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Characterizing Inward Leakage in a Pressure-Demand, Self-Contained Breathing Apparatus

Published

Author(s)

Rodney A. Bryant, Amy Mensch

Abstract

An analytical model of the flow across a resistive flow path such as an orifice or pipe was applied to predict the inward leakage in the facepiece of a self-contained breathing apparatus (SCBA) during a steady negative facepiece pressure. The model was used to estimate leakage rates with respect to the size of the leak and for negative pressure conditions reflective of measured occurrences. The results of the model were also used to make quantitative estimates of the protection level of the respirator. Experiments were designed to induce a continuous below-ambient pressure inside the facepiece of a pressure-demand SCBA attached to a head form. Negative facepiece pressure measured in the presence of a leak correlated with the measured particle concentration ratio. The results show that the analytical model generated reasonable estimates of leakage rates during conditions of negative pressure inside the facepiece. Thus the analytical model performed well for constant flow conditions, demonstrating the capability to predict a momentary compromise in respirator protection during momentary negative facepiece pressure conditions.
Citation
Journal of Occupational and Environmental Hygiene
Volume
8
Issue
7

Keywords

respirator, firefighter, SCBA, leak, inward leakage

Citation

Bryant, R. and Mensch, A. (2011), Characterizing Inward Leakage in a Pressure-Demand, Self-Contained Breathing Apparatus, Journal of Occupational and Environmental Hygiene, [online], https://tsapps.nist.gov/publication/get_pdf.cfm?pub_id=906719 (Accessed March 28, 2024)
Created June 9, 2011, Updated October 12, 2021