Identification of Soils on Firefighter Turnout Gear from the Philadelphia Fire Department

Huston, Tabitha N

01 January 2014

The purpose of this research was to identify the composition of soils on firefighter turnout gear from the Philadelphia Fire Department and to determine which soils contain hazardous materials. The objective of the research was to identify the composition of soils remaining on the firefighter turnout gear to enable the industry to design an effective cleaning procedure for removal of soils. A pilot study was conducted on hoods from the Philadelphia fire department to evaluate the test methods that would be used to identify the composition of soils. Soils that had been identified from previous studies were targeted in the analysis of the extraction of the samples removed from the hoods. Samples were removed from areas of the coats and pants where dermal absorption is reported as high areas of skin absorption, including areas in the neck, armpit, crotch and wrist locations.

Turnout Gear

Firefighter

Soils

Hazardous Materials

Philadelphia

Agriculture

Post Use Analysis of Firefighter Turnout Gear- Phase III

Cinnamon, Meredith Laine

01 January 2013

The purpose of this research was to perform a post-use evaluation of retired firefighter turnout gear. Garments were categorized as 10-12 years old, 13-17 years old and 18-21 years old. Inspection and test procedures required by National Fire Protection Association (NFPA) 1851 and NFPA 1971 were followed to determine if the current recommended 10 year wear life (retirement age) is appropriate. Testing included a visual inspection (closure system functionality, light evaluation, leakage evaluation and flashlight test) and performance properties (Thermal Protective Performance (TPP), flammability, breaking strength, tear strength, seam strength and water penetration) completed on 108 garments. Ten-year retirement, care, and use were criteria evaluated. The results confirm the flashlight test allows the firefighter to effectively evaluate trim reflectance on their turnout gear according to NFPA 1851. The leakage tests were not replicated by the water penetration tests. Based on the results of this study, the advanced visual inspection and light evaluation confirm the recommended retirement age of a garment that was at least ten years from manufacture date.

Turnout Gear

Post Use

Firefighter

Retirement

NFPA Standards

Life Sciences

Medicine and Health Sciences

Physical Sciences and Mathematics

Development of non-destructive test methods for assessment of in-use fire fighter's protective clothing

Thorpe, Peter A

31 May 2004

The very nature of the fire fighting environment makes thermal degradation of turnout gear inevitable. Standards that are currently in place to ensure that new gear performs adequately for the protection of the fire fighter do not provide a quantitative measure for assessing this gear once it is in service. When the performance of the gear is compromised due to degradation, it could put the fire fighter wearing the gear at unnecessary risk. A non-destructive test that indicates the end of the useable service of the garment would be a benefit to the fire service. Full scale fire tests were conducted to suggest a range of heat fluxes that turnout gear specimens should be subjected to in order to simulate degradation caused by in-field use of the gear. A series of destructive tests were conducted on exposed specimens. A number of non-destructive tests were performed on the same specimens. The results of destructive and non-destructive tests were compared. This research explored some options for non-destructive tests of turnout gear. Digital image analysis and colorimetry were both offered as possibilities for a diagnostic test of this gear. Correlations between destructive performance tests and the colour changes of the outer shell fabric could be used to develop non-destructive tests to evaluate every garment owned by a department. More work is required to improve these test methods, but the door has been opened to better testing for in-use gear, and ultimately to provide better protection for the fire fighters who use this clothing.

non-destructive testing

digital image analysis

full scale fire tests

turnout gear

degradation

heat transfer

fire fighter

protective clothing

Development of non-destructive test methods for assessment of in-use fire fighter's protective clothing

Thorpe, Peter A

31 May 2004

The very nature of the fire fighting environment makes thermal degradation of turnout gear inevitable. Standards that are currently in place to ensure that new gear performs adequately for the protection of the fire fighter do not provide a quantitative measure for assessing this gear once it is in service. When the performance of the gear is compromised due to degradation, it could put the fire fighter wearing the gear at unnecessary risk. A non-destructive test that indicates the end of the useable service of the garment would be a benefit to the fire service. Full scale fire tests were conducted to suggest a range of heat fluxes that turnout gear specimens should be subjected to in order to simulate degradation caused by in-field use of the gear. A series of destructive tests were conducted on exposed specimens. A number of non-destructive tests were performed on the same specimens. The results of destructive and non-destructive tests were compared. This research explored some options for non-destructive tests of turnout gear. Digital image analysis and colorimetry were both offered as possibilities for a diagnostic test of this gear. Correlations between destructive performance tests and the colour changes of the outer shell fabric could be used to develop non-destructive tests to evaluate every garment owned by a department. More work is required to improve these test methods, but the door has been opened to better testing for in-use gear, and ultimately to provide better protection for the fire fighters who use this clothing.

non-destructive testing

digital image analysis

full scale fire tests

turnout gear

degradation

heat transfer

fire fighter

protective clothing