(129h) Simulation of the Thermal Plume Around a Seated Mannequin

The thermal plume
around a standing human subject was studied experimentally by Craven and Settles
(JFE, 2007). The portion of the plume above the person's head was turbulent,
and the maximum value of the time-averaged vertical velocity was 0.24 m/s; it
occurred at a distance equal to 0.43 m directly above the subject's head.
Craven & Settles also performed a RANS simulation of the thermal plume; the
maximum value of the time-averaged vertical velocity obtained from the
simulation was 0.20 m/s. This paper will present the results of numerical
simulations of the thermal plume created by a seated mannequin. The simulations
were performed using a lattice Boltzmann method. Following the detailed
measurements of Craven and Settles, the surface temperature of the mannequin
was taken to be 5^oC warmer than the initial temperature of the
surrounding air. Simulations were performed for three different spatial grids
to determine the effect of spatial resolution on the velocity and temperature fields.
In each case, a uniform, cubic spatial grid was used for the simulation; the
grid spaces were 0.0067, 0.01, and 0.02m, respectively. The results obtained from
the finest grid were in reasonable agreement with the experimental study; the
maximum time-averaged vertical velocity was 0.226 m/s and it occurred at a
distance 0.53m directly above the mannequin's head. The simulations also reveal
that the instantaneous vertical velocity is significantly larger than the
time-averaged vertical velocity, and that it occurs over a large range of
distances above the mannequin; values as large as 0.34 m/s were obtained at
times at late as 10 minutes from the initial condition. A more detailed
comparison between the simulations and the experimental results will be presented
in the talk.