Ground Source Heat Pumps are gradually spreading in Europe, as the price of fossil fuel is increasing at a fast rate. The significant reduction of emissions and the margins for economic saving achievable with this technology are strongly correlated to the long-term sustainability of the exploitation of the heat stored in the soil. The operation of a GSHP over its lifetime should be therefore modelled considering realistic conditions, and a thorough characterization of the physical properties of the soil is essential to avoid large errors of prediction. In this paper, a BHE modelling procedure with the finite-element code FEFLOW is presented. Starting from the governing equations of the heat transport in the soil around and inside the BHE, the most important parameters are individuated and the adopted program settings are explained. A sensitivity analysis is then carried on both the design parameters of the heat exchanger, in order to understand the margins of improvement of a careful design and installation, and the physical properties of the soil, with the aim of quantifying the uncertainty induced by their variability. The relative importance of each parameter is therefore assessed by comparing the statistical distributions of the fluid temperatures and estimating the energy consumption of the heat pump, and practical conclusions are drawn from these results about the site characterization, the design and the installation of a BHE.
Finite-element flow and heat transport modelling of Borehole Heat Exchangers / Casasso, Alessandro; Sethi, Rajandrea. - ELETTRONICO. - (2013), pp. 1-7. (Intervento presentato al convegno European Geothermal Congress 2013 tenutosi a Pisa nel 3-7 June 2013).
Finite-element flow and heat transport modelling of Borehole Heat Exchangers
CASASSO, ALESSANDRO;SETHI, RAJANDREA
2013
Abstract
Ground Source Heat Pumps are gradually spreading in Europe, as the price of fossil fuel is increasing at a fast rate. The significant reduction of emissions and the margins for economic saving achievable with this technology are strongly correlated to the long-term sustainability of the exploitation of the heat stored in the soil. The operation of a GSHP over its lifetime should be therefore modelled considering realistic conditions, and a thorough characterization of the physical properties of the soil is essential to avoid large errors of prediction. In this paper, a BHE modelling procedure with the finite-element code FEFLOW is presented. Starting from the governing equations of the heat transport in the soil around and inside the BHE, the most important parameters are individuated and the adopted program settings are explained. A sensitivity analysis is then carried on both the design parameters of the heat exchanger, in order to understand the margins of improvement of a careful design and installation, and the physical properties of the soil, with the aim of quantifying the uncertainty induced by their variability. The relative importance of each parameter is therefore assessed by comparing the statistical distributions of the fluid temperatures and estimating the energy consumption of the heat pump, and practical conclusions are drawn from these results about the site characterization, the design and the installation of a BHE.Pubblicazioni consigliate
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https://hdl.handle.net/11583/2508935
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