Slow pyrolysis of CCB-treated wood for energy recovery: Influence of chromium, copper and boron on pyrolysis process and optimization

•CCB salts inhibit the thermal conversion of treated wood and decrease their degradation temperature.•Maximum degradation temperature of CCB-treated wood was observed at 300°C and 370°C.•CCB salts promote the formation of H2.•45% of charcoal, retaining 80% of metals, was produced by pyrolysis at 300...

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Bibliographic Details
Published in:Journal of analytical and applied pyrolysis 2013-11, Vol.104, p.210-217
Main Authors: Kinata, Silao Espérance, Loubar, Khaled, Paraschiv, Maria, Bouslamti, Amine, Belloncle, Christophe, Tazerout, Mohand
Format: Article
Language:English
Subjects:
boron
byproducts
carbon dioxide
carbon monoxide
CCB
charcoal
chromium
copper
copper sulfate
energy recovery
Engineering Sciences
gas chromatography
gases
hydrogen
mass spectrometry
Pyrolysis
softwood
temperature
Thermogravimetric analysis
thermogravimetry
Treated wood
Waste management
weight loss
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Summary:•CCB salts inhibit the thermal conversion of treated wood and decrease their degradation temperature.•Maximum degradation temperature of CCB-treated wood was observed at 300°C and 370°C.•CCB salts promote the formation of H2.•45% of charcoal, retaining 80% of metals, was produced by pyrolysis at 300°C and 30min of residence time. This paper investigates the effect of copper, chromium and boron on the slow pyrolysis of CCB-treated wood. A mixture of softwood has been impregnated with several inorganic salts (individually CuSO4, KCr(SO4)2, B4Na2O7) and with salt of CCB (mixture of CuSO4, KCr(SO4)2 and H3BO3). The weight loss of samples is identified by thermogravimetric analysis (TGA). The results show a higher mass of final residue and a decrease in degradation temperature on treated wood compared to untreated wood. TGA results also show that, the maximum degradation of CCB treated wood occurs at 300°C. In addition, slow pyrolysis experiments were carried out in a laboratory scale reactor. The pyrolysis products were quantified using analytical balance whereas gases were analyzed by gas chromatography. The trends of weight loss obtained by TGA and by laboratory scale pyrolysis are similar. Furthermore, it is observed that CCB salts inhibit the formation of CO and CO2 but promote that of H2. In the second part of this work, yield of solid pyolysis residue (charcoal) with a high metal content (Cu, Cr, B) has been carried out at 300°C and 370°C during residence time of 20 and 30min. Metals in charcoal are analyzed using Inductively Coupled Plasma Mass Spectrometry. Taking into account the energy recovery of by-products, slow pyrolysis at 300°C and 30min appears to be optimal conditions with a high yield of charcoal about 45% and the element recovery is up to 94% of Cu, 100% of Cr and 88% of B.
ISSN:0165-2370
1873-250X
DOI:10.1016/j.jaap.2013.08.002