Abstract
Indoor air quality (IAQ) is much more crucial to human health than its atmospheric air quality counterpart. Improving indoor air environment requires investigating how different indoor air stability affects airflow trajectory. By presenting both manikin experiment and Computational Fluid Dynamics (CFD) simulation, we find that temperature background effect, i.e., indoor air stability, which is a measure of the nature or attribute of the capacity to keep the original or initial inertia force or inertia transmission state instead of turbulence diffusion or transmission restraining state, i.e., a kind of inertia stability, rather than a turbulence diffusion characteristic stability, is markedly affecting the interactive respiration process. So we define and derive a new parameter called Gc number as a criterion to judge air stability. Furthermore, we find the phenomenon of inertia conjugation. Air stability and inertia conjugation, which named together as temperature background effect, work together on interactive respiration process. This work gives us a re-orientation of temperature difference agents and thus improves human being’s living environment.
Highlights
Temperature difference affects atmospheric stability, which attributes to haze accumulation in human habitants
Tt > Tb, indoor air is in a stable pattern, Gc = 119.94 > 0, Gc′ = 8.3 × 10−3 > 0, and the results are in accordance with the judgments of the dry adiabatic lapse rate
Air stability is a kind of map of temperature difference agent or density difference agent which affects the respiration airflow along two directions, and keeps the original or initial inertia force or inertia transmission state other than turbulence diffusion or transmission state
Summary
Temperature difference affects atmospheric stability, which attributes to haze accumulation in human habitants.
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