Low temperature geothermal energy: heat exchange simulation in aquifers through Modflow/MT3DMS codes

Geothermal energy and in particular low temperature re- sources, have a rising worldwide importance. Ground-Source Heat Pumps (GSHP) have been used increasingly because they are among the cleanest and most energy efficient heating and cooling systems for buildings. Simulation models can be applied for a more effective use of the subsoil for geothermal purposes. In fact they are useful tools for the design of efficient systems considering also the need to avoid abnormal temperature distributions in soil and aquifers. In the hydrogeology field MODFLOW/MT3DMS are the most widespread programs to face environmental problems and to fore- cast quantity and quality impacts on groundwater resources. Al- though MODFLOW/MT3DMS are used to represent open circuit heat pumps, they are hardly used to represent borehole heat exchang- ers (BHE). The aim of this study is to simulate BHEs through two computer codes. The first one is TRNVDSTP, coupled to TRNSYS, which is often used in GSHP design in pure conduction cases. A methodology to take groundwater flow into account was added to TRNVDSTP, but a validation is still missing. The second one is MODFLOW/MT3DMS, suitable for groundwater flow and transport models, but whose reliability in BHE simulation is today unknown. The two software have been compared in terms of predicted ex- changed energy and temperature distribution in the aquifer.

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