Thermodynamic Analysis of Suppressant-Enhanced Overpressure in the FAA Aerosol Can Simulator

Linteris, Gregory T.; Takahashi, Fumiaki; Katta, Viswanath R.; Chelliah, Harsha K.; Meier, Oliver

doi:10.3801/iaffs.fss.10-307

Cited by 5 publications

(6 citation statements)

References 19 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In the FAA-ACT, overpressures were observed (indicating an increase in flammability) [4,5]. Similarly, in a constantvolume apparatus at high agent loadings in lean flames, increases in pressure, burning velocity, and flame temperature were observed [23].…”

Section: Discussionmentioning

confidence: 99%

“…Cup burner tests indicate that 2-BTP is an effective flame extinguisher at concentrations similar to those required by CF 3 Br [1][2][3]. However, it was unexpectedly found that when 2-BTP is added at subinerting concentrations in the U.S. Federal Aviation Authority Aerosol Can Test (FAA-ACT) [4][5][6][7][8] a large overpressure is obtained, causing the agent to fail the test and indicating that 2-BTP is reacting exothermically under these conditions. The development of a fundamental model explaining the chemical basis of these results would be of value to help assess the range of conditions where such behavior might be expected, as well as provide insights that could lead to the development of more effective agents.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

A Chemical Kinetic Mechanism for 2‐Bromo‐3,3,3‐trifluoropropene (2‐BTP) Flame Inhibition

Burgess

Babushok

Linteris

et al. 2015

Int J of Chemical Kinetics

View full text Add to dashboard Cite

In this work, we report a detailed chemical kinetic mechanism to describe the flame inhibition chemistry of the fire-suppressant 2-bromo-3,3,3-trifluoropropene (2-BTP), under consideration as a replacement for CF 3 Br. Under some conditions, the effectiveness of 2-BTP is similar to that of CF 3 Br; however, like other potential halon replacements, it failed an U.S. Federal Aviation Authority (FAA) qualifying test for its use in cargo bays. Large overpressures are observed in that test and indicate an exothermic reaction of the agent under those conditions. The kinetic model reported herein lays the groundwork to understand the seemingly conflicting behavior on a fundamental basis. The present mechanism and parameters are based on an extensive literature review supplemented with new quantum chemical calculations. The first part of the present article documents the information considered and provides traceability with respect to the reaction set, species thermochemistry, and kinetic parameters. In additional work, presented more fully elsewhere, we have combined the 2-BTP chemical kinetic mechanism developed here with several other submodels from the literature and then used the combined mechanism to simulate premixed flames over a range of fuel/air stoichiometries and agent loadings. Overall, the modeling results qualitatively predicted observations found in cupburner tests and FAA Aerosol Can Tests, including the extinguishing concentrations required and the lean-to-rich dependence of mixtures. With these data in hand, in a second phase of the present work, we perform a reaction path analysis of major species under several modeled conditions. This analysis leads to a qualitative understanding of the ability of 2-BTP to act as

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Chemical Kinetic Mechanism for 2‐Bromo‐3,3,3‐trifluoropropene (2‐BTP) Flame Inhibition

Burgess

Babushok

Linteris

et al. 2015

Int J of Chemical Kinetics

View full text Add to dashboard Cite

show abstract

“…The objective of this work was to develop a laboratory scale experiment to validate the theoretical work of Linteris (2011) andBabushok (2012) for aviation applications. The results of this work support their calculation model.…”

Section: Discussionmentioning

confidence: 99%

“…Theoretical research into the possible causes for these phenomena included development of calculation models to describe and predict the mechanisms of the specific explosion events (Linteris, 2011;Babushok, 2012). This provided some possible explanations about the chemistry involved.…”

