effect on buildings. Apart from the optimization of pipe laying, many other factors can also influence the heat transfer efficiency of energy piles. In this study, a new method that can increase the heat transfer efficiency of energy piles was proposed to explore the influences of adding graphite powder with high thermal conductivity to pile concrete on the heat transfer efficiency of energy piles. The thermal resistance models of energy piles in three different pipe-burying modes were constructed by combining the 2D plane method and the heat transfer mechanism of energy piles. The internal heat transfer characteristics of energy piles at different temperatures, graphite contents, and pipe-burying modes were discussed by combining the indoor thermal conductivity test of graphite-modified concrete. The external heat transfer characteristics of graphite-modified concrete energy piles were analyzed through numerical simulation analysis. Results demonstrate that the increase in graphite contents is beneficial to heat transfer in energy piles. In particular, thermal conductivity significantly increases when the graphite content exceeds 5%. The high temperature in the pipe is also conducive to the thermal conductivity of the energy pile. The thermal conductivity of the concrete samples with 8% graphite content in an environment at 40°C is 1.35 times that at 20°C. The heat transfer efficiency of the spiral coil-type energy pile is higher than those of single-U and double-U tube energy piles. The proposed method provides a certain reference for improving the heat transfer efficiency of energy piles and constructing the internal and external heat transfer models in energy piles.