An application of seasonal borehole thermal energy system in Finland

Borehole thermal energy system is an important component of the future low temperature heating networks. Applications of such systems are available around the world presenting various configurations. However, the mobility of the system from solar assisted to industrial heat has not yet evaluated. A...

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Bibliographic Details
Published in:Cleaner Engineering and Technology
Main Authors: Hafiz Haq, Petri Välisuo, Lucio Mesquita, Lauri Kumpulainen, Seppo Niemi
Format: Article in Journal/Newspaper
Language:English
Published: Elsevier 2021
Subjects:
borehole Thermal energy storage
4G district heating system
3D model of ground heat storage
Artificial neural network model
Low temperature heating network
Renewable energy sources
TJ807-830
Environmental engineering
TA170-171
Sodankylä
Online Access:https://doi.org/10.1016/j.clet.2021.100048
https://doaj.org/article/f3bbd148714f41db83b956838a4be909
Description
Summary:Borehole thermal energy system is an important component of the future low temperature heating networks. Applications of such systems are available around the world presenting various configurations. However, the mobility of the system from solar assisted to industrial heat has not yet evaluated. A 3D model of borehole thermal energy system created similar to Drake landing solar community project configuration. This model is validated with experimental measurements. The accuracy of the model estimated at 95%. Experimental measurements further utilized to create an artificial neural network model to predict modes of operation (charging/discharging). The accuracy of the model calculated at 97%. This study presents a possible application of storing excess heat from combined heat and power plants in Sodankylä, Finland. The municipality of Sodankylä is planning construction of new combined heat and power plants. These plants systematically shutdown during summer season leaving 1.53 MW of excess heat. The heat surplus can be stored in a heat storage. Simulations reveal that the model has storage capacity between 250 kW and 285 kW. In addition, there is a potential of five borehole thermal energy storage to store the entire excess heat. The novelty of the study is to test the mobility of borehole thermal energy system from solar assisted storage to industrial excess heat storage. The model used in a standardized manner considering the conventional combined heat and power plants supply temperature for working configuration of heat storage.

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