Section: 1mentioning

confidence: 99%

Fluorinated halon replacement agents in explosion inerting

Gatsonides

Andrews

Phylaktou

et al. 2015

Journal of Loss Prevention in the Process Industries

View full text Add to dashboard Cite

The US Federal Aviation Administration (FAA) observed during explosion tests that at low concentrations candidate halon replacement agents increased the explosion severity instead of mitigating the event. At UTC Aerospace Systems a test program was developed to assess the behaviour of alternative agents at values below inerting concentration. Two agents were selected, HFC-125 and Novec ™ 1230. Baseline tests were performed with unsuppressed propane/air mixtures and fuel/air mixtures with Halon 1301 and nitrogen (N 2 ). Using Halon 1301 or N 2 at below inerting concentrations mitigated the explosion. HFC-125 was tested against propane at stoichiometric (4 vol%) and lower explosion limit (LEL) (2 vol%). Against 4 vol% propane the combustion was mitigated, proportional to agent concentration; however, low concentrations of HFC-125 with 2 vol% propane enhanced the explosion. Tests with N 2 against a volatile mixture of propane with HFC-125 showed that N 2 mitigated the events.Final tests were performed with low concentrations of Novec™1230 against propane/air mixtures. This showed similar behaviour to that observed with the HFC-125 tests. Normally during qualification tests for new agents the stoichiometric concentration of a fuel is deemed to be the worst case scenario and the baseline against which agents are tested. The above described test results show that this assumption may need to be reconsidered. This work shows that contrary to common assumption the agents investigated did not act chemically at the flame front, but mainly cooled the flame and changed the stoichiometry, i.e. the ratio of components of the flammable mixture.

show abstract

“…8,9 Several studies have been performed to explain this phenomenon. 10–13 Perfectly stirred reactor simulations have indicated that adding the suppressant to the lean system increases the energy release rate and the overall reaction rate. 10 Thermodynamic equilibrium calculation indicated that the peak pressure rise occurred when the fuel and agent were completely consumed.…”

Section: Introductionmentioning

confidence: 99%

Numerical investigation of the chemical and physical effects of halogenated fire suppressants addition on methane–air mixtures

Ren

Jiang

2016

Journal of Fire Sciences

View full text Add to dashboard Cite

Previous experimental and numerical studies have demonstrated the unwanted promotion effect caused by potential halon replacements added to hydrocarbon–air mixtures. To explore this abnormal phenomenon, the chemical and physical contributions of the addition of C6F12O (Novec 1230) and C2HF5 (HFC-125) on the laminar flame speeds of the CH4–air mixtures are numerically investigated. Numerical simulations are conducted using the CHEMKIN-PRO software with newly developed fluorinated compounds’ mechanisms. Based on the interaction between the chemical effect and the physical effect, the equivalence ratio zone is divided into synergistic zone and antagonistic zone. Furthermore, the fuel-like characteristics of C6F12O and C2HF5 are also studied. In the lean CH4–air condition, the agents contribute to increasing the equivalence ratio, thus increasing the flame speeds chemically but cooling the mixture physically. When the actual equivalence ratio of the agent–CH4–air mixture is larger than 1.10 (for the C2HF5 addition) or 1.20 (for the C6F12O addition), the agents create an over-rich fuel mixture, thus decreasing the flame speed chemically. The contribution of the chemical effect is studied under different initial temperature and pressure conditions. The results indicate that increasing the temperature slightly lowers the chemical contribution, whereas increasing the pressure largely increases the chemical contribution. Additionally, a sensitivity analysis is conducted to interpret the large chemical component increase under high pressure conditions.

show abstract

Thermodynamic Analysis of Suppressant-Enhanced Overpressure in the FAA Aerosol Can Simulator

Cited by 5 publications

References 19 publications

A Chemical Kinetic Mechanism for 2‐Bromo‐3,3,3‐trifluoropropene (2‐BTP) Flame Inhibition

A Chemical Kinetic Mechanism for 2‐Bromo‐3,3,3‐trifluoropropene (2‐BTP) Flame Inhibition

Fluorinated halon replacement agents in explosion inerting

Numerical investigation of the chemical and physical effects of halogenated fire suppressants addition on methane–air mixtures

Contact Info

Product

Resources

About