A method for evaluating aerosol leakage through the interface between protective suits and full-face respirators

Military personnel and first responders use a range of personal equipment including protective suits, gloves, boots, and respirators to prevent exposure of their skin and airways to hazardous chemical, biological, radiological, and/or nuclear substances. Although each individual item of personal pro...

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Bibliographic Details
Published in:Journal of occupational and environmental hygiene 2016-05, Vol.13 (5), p.315-324
Main Authors: Arnoldsson, Kristina, Danielsson, Signar, Thunéll, Marianne
Format: Article
Language:English
Subjects:
Aerosols
Air leakage
Air Pollutants, Occupational
CBRN
Equipment Design
Face
hood-respirator interface
Hoods
Inhalation Exposure - analysis
Interfaces
Leakage
Manikins
Materials Testing - methods
Mineral Oil
Occupational Exposure - prevention & control
Occupational health
Particle Size
Personal protective equipment
Product design
Protective
Protective Clothing
protective equipment
Respirators
respiratory exposure
Respiratory Protective Devices - standards
Sealing
Seals
Strip
Studies
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Summary:Military personnel and first responders use a range of personal equipment including protective suits, gloves, boots, and respirators to prevent exposure of their skin and airways to hazardous chemical, biological, radiological, and/or nuclear substances. Although each individual item of personal protective equipment is well tested against existing standards, it is also necessary to consider the performance of the interfaces between items in terms of prevention from exposure, and the protection system as a whole. This article presents an aerosol challenge method for assessing the performance of the interface between a respirator and the hood of a protective suit. The interface is formed between the sealing strip of the hood and the surface of the respirator's outer sealing area and is affected by how well the sealing strip can cover and adapt to the sealing area. The method evaluates the leakage of particles of different sizes into the hood via the interface by particle counting at sampling points around the respirator's perimeter. Three different respirators were tested together with a single hood having a tight-fitting seal. The method variation between measurements was low but increased appreciably when the protective ensemble was re-dressed between measurements. This demonstrates the difficulty of achieving a reliable and reproducible seal between respirator and hood under normal conditions. Different leakage patterns were observed for the three respirators and were linked to some specific design features, namely the respirator's sealing area at the chin and its width at cheek level. Induced leak experiments showed that to detect substantial particle leakage, channels at the hood-respirator interface must be quite large. The method outlined herein provides a straightforward way of evaluating hood-respirator interfaces and could be useful in the further development of personal protective equipment.
ISSN:1545-9624
1545-9632
DOI:10.1080/15459624.2015.1117616