1. Geothermal pavements: A city-scale investigation on providing sustainable heating for the city of Cardiff, UK.
- Author
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Makasis, Nikolas, Gu, Xiaoying, Kreitmair, Monika J., Narsilio, Guillermo A., and Choudhary, Ruchi
- Subjects
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GROUND source heat pump systems , *SUSTAINABLE urban development , *PAVEMENTS , *HEAT pumps , *HEAT flux , *CARBON emissions - Abstract
Geothermal pavements can be used with ground-source heat pump systems to sustainably provide energy for heating and cooling by incorporating ground heat exchanger elements underneath pavement surfaces. This work investigates the suitability of geothermal pavements at scale, adopting the city of Cardiff, UK, as a case-study. A two-scale modelling framework, combining detailed small-scale with holistic large-scale approaches, is presented, incorporating the accuracy of the former with the continuity of the latter. The results show that between 184 kWh and 345 kWh of thermal energy per metre length of pavement can be supplied annually, depending on soil profile. Moreover, geothermal operation can reduce anthropogenic heat flux into the ground from heated basements, and its associated negative impacts, by about 390 MWh/year. A city-scale analysis using population-consistent geographic areas called LSOAs, estimates that geothermal pavements can supply about 23% of the entire city residential heat demand, or up to 75% with heat sharing between LSOAs. The suitability of geothermal pavements for larger LSOAs is highlighted, supplying up to 100% of the annual domestic heat demand. Investigating the carbon emissions of heating and cooling technologies shows potential reductions of up to 75% when replacing gas boilers and resistance heating with geothermal pavement systems. • Two-scale modelling is used to assess city-scale geothermal pavement potential. • Depending on ground conditions, 184–345 kWh annually/m road of heat can be provided. • Geothermal pavements can reduce anthropogenic heat flux into the ground by ∼ 390 MWh/a. • In low population density areas 100% residential demand can be fulfilled, overall 23%. • Replacing traditional systems can reduce carbon emission by ∼ 75%. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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