Comprehensive Theoretical and Experimental Studies on the CF<sub>3</sub>H Fire‐extinguishing Mechanism

Zhou, Xiaomeng; Zhou, Biao

doi:10.1002/cjoc.201180251

Cited by 10 publications

(3 citation statements)

References 25 publications

(20 reference statements)

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“…F∙ radicals can also capture H∙ radicals, but their ability is much worse than that of CF 3 ∙ radicals. The detailed kinetic study of CF 3 ∙ has been reported in a previous study [32], so it is not be discussed here. Each N(CF 2 CF 3 ) 3 molecule can produce at most three CF 3 ∙ radicals, which can also be inferred from its good fire‐extinguishing ability.…”

Section: Resultsmentioning

confidence: 99%

Thermal decomposition and fire‐extinguishing mechanism of N(CF₂CF₃)₃ by ReaxFF‐based molecular dynamics simulation and density functional theory calculation

Tao

Cheng

Xing

et al. 2022

Int J of Quantum Chemistry

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Since halon fire‐extinguishing agents are forbidden to be used due to environmental concerns, it is necessary to explore new environmentally friendly fire‐extinguishing agents. Perfluorotriethylamine (N(CF2CF3)3) with good physicochemical properties is a potential substitute for halons. To evaluate its practicability as the halon substitute, the thermal decomposition performance and mechanism of N(CF2CF3)3 were systematically investigated by combining experiment and theory in this study. The initiation reaction of N(CF2CF3)3 thermal decomposition was calculated by density functional theory. The reactive molecular dynamics simulations based on the reactive force field were used to investigate the thermal decomposition process of N(CF2CF3)3 at different temperatures, including the intermediates, decomposition temperature, and product distribution. To examine the actual fire‐extinguishing performance of N(CF2CF3)3, its fire‐extinguishing concentration in the n‐heptane‐air flame was measured by the cup‐burner method. Finally, the chemical fire‐extinguishing mechanism of N(CF2CF3)3 was proposed. N(CF2CF3)3 was pyrolyzed during the interaction with flame, producing the fire extinguishing radical CF3∙, which further consumed the active H∙ and OH∙ radicals by reactions.

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Section: Resultsmentioning

confidence: 99%

Thermal decomposition and fire‐extinguishing mechanism of N(CF₂CF₃)₃ by ReaxFF‐based molecular dynamics simulation and density functional theory calculation

Tao

Cheng

Xing

et al. 2022

Int J of Quantum Chemistry

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“…As an effective component for chemical extinguishment, , the CF 3 H molecule can react with hydroxyl and hydrogen radicals through hydrogen atom abstraction by radicals with negligible energy barriers of 1.102 and 8.134 kcal·mol –1 , respectively, leading to the generation of CF 3 • radicals (paths 15 and 16 in Figure S14). After that, the CF 3 • radical could spontaneously combine with a H • radical without any barrier, resulting in the formation of the CF 3 H product that has obviously lower energy than reactants (path 17 in Figure S14).…”

Section: Resultsmentioning

confidence: 99%

Thermal Decomposition Mechanism and Fire-Extinguishing Performance of trans-1,1,1,4,4,4-Hexafluoro-2-butene: A Potential Candidate for Halon Substitutes

Zhang

Wang

et al. 2020

J. Phys. Chem. A

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In view of the appropriate physicochemical characteristics and environmental friendliness of the trans-1,1,1,4,4,4-hexafluoro-2-butene (HFO-1336mzz(E)) substance, the thermal-decomposition mechanism as well as the fire-extinguishing mechanism and performance of this agent were systematically studied by employing both experimental and theoretical methods in this work. We found that the HFO-1336mzz(E) agent not only has promising thermal stability at room temperature but also exhibits pronounced fire-extinguishing performance, which is comparable to that of HFC-236fa and even better than that of HFC-125 extinguishant. Additionally, the promising fire-extinguishing performance of HFO-1336mzz(E) may result from the physical and chemical extinguishing effect of its thermal-decomposition products including HFO-1336mzz(Z), HCCCF3, CF3CCCF3, and CF3H, which makes a significant contribution to capturing the free radicals in the flame, as well as cooling and diluting the combustible fuel-air mixture. Both experimental and theoretical results suggest that the HFO-1336mzz(E) agent is a highly recommendable candidate for Halon extinguishant, which is worthy of further investigation and evaluation of its practical applicability in fire-suppression utilization.

