Air sampling at the chest and ear as representative of the breathing zone.

S. Guffey, M. Flanagan, G. van Belle
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引用次数: 26

Abstract

Tracer gas concentrations were measured on a 60%-sized mannequin holding a pure sulfur hexafluoride source in its hands at waist height while it stood in a wind tunnel. Samplers were placed at the mannequin's mouth, in front of the ear, and at three chest locations at lapel level. Simultaneous 15-min time-weighted average samples were taken by drawing air into different sampling bags with sampling pumps. For the factorial study design, test conditions included cross-draft velocities of 10, 22, 47, and 80 ft/min; three mannequin orientations (facing to, side to, and back to cross-draft), and rotating speed through an 80 degrees arc (fast, slow, and no movement). Each study condition was tested twice. Concentrations at all sampling locations when the mannequin faced to the front and side were less than a tenth of the levels measured at the nose (Cnose) when the mannequin faced downstream. Higher velocities significantly increased concentration at the Back orientation and generally reduced it at the Side and Facing orientations. Concentrations at the nose were different from concentrations at other sites. For 34 of 36 samples the mean chest concentration (Cchest,) was higher than the Cnose (geometric mean three times higher). The ratio of ear (Cear) and Cnose varied with orientation. At the Back orientation, Cear, was lower than Cnose, whereas Cear was higher than Cnose at the Side and Facing to flow orientations. Velocity affected the ratios of concentrations. At the Back orientation, the chest sampler provided lower overestimates of Cnose, at higher velocities than at lower values. Mannequin movement, done only at the Back orientation, proved important only for the ear location. Results showed significant and substantial differences between concentrations at the nose and lapel. However, these findings should be interpreted with caution because a very dense tracer gas and an unheated, nonbreathing mannequin were used. In more realistic conditions, the findings probably would show far smaller differences in concentrations at different sampling sites.
胸部和耳朵的空气采样作为呼吸区的代表。
示踪气体浓度是在一个60%大小的人体模型上测量的,该模型站在风洞中,双手拿着纯六氟化硫源,处于腰部高度。采样器被放置在人体模型的嘴巴,耳朵前面,以及在翻领水平的三个胸部位置。用采样泵将空气吸入不同的采样袋中,同时采集15分钟时间加权平均样本。对于析因研究设计,测试条件包括10、22、47和80英尺/分钟的横向气流速度;三个人体模型的方向(面对,侧面,和背面的交叉草案),并通过80度弧线旋转速度(快,慢,不移动)。每个研究条件都测试了两次。当人体模型面朝前方和侧面时,所有采样位置的浓度都小于人体模型面朝下游时在鼻子(Cnose)测量的浓度的十分之一。较高的速度显著增加了背面方向的浓度,而在侧面和面向方向上通常会降低浓度。鼻部的浓度与其他部位的浓度不同。36个样本中有34个样本的平均胸部浓度(Cchest)高于Cnose(几何平均值高3倍)。耳(耳)和鼻(鼻)的比例随取向而变化。在背向方向上,锐度低于Cnose,而在侧面和面向流动方向上,锐度高于Cnose。速度影响浓度比。在背部方向,胸部采样器提供了较低的Cnose高估,在较高的速度比在较低的值。人体模型的运动,只在背部方向进行,证明只对耳朵的位置很重要。结果显示鼻部和翻领的浓度有显著的差异。然而,这些发现应该谨慎解释,因为使用了非常密集的示踪气体和未加热、无呼吸的人体模型。在更现实的条件下,研究结果可能会显示不同采样点的浓度差异要小得多。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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