Heating and ventilation performance investigation of a novel linear slot diffuser with adaptive outlet area for near window applications

Abstract

The linear slot diffuser has ideal cooling performance for near-window applications, and is used for ventilation by utilizing the coandă effect in some cases. However, it has insufficient throw distance due to buoyancy impact during heating periods. And airflow near window surfaces increases convection heat transfer, resulting in extra HVAC energy consumption. Our research focuses on a prototype linear slot diffuser with an adaptive outlet area. Two deflection panels are installed for adjusting the outlet area depending on temperature or usage scenarios. Supply air has a low velocity and wide diffusion range when the panels are open. It can utilize the coandă effect as well as keep convection heat transfer within an appropriate range. Closing the panels will halve the supply area and completely change airflow diffusion and turbulence characteristics. This is considered suitable for heating, but the mounting location needs to be re-evaluated. Therefore, this prototype's heating and ventilation performance is numerically investigated using a low-Reynolds number turbulence model with fine meshes. Temperature, airflow, tracer gas distribution in a typical office space, and the ADPI, DR, and age-of-air indexes are compared before and after outlet area adjustment. Diffuser mounting locations and exhaust methods are also altered to balance heating and ventilation efficiency. As a result, a proper installation location for this prototype is suggested. The adaptive supply area significantly improved this terminal's heating and ventilation performance. Temperature stratification was reduced to a maximum of one-tenth, and impinging jets or displacement ventilation were observed in some cases.