Biomass
for energy production has been extensively studied in the recent years.
To overcome some constraints imposed by the chemical–physical
properties of the biomass, several pretreatments have been proposed.
Torrefaction is one of the most interesting pretreatments because
torrefied biomass holds a wide range of advantages over raw biomass.
The devolatilization of water and some oxygenated compounds influences
the increase in the calorific value on both a mass and volumetric
basis. The increase in the density reduces the transportation costs.
Moreover, the decreased moisture content increases the resistance
of biomass to biological degradation, thus facilitating its storage
for long periods. Under torrefaction conditions, approximately 10–40
wt % of the initial biomass is converted into volatile matter, including
liquid and non-condensable combustible gases. The energy efficiency
of the process could greatly benefit the exploitation of the energy
content of these products. Recent studies and technological solutions
have demonstrated the possibility to realize polygeneration systems
that integrate torrefaction/pyrolysis to a combustion process with
the aim of obtaining torrefied material/biochar and/or energy from
biomass. Some examples include Pyreg, Pyreg-Aactor GT, TorPlant, and
Top Process. The identification of the main volatiles produced under
the torrefaction regime is useful for the optimization of the operating
conditions of the integrated system. The integrated process raises
some concerns when biomass from phytoremediation and wood from demolition
and construction activities are used as feedstock because they could
contain potential toxic elements (PTEs). During the torrefaction treatment,
the fate of PTEs should be controlled to avoid their release in the
gas phase and to evaluate the extent of their concentration in the
torrefied biomass. The present work aims at studying torrefaction
as an eco-sustainable process for the combined production of a solid
biofuel with improved characteristics with respect to the starting
material and a combustible vapor phase, embedded in the gas carrier
flow, to be directly burned for energy recovery. Herein, torrefaction
tests on Populus nigra L. branches
from phytoremediation and demolition wood were conducted at three
temperatures, 250, 270, and 300 °C, at a holding time of 15 min.
The energetic content of torrefied materials was determined. At the
same time, the fate of the heavy metals (Cd, Pb, and Zn) in the raw
biomass at different torrefaction temperatures was studied, and their
mobility in the torrefied biomass was investigated and compared to
the mobility in the raw biomass.
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