Edwards Jack R, Huang Ching-Wei, Liu Xiaoyu
Department of Mechanical and Aerospace Engineering, North Carolina State University, Campus Box 7910, Raleigh, NC 27695-7910, USA.
Department of Mechanical and Aerospace Engineering, North Carolina State University, Campus Box 7910, Raleigh, NC 27695-7910, USA.
J Hazard Mater. 2024 Feb 5;463:132832. doi: 10.1016/j.jhazmat.2023.132832. Epub 2023 Oct 21.
Computational fluid dynamics simulations are used to model the velocity field and the transport of a passive scalar within a micro-scale chamber used to measure diffusional transport through various building materials. Comparisons of solutions obtained using a steady, laminar flow assumption with velocity measurements obtained from hot-wire anemometry show that the numerical method generally underpredicts the near surface velocity field. The results improve for higher flow rates and for carpeted test materials, modeled as a porous resistive layer. Calculations involving scalar transport within the upper chamber of the sampling device are performed for different flow rates and Schmidt numbers. The results are used to develop a model for the convective mass transfer coefficient, correlated as a function of the Reynolds and Schmidt numbers as well as the porosity of the carpet. This model is integrated into a steady-state mass transport model for predicting the diffusion of gaseous formaldehyde through various test materials. Predictions of diffusion and partition coefficients for vinyl flooring, gypsum wall board, and carpet are within the ranges of literature data. The results indicate that a perfectly mixed upper part of the sampling device is an adequate assumption.
计算流体动力学模拟用于对一个微尺度腔室内的速度场和被动标量的输运进行建模,该微尺度腔室用于测量通过各种建筑材料的扩散输运。将使用稳定层流假设获得的解与通过热线风速仪获得的速度测量结果进行比较,结果表明数值方法通常会低估近表面速度场。对于更高的流速以及模拟为多孔电阻层的铺有地毯的测试材料,结果有所改善。针对不同的流速和施密特数,对采样装置上腔室内的标量输运进行了计算。这些结果用于建立对流质量传递系数模型,该模型与雷诺数、施密特数以及地毯的孔隙率相关。该模型被集成到一个稳态质量输运模型中,用于预测气态甲醛通过各种测试材料的扩散。对乙烯基地板、石膏墙板和地毯的扩散系数和分配系数的预测在文献数据范围内。结果表明采样装置上部完全混合是一个合理的假设。