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“…There have been many attempts in the literature to develop approaches that address the HF generation mechanism during fire suppression. The main emphasis of available researches are focused on HF yield amount [15] and mechanism of CF 3 H [16], thermal decomposition mechanism of CHF 2 CF 3 [17,18] and other Halon alternatives [19], HF production of CF 3 CHFCF 3 [20], thermal decomposition of trans-CF 3 CH = CHCF 3 [21], HF pyrolysis of CF 2 H 2 [22], thermal decomposition of CF 3 CBrH = CH [23] and so on. Although the yield of corrosive gases has been reported to impact potential damage on the surface of materials [24], the comprehensive study of the influence of HF on the color change of wooden materials is still unavailable.…”

Section: Introductionmentioning

confidence: 99%

The color change analysis of historic wooden remains after fire-suppression by fluorinated chemical gases

Yang

Zhou

et al. 2021

Herit Sci

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Many wooden Chinese historic buildings are destroyed due to the ravages of frequent fire disasters. The fire risk of historic buildings are highly enlarged since a long-time weathered wooden structures in the natural environment. The clean fire-extinguishing technology using fluorinated chemical gases to put out a historic building fire rapidly at the initial stage is highly recommended and widely used. However, the gaseous hydrogen fluoride (HF) yielded during the fire suppression process could be a potential method to result in secondary damage due to its corrosiveness. Nowadays, experiments were employed to clarify the effect of fire suppression on the surface of historic wooden buildings. Five traditional fluorinated chemical gases, H-37, FK-5-1-12, H-1323, H-2402, and H-1301, are used to suppress a fixed flame. The wooden samples, including a Dao Talisman board, a painting paper, and wooden chips, are placed in a chamber. Wooden chips consist of traditional and weathered samples (acting as the Chinese historic buildings). The concentration of gaseous products yielded from fire suppression are monitored by a gas-FTIR from ABB, and the surface analysis is conducted by a Quanta FEG SEM–EDX from FEI. It is observed that flame enhancement happens at the early stage of fire suppression and varies with fire agents. The amount of F-deposited on the wooden surface is positively correlated with a total amount of gaseous HF. The color change mechanism of the wooden surface is comprehensive, although the amount of HF is a leading factor. The influence of HF on color change depends on the amount of both gaseous H2O and HF. It is concluded that the value of L* of the traditional chip is much easier to be reduced comparing with weathered samples with the same wood grain. The reduction of $${\mathrm{b}}^{*}$$ b ∗ value of weathered samples is much larger than the traditional ones. It suggests the weathered chips show a color shift toward blue because of fire suppression. The present study hopes to provide a basic acknowledgment for the comprehensive understanding of secondary damage caused by fire suppression.

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Comprehensive Theoretical and Experimental Studies on the CF₃H Fire‐extinguishing Mechanism

Cited by 10 publications

References 25 publications

Thermal decomposition and fire‐extinguishing mechanism of N(CF₂CF₃)₃ by ReaxFF‐based molecular dynamics simulation and density functional theory calculation

Thermal decomposition and fire‐extinguishing mechanism of N(CF₂CF₃)₃ by ReaxFF‐based molecular dynamics simulation and density functional theory calculation

Thermal Decomposition Mechanism and Fire-Extinguishing Performance of trans-1,1,1,4,4,4-Hexafluoro-2-butene: A Potential Candidate for Halon Substitutes

The color change analysis of historic wooden remains after fire-suppression by fluorinated chemical gases

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Comprehensive Theoretical and Experimental Studies on the CF3H Fire‐extinguishing Mechanism

Cited by 10 publications

References 25 publications

Thermal decomposition and fire‐extinguishing mechanism of N(CF2CF3)3 by ReaxFF‐based molecular dynamics simulation and density functional theory calculation

Thermal decomposition and fire‐extinguishing mechanism of N(CF2CF3)3 by ReaxFF‐based molecular dynamics simulation and density functional theory calculation

Thermal Decomposition Mechanism and Fire-Extinguishing Performance of trans-1,1,1,4,4,4-Hexafluoro-2-butene: A Potential Candidate for Halon Substitutes

The color change analysis of historic wooden remains after fire-suppression by fluorinated chemical gases

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Comprehensive Theoretical and Experimental Studies on the CF₃H Fire‐extinguishing Mechanism

Thermal decomposition and fire‐extinguishing mechanism of N(CF₂CF₃)₃ by ReaxFF‐based molecular dynamics simulation and density functional theory calculation

Thermal decomposition and fire‐extinguishing mechanism of N(CF₂CF₃)₃ by ReaxFF‐based molecular dynamics simulation and density functional theory calculation