A transient three-dimensional numerical solution is developed to analyze the thermal performance of thermo-active foundations used to heat and cool commercial buildings. Using laboratory testing data, the numerical solution is validated and used to carry out a sensitivity analysis to assess the most important design and operating parameters that affect the thermal performance of thermo-active foundations. It is found that the foundation depth, the shank space, the fluid flow rate, and the number of U-tube loops in each foundation pile are the main parameters that affect the thermal performance of a thermo-active foundation system. Based on the validated numerical solution, thermal response factors for a thermo-active foundation are developed, and implemented into a detailed building energy simulation program. These thermal response factors are then used to estimate the impact of installing thermo-active foundations on the total energy use of typical office buildings in representative US climates.
Issue Section:
Integrated Sustainable Equipment and Systems for Buildings
Topics:
Climate,
Computer simulation,
Concretes,
Design,
Fluids,
Heat,
Heat exchangers,
Heating and cooling,
Pipes,
Sensitivity analysis,
Soil,
Structures,
Temperature,
Transients (Dynamics),
Heat transfer,
Thermal conductivity,
Simulation analysis,
Simulation,
Boundary-value problems,
Thermal properties,
Cooling,
Energy consumption,
Fluid dynamics
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