An enthalpy-temperature hybrid method for solving phase-change problems and its application to polymer pyrolysis and ignition

Zhou, Yong; Fernandez‐Pello, A. C.

doi:10.1088/1364-7830/4/4/306

Cited by 16 publications

(7 citation statements)

References 26 publications

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“…A model that includes melting has been developed and used to successfully predict the time to ignition of a polypropylene/glass composite [192]. More recently, polymer melt flow behavior in laboratory-scale experiments has been modeled with encouraging results [190].…”

Section: Special Topics: Melting Bubbling and Related Phenomenamentioning

confidence: 99%

Generalized pyrolysis model for combustible solids

Lautenberger

Fernandez-Pello

2009

Fire Safety Journal

307

259

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This dissertation presents the derivation, numerical implementation, and verification/validation of a generalized model that can be used to simulate the pyrolysis, gasification, and burning of a wide range of solid fuels encountered in fires. The model can be applied to noncharring and charring solids, composites, intumescent coatings, and smolder in porous media. Care is taken to make the model as general as possible, allowing the user to determine the appropriate level of complexity to include in a simulation. The model considers a user-specified number of gas phase and condensed phase species, each having its own temperature-dependent thermophysical properties.Any number of heterogeneous (gas-solid) or homogeneous (solid-solid or gas-gas) reactions can be specified. Both in-depth radiation transfer through semi-transparent media and radiation transport across pores are considered. Volume change (surface regression or swelling/intumescence) is handled by allowing the size of grid points to change as dictated by mass conservation. All volatiles generated inside the solid escape to the ambient with no resistance to mass transfer unless a pressure solver is invoked; the resultant flow of volatiles is then calculated according to Darcy's law. A gas phase 2 convective-diffusive solver can be invoked to determine the composition of the volatiles.Oxidative pyrolysis is simulated by modeling diffusion of oxygen from the ambient into the pyrolyzing solid where it may participate in reactions. Consequently, the mass flux and composition of volatiles escaping from the solid can be calculated. To aid in determining the required input parameters, the model is coupled to a genetic algorithm that can be used to estimate the required input parameters from bench-scale fire tests or thermogravimetric analysis.

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Section: Special Topics: Melting Bubbling and Related Phenomenamentioning

confidence: 99%

Generalized pyrolysis model for combustible solids

Lautenberger

Fernandez-Pello

2009

Fire Safety Journal

307

259

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“…45 This method does not need to use a solid/liquid interface and thus, to calculate specific boundary conditions at this interface. Moreover, it takes directly into account the local changes in melting temperature in a particles based material.…”

Section: Heat Of Meltingmentioning

confidence: 99%

Kinetic modeling of polypropylene thermal oxidation during its processing by rotational molding

Sarrabi

Colin

Tcharkhtchi

2010

J of Applied Polymer Sci

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ABSTRACT:The main drawback of rotational molding is a long stay (several dozens of minutes) of polymer in melt state at high temperature in atmospheric air. To prevent any significant polymer thermal degradation, it is necessary to define, preliminary, a processing window in a temperature-molar mass map. The objective of this article is to elaborate and check the validity of a general thermal degradation model devoted to determine, in a near future, some important boundaries of this processing window. This model is composed of two distinct levels: (i) The first level is derived from the thermal transfer mechanisms occurring during a processing operation, polymer phase changes (i.e., melting and crystallization) being simulated by the enthalpy method; and (ii) The second level is derived from the oxidation mechanistic scheme of free additive polymer in melt state established in a previous study, but completed, here, by adding the main stabilization reactions of a common synergistic blend of antioxidants, widely used for rotational molding polymer grades. By juxtaposing such ''thermal'' and ''chemical'' levels, it is possible to predict the polymer thermal degradation during a whole processing operation. The validity of both levels is successfully checked in real rotational molding conditions for polypropylene (PP). V C 2010 Wiley Periodicals, Inc. J Appl Polym Sci 118: [980][981][982][983][984][985][986][987][988][989][990][991][992][993][994][995][996] 2010

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“…This method makes it possible to use only one equation to describe thermal phenomenon in both two phases (liquid polymer and solid powder), and makes it possible, thus, to free from the calculation of boundary conditions on liquid/solid interface. It is named enthalpy method [15,16]. If we leave the assumption that melting or crystallization does not occur at a constant temperature, which is more realistic for a particulate solid, enthalpy evolution according to temperature can be schematized as on …”

Section: Enthalpic Methods (Layer By Layer)mentioning

confidence: 99%

“…This study is divided into two main parts, the first one is focused on the rotational moulding of polyamide 11, and the second one is devoted to simulation of thermal transfer phenomenon in rotational moulding and modelling of phase changes by enthalpy method [14][15][16] coupled to Ozawa model [17]. The results obtained allow us to validate the theoretical approach adopted by the experimentation and to observe that the two shutters (theoretical and experimental) are closely dependant.…”

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confidence: 99%

Thermal transfer simulation regarding the rotational moulding of polyamide 11

Hafsaoui

Benziane

Tcharkhtchi

2012

J Therm Anal Calorim

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is an open access repository that collects the work of Arts et Métiers ParisTech researchers and makes it freely available over the web where possible. Abstract Simulation of thermal phenomena in rotational moulding is very important to follow the evolution of the temperature in various zones of this process. It was a question of modelling heat gradients developing in rotational moulding part. Thermal model tested take into account the temperature change (thermal transfer mechanism) of melting and crystallization pseudo-stages (enthalpy method). Series of tests in polyamide 11 (PA11) were carried out by means of rotational moulding STP LAB, and non-isothermal crystallization kinetics of rotational moulding PA11 grade are measured and analysed by DSC technique type TAQ20. A result of non-isothermal crystallization of the studied polyamide was confronted with Ozawa model. In order to test the validity degree of enthalpy method (layer to layer), another approach based on Ozawa model has also been used in the case of cooling pseudo-stage. As results, the rotational moulding of PA11 was successfully carried out. The simulation of the fusion and crystallization stages, by application of Ozawa model coupled with enthalpy method gave a good representation of experimental data.

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An enthalpy-temperature hybrid method for solving phase-change problems and its application to polymer pyrolysis and ignition

Cited by 16 publications

References 26 publications

Generalized pyrolysis model for combustible solids

Generalized pyrolysis model for combustible solids

Kinetic modeling of polypropylene thermal oxidation during its processing by rotational molding

Thermal transfer simulation regarding the rotational moulding of polyamide 11

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