- Author
-
Pitts, W. M.
|
Yang, J. C.
|
Bryant, R. A.
|
Blevins, L. G.
|
Huber, M. L.
- Title
- Characterization and Identification of Super-Effective Thermal Fire Extinguishing Agents. Final Report. NGP Project 4C/1/890.
- Coporate
- National Institute of Standards and Technology, Gaithersburg, MD
- Report
-
NIST Technical Note 1440; NIST TN 1440,
July 2006,
138 p.
- Keywords
-
fire extinguishing agents
|
reaction kinetics
|
flame extinguishment
|
surface cooling
|
combustion
|
propane
|
experiments
|
thermophysical properties
|
lactic acid
|
halon alternatives
|
diffusion flames
|
methane
|
extinction
|
argon
|
nitrogen
|
carbon dioxide
|
helium
|
water vapors
|
dilution
|
heat extraction
|
flame fronts
|
extinguishing
|
halon 1301
- Identifiers
- identification and testing of potential highly effective thermal agents; detailed chemical-kinetic modeling and experimental investigations of thermal agent flame extinguishment; detailed chemical-kinetic mechanism for propane combustion; additional details concerning the coflow diffusion flame experiment
- Abstract
- The use of halon 1301 for fire fighting is being phased out due to its deleterious effects on stratospheric ozone. This report summarizes the findings of a three-year study designed to characterize and identify super-effective thermal fire-fighting agents as possible replacements for these widely used compounds. Four distinct aspects related to the effectiveness of potential thermal agents have been considered. First, existing thermodynamic databases maintained by NIST have been searched in order to identify chemical compounds which are predicted to extract large amounts of heat from a combustion zone. Second, two liquids that were identified as being particularly interesting during the database search were tested experimentally for their extinguishing effectiveness. Third, detailed chemical-kinetic modeling and experimental studies of extinguishing volume fractions in simple flame systems were employed to improve the understanding of the effects of thermal agents on diffusion flames. Fourth, empirical heat transfer correlations for spray cooling of a surface were used to estimate the efficiencies of surface cooling by thermal agents. The database searches used two primary sources -- the Design Institute for Physical Properties database containing 1458 compounds from 83 family types and a smaller database, REFPROP, containing 43 compounds which is tailored to refrigerant applications. Additional substances were included that are not well represented in these databases. Compounds having high 1) heats of vaporization, 2) liquid-phase heat capacities, and 3) total heat absorption due to phase changes (if applicable), heating of a liquid (if applicable), and the heating of the gas phase to combustion temperatures were identified. The results are reported in tables of compounds ordered in terms of their ability to extract heat. The following recommendations are made based on the findings of the study: 1. The effectiveness of HFE7100 as a fire-extinguishing agent should be tested on full-scale simulations of aircraft fires. 2. Additional studies of the effectiveness of fire extinguishing agents released as liquids should be performed with a focus on confirming and understanding their enhanced performance relative to that expected based on simple heat extraction. 3. Experiments should be designed and performed with a goal of better understanding the interactions of liquid agent droplets with heated and reacting surfaces. Such an understanding is needed to better predict the effectiveness of liquid agents and could lead to improved approaches for delivering such agents to a fire.