Full-scale assessment of a liquid CsWO3-SnO2 near-infrared shielding coating and a nanoceramic WO3 photochromic window film for in-situ window retrofits

•Evaluation of two low-cost window retrofits: a near-infrared absorbing nanocoating and a photochromic film.•The technologies were tested under real-world conditions in Toronto's continental climate with distinct summers and winters.•Significant reductions in solar transmittance and solar factor were observed, leading to the mitigation of overheating.•The photochromic film enhanced visual comfort, improving useful daylight illuminance by 10%–17% and reducing peak discomfort glare by 9%.•Limited energy savings were observed in a low window-to-wall ratio setting, but results indicate potential benefits for highly glazed buildings. Windows play a pivotal role in building design by providing daylight, solar heat gains, and natural ventilation. However, older buildings with outdated windows and inadequate solar control suffer from overheating, discomfort glare, and high cooling costs. While replacing existing windows with high-performance products can significantly boost energy efficiency and occupant comfort, the associated costs can be prohibitive. Consequently, retrofit technologies that utilize existing glass panes and frames offer a compelling solution. This paper investigates the thermal, energy, and daylight performance of two innovative window retrofit technologies relative to a clear reference tested simultaneously at the BeTOP outdoor test cells in Toronto, ON-a vicinity with distinct warm summers and cold winters. The retrofits included a near-infrared absorbing CsWO3-SnO2 nanosuspension and a nanoceramic WO3-based photochromic window film with dynamic absorptance to visible radiation. The low-cost technologies were applied directly to interior glass surfaces, allowing for swift installation with minimal occupancy interruption. The results show that retrofitting existing glass did not significantly influence the equivalent thermal transmittance but significant reductions in the equivalent solar factor and solar transmittance were observed. Although the retrofits did not significantly influence the energy consumption in this particular setting due to Toronto's cold climate and the adopted low window-wall ratio (10%), they contributed to the mitigation of overheating indicated by up to 50% reduction in the percentage of people dissatisfied. Furthermore, the photochromic film significantly improved visual comfort indicated by a 10%–17% improvement in the useful daylight illuminance and a 9% reduction in peak discomfort glare probability. [Display omitte