Pyrolysis of Medium-Density Fiberboard: Optimized Search for Kinetics Scheme and Parameters via a Genetic Algorithm Driven by Kissinger’s Method

Li, Kai Yuan; Huang, Xinyan; Fleischmann, Charles; Rein, Guillermo; Ji, Jie

doi:10.1021/ef501380c

Cited by 170 publications

(79 citation statements)

References 30 publications

(145 reference statements)

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“…The 2 Reaction Model provides a notably better fit with R 2 = 0.96–0.99. In addition to these mechanisms, a decomposition mechanism consisting of 3 parallel reactions that was proposed by Li et al for MDF was considered. The kinetic parameters of individual reactions determined by these researchers were kept unaltered, while the relative amounts of 3 reactants, which according to Li et al represent cellulose, hemicellulose, and adhesive, were varied to fit the MCC data.…”

Section: Materials Property Determination Resultsmentioning

confidence: 99%

A methodology for predicting and comparing the full‐scale fire performance of similar materials based on small‐scale testing

et al. 2018

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Summary Reconstructive fire testing is an important tool used by fire investigators to determine the cause, origin, and progression of a particular fire. Accurate reconstruction of the fire requires the laboratory structure to be outfitted with materials that, in terms of contribution to fire growth, perform similarly to the original materials found at the fire scene. Therefore, a procedure was developed to enable fire investigators to select these replacement materials on the basis of a quantitative assessment of their relative fire performance. This procedure consists of gram‐scale and/or milligram‐scale standard testing accompanied by inverse numerical modeling of these tests, which is used to obtain relevant material properties. A numerical model composed of a detailed pyrolysis submodel and empirical flame heat feedback submodels, which were developed in this study, is subsequently employed to simulate the early stages of the Room Corner Test, which was selected to represent full‐scale material performance. The results of these simulations demonstrate that this procedure can successfully differentiate between fire growth propensities of several commercially available medium density fiberboards.

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Section: Materials Property Determination Resultsmentioning

confidence: 99%

A methodology for predicting and comparing the full‐scale fire performance of similar materials based on small‐scale testing

et al. 2018

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“…(5) could not be determined. Nevertheless, the reaction order only changes the shape of DTG (mass-loss rate) curve, not the location of DTG peak [35,36]. So for simplicity, the same second-order reaction (n c ¼ 2) is assumed for all three coals.…”

Section: Kinetic Analysis Via Hot-oven Testmentioning

confidence: 99%

Experimental investigation on the self-ignition behaviour of coal dust accumulations in oxy-fuel combustion system

Huang

Norman

et al. 2015

Fuel

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“…It should be noted that the reaction order, n, is mainly affecting the shape of DTG curves instead of the peak temperatures, so called shape factor . The mass fraction at the DTG peak can be determined by rewriting Equation as:

1 - α_{c p ((), p)} = {(\frac{1}{n})}^{\frac{1}{n - 1}} .

…”

Section: Mathematical Analysismentioning

confidence: 99%

“…Because of the range of kinetic properties, selection of the appropriate set of values is needed. The determination of kinetic properties by graphical techniques such as model-free methods can be difficult and its results are questionable for CFD modelling [11].Therefore, since the late 1990s, with the constant improvement of computational capability, several effective property estimation methods and software such as the genetic algorithms (GA) [12,13], PEAKFIT [14] and least-squares method [15,16] have been developed to allow improved kinetic properties estimation. Subsequently, new decomposition models such as the multi-component model [10] and the distributed activation energy model [17] have also been developed.…”

mentioning

confidence: 99%

“…The 'uniqueness' of the kinetic properties for different heating rates has been directly challenged recently [18]. Besides, in order to use the enhanced property estimation methods, a set of search regions need to be specified for the kinetic properties, which are usually user defined or based on literature values which are material specific.Recently, a new technique, so called 'K-K' method [11], is developed to fast and accurately predict the material pyrolysis kinetics. The technique is highly efficient, faster than regular optimized searches alone in kinetic properties determination.…”

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confidence: 99%

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Pyrolysis of polyurethane foam: optimized search for kinetic properties via simultaneous K–K method, genetic algorithm and elemental analysis

Pau²,

Zhang

2015

Fire and Materials

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SUMMARYThis study focuses on the determination of kinetic properties for non-fire retardant (NFR) and fire retardant (FR) polyurethane foams. Based on the experimental thermogravimetric (TG) curves, this paper describes the application of an in-depth mathematical analysis and genetic algorithm (GA) to produce the kinetic properties. A recent developed technique, K-K method, is used for calculating kinetic properties and determining the search regions of these properties for GA. Elemental analysis is also used to study the pyrolysis mechanism. Three decomposition models were investigated for comparison, and the results show that the decomposition model with three sub-reactions achieves the closest representation with experimental results. In the model, two sub-reactions capture the foam and melt decompositions, and another sub-reaction with relatively lower activation energy captures the early onset of foam decomposition. The kinetic properties of melt decomposition are found similar because of the similarity of melt chemical formulas and decomposition of NFR and FR foams. The kinetic properties of foam decomposition between NFR and FR foams are different because of the mechanism of FR additives. Validation of the successive and parallel reaction schemes shows no noticeable difference between the two schemes in the modelling decomposition.

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Pyrolysis of Medium-Density Fiberboard: Optimized Search for Kinetics Scheme and Parameters via a Genetic Algorithm Driven by Kissinger’s Method

Cited by 170 publications

References 30 publications

A methodology for predicting and comparing the full‐scale fire performance of similar materials based on small‐scale testing

A methodology for predicting and comparing the full‐scale fire performance of similar materials based on small‐scale testing

Experimental investigation on the self-ignition behaviour of coal dust accumulations in oxy-fuel combustion system

Pyrolysis of polyurethane foam: optimized search for kinetic properties via simultaneous K–K method, genetic algorithm and elemental analysis

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