Experimental validation of a numerical code by thin film heat flux sensors for the resolution of thermal bridges in dynamic conditions

Thermal bridges are areas of risk of the building envelope, inducing uncontrolled increments of heat transfer, mainly in winter. This notwithstanding, thermal bridges are often neglected in energy audits, since many numerical codes for building energy simulations adopt heat transfer models based on onedimensional heat flux: this can cause lack of reliability. This paper validates a numerical model, written in MatLab™, which solves thermal bridges – under bidimensional heat transfer conditions – in transient regime. More in detail, the model – developed by the same authors – allows estimation of thermal bridge effects under dynamic conditions (hourly and subhourly). The model is validated through a comparison with experimental data, measured by means of a proper apparatus, consisting in a set of heat flow meters, thin flux sensors, temperature probes, infrared thermographic camera. A typical L-shaped thermal bridge has been investigated and the numerical methodology – compared to the experimental study – reveals very satisfactory results in reliability and accuracy. The percentage gap between calculated and measured heat fluxes varies between 12% and +6%, with an average value close to zero. A satisfactory agreement has been evaluated also with reference to the thermal power through the investigated envelope element.