Structure optimization design of ground heat exchanger by topology method to mitigate the geothermal imbalance

•Topology optimization method is proposed to design optimized structure for GHE.•The topology optimization result presents a symmetrical tree-shaped structure.•The rules of generation and evolution of optimization results are studied.•Comparisons between thermal performance of optimized GHE and conv...

Full description

Saved in:
Bibliographic Details
Published in:Applied thermal engineering 2020-04, Vol.170, p.115023, Article 115023
Main Authors: Xu, Lingling, Pu, Liang, Zhang, Shengqi, Nian, Luozhu, Li, Yanzhong
Format: Article
Language:English
Subjects:
Accumulation
Boundary conditions
Buried pipes
Design optimization
Dissipation of heat transport potential capacity
Ground heat exchanger
Heat accumulation
Heat conductivity
Heat exchangers
Heat transfer
Interference
Pipes
Serpentine
Soil temperature
Soils
Temperature
Topology optimization
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•Topology optimization method is proposed to design optimized structure for GHE.•The topology optimization result presents a symmetrical tree-shaped structure.•The rules of generation and evolution of optimization results are studied.•Comparisons between thermal performance of optimized GHE and conventional serpentine GHE are conducted. Intensive thermal interference between adjacent buried pipes and heat buildup around the surrounding soil lead to the deterioration of thermal performance of ground heat exchanger (GHE). The study aims at designing an optimized structure for GHE to accelerate releasing rate of the accumulating heat and mitigate the degree of thermal interference. In this paper, the topology optimization method is proposed to the design of highly conductive GHE and the optimization result is obtained. Moreover, the rules of generation and evolution of optimization results are studied by exploring the influences of volume fraction and different boundary conditions. Finally, a comparison study between thermal performance of optimized GHE and conventional serpentine GHE is carried out. Taking the minimum dissipation of heat transport potential capacity as the optimization objective, the topology optimization result presents a symmetrical tree-shaped structure. The tree-structure GHE yields a lower standard deviation of soil temperature and a smaller maximum soil temperature. Compared with conventional serpentine GHE, the tree-structure GHE can efficiently accelerate the releasing heat rate and improve heat transfer performance by about 25.3%, which provides a new way to design GHE to avoid heat accumulation.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2020.115023