| Revue: | Maderas : ciencia y tecnología |
| Base de datos: | |
| Número de sistema: | 000544588 |
| ISSN: | 0718-221X |
| Autores: | Pétrissans, A1 Younsi, R2 Chaouch, M3 Gérardin, P1 Pétrissans, M1 |
| Instituciones: | 1Université de Lorraine, LERMAB, Vandoeuvre les Nancy. Francia 2École Polytechnique de Montréal, Département de Génie Mécanique, Montréal. Canadá 3SEREX, Québec. Canadá |
| Año: | 2014 |
| Periodo: | May |
| Volumen: | 16 |
| Número: | 2 |
| Paginación: | 133-148 |
| País: | Chile |
| Idioma: | Inglés |
| Resumen en inglés | Wood heat treatment is an attractive alternative to improve decay resistance of low natural durability of wood species. Decay resistance is strongly correlated to thermal degradation of wood cell wall components. Some recent studies proposed the use of wood mass loss during the heat treatment as a valuable marker to predict final properties of the material (Hakkou et al. 2006, Welzbacher et al. 2007). In this study, heat treatment was carried out in a relatively low temperature (230˚C). Mass loss kinetics was studied using equipment, specially conceived to measure sample’s mass during the thermal treatment. Laboratory experiments were performed for heating rates of 1˚C min-1. Mathematical model for kinetics of pyrolysis process was used and validated. During the pyrolysis of dry wood samples under inert atmosphere, measurements of temperature distribution and dynamic weight loss were performed. Five different wood species Fagus sylvatica (Beech), Populus nigra (Poplar), Fraxinus excelsior (Ash), Pinus sylvestris (Pine) and Abies pectinata (Silver Fir) were investigated. The unsteady-state mathematical model equations were solved numerically using the commercial package Femlab 2.0. A detailed discussion of the computational model and the solution algorithm is given. The validity of different model assumptions was analyzed. Experimental results were compared with those calculated by the model. Acceptable agreement was achieved. |
| Keyword: | Heat treatment, Modeling, Reaction kinetics, Thermodegradation, Wood |
| Texte intégral: | Texto completo (Ver HTML) Texto completo (Ver PDF) |
