We measured indoor air speeds generated by ceiling fans in 78 full-scale laboratory tests. The factors were the room size, fan diameter, type, speed, direction (up or down), blade height, and mount distance (i.e. blade to ceiling height). We demonstrated the influence o f t hese f actors, s howing t hat t he m ost s ignificant ar e speed, diameter and direction. With other factors fixed, t he average r oom a ir s peed i n t he o ccupied z one increases proportionally with fan air speed and diameter. Blowing fans upwards yields lower but far more uniform air speeds than downwards. We show that for the same fan diameter and airflow, f an type h as l ittle effect on the air speed distribution in the region outside the fan blades. We developed several new dimensionless representations and demonstrate that they are appropriate for comparisons over a wide range of fan and room characteristics. Dimensionless linear models predict the lowest, average, and highest air speeds in a room with a median (and 90 th percentile) absolute error of 0.03 (0.08), 0.05 (0.13), and 0.12 (0.26) m/s respectively over all 56 downwards tests, representing common applications. These models allow designers to quickly and easily estimate the air speeds they can expect for a given fan and room. We include all measured data and analysis code in this paper.
Highlights:• Measured air speed distribution in 78 full-scale laboratory tests • Average air speeds increase in direct proportion to fan rotational speed and diameter • Blowing fans upwards yields lower but more uniform air speeds than downwards • At equal diameter and airflow, fan type doesn't affect air speeds in most of the room • Developed easily applied models to predict indoor air speeds with ceiling fans Graphical Abstract 2