Wet Torrefaction of Biomass – Production and Conversion of Hydrochar
Abstract
Biomass is a renewable and carbon neutral energy resource which has a high
potential for replacing fossil fuels. However, the use of biomass for energy
applications is not straightforward. It is because native solid biomass fuels are
highly bulky and inhomogeneous. They normally have higher moisture content,
inferior heating value, and poorer grindability, compared to coal. These drawbacks
limit the use of biomass as fuel. Pretreatment of biomass via chipping and/or
pelletizing for example is therefore a common practice in order to overcome the
drawbacks. This operation adds more costs to biomass fuels, but improvements in
the fuel properties are limited.
Wet torrefaction (WT) is a promising method for pretreatment of biomass for use
as fuel. The method involves the use of hot compressed water, within 180–260 °C
approximately, as reaction medium. Like dry torrefaction (DT), which may be
defined as mild thermal treatment of biomass within 200–300 °C, WT improves
significantly the fuel properties of biomass. In addition, due to the use of water as
reaction medium, WT is highly suitable for low cost biomass sources such as forest
residues, agricultural wastes, and aquatic energy crops, which normally have very
high moisture content.
This PhD was carried out to technically assess the WT process as a pretreatment
method for production of advanced solid biofuel, hydrochar, from forest residues, a
low cost biomass resource in Norway.
As the first step, stem woods from Norway spruce (softwood) and birch
(hardwood) were tested as feedstocks. This choice made it possible to compare with
the results from previous studies on DT of biomass using identical feedstocks. WT
experiments were carried out using a bench‐top autoclave reactor of 250 ml in
volume from Parr Instrument, with nitrogen as purge gas. Effects of various WT process parameters on the yield and the fuel properties of hydrochar (solid fuel
obtained from biomass WT) were examined. The pyrolysis and combustion
reactivity of hydrochar, produced under various WT conditions, was studied
thermogravimetrically by means of a Mettler Toledo TGA/SDTA 815e. Multipseudo‐
component models with different reaction orders were adopted for kinetic
modelling and extraction of the kinetic parameters from these thermochemical
conversion processes of hydrochars. Effects of WT on the kinetics were also
discussed.
In the second step, forest residues were used as feedstock, employing similar
approaches as in the first step. In addition, carbon dioxide was tested as purge gas
and compared with nitrogen for evaluating the possibility to use and recover heat
of the flue gas from combustion plants.
Finally, the pelletability of hydrochar from forest residues was investigated and
compared with that of untreated feedstock. The pelletization was performed using
a single pellet press. Different compressing pressures (20, 40, 80, 160, 240 MPa) and
temperatures (120, 180 °C) were applied to produce pellets. The pellet strength was
then tested via diametric compression test, employing a 60 mm diameter probe
connected to a Lloyd LR 5K texture analyzer. Effects of WT on the mass density,
energy density and mechanical strength of the pellet were investigated.
The major findings from the studies reported in this PhD are:
· Both reaction temperature and holding time have significant effects on the
mass yield, energy yield, and fuel properties of the hydrochar.
· Pressure also enhances the torrefaction rate; however, the effect becomes
marginal above a certain pressure.
· Feedstock particle size slightly affects the yield and fuel properties of the
hydrochar.
· Ash content of biomass fuel is significantly reduced by WT.
· Given the same solid yields, WT requires significantly lower torrefaction
temperatures and shorter holding times than DT.
· Given the same solid yields, solid biomass fuels upgraded via WT have
greater heating values than via DT.
· Hardwood is more reactive and produces less hydrochar than softwood
in identical WT conditions.
· Forest residues are more reactive than stem woods in identical WT
conditions.
· WT in CO2 enhances the torrefaction process, but reduces the heating
value of hydrochar, compare to WT in N2.
· The pellets made from wet‐torrefied forest residues are more
compressible and mechanically stronger than the pellets made from raw
forest residues.
· Overall, WT has positive effects on the fuel properties of biomass.
Has parts
Paper 1: Bach, Quang Vu; Tran, Khanh-Quang; Khalil, Roger Antoine; Skreiberg, Øyvind; Seisenbaeva, Gulaim. A comparative assessment of wet torrefaction. Energy & Fuels 2013 ;Volum 27.(11) s. 6743-6753 http://dx.doi.org/10.1021/ef401295w ©2013 American Chemical SocietyPaper 2: Bach, Quang Vu; Tran, Khanh-Quang; Skreiberg, Øyvind; Khalil, Roger Antoine; Phan, N. Anh. Effects of wet torrefaction on reactivity and kinetics of wood under air combustion conditions. Fuel 2014 ;Volum 137. s. 375-383 http://dx.doi.org/10.1016/j.fuel.2014.08.011 This article is reprinted with kind permission from Elsevier, sciencedirect.com
Paper 3: Bach, Quang Vu; Tran, Khanh-Quang; Skreiberg, Øyvind; Trinh, Thuat. Effects of Wet Torrefaction on Pyrolysis of Woody Biomass Fuels. Energy 2015 http://dx.doi.org/10.1016/j.energy.2015.05.062 This article is reprinted with kind permission from Elsevier, sciencedirect.com
Paper 4: Quang‐Vu Bach, Khanh‐Quang Tran, Øyvind Skreiberg. Torrefaction of forest residues in subcritical water
Paper 5: Bach, Quang Vu; Tran, Khanh-Quang; Skreiberg, Øyvind; Khalil, Roger Antoine. Effects of CO2 on wet torrefaction of biomass. Energy Procedia 2014 ;Volum 61. s. 1200-1203 http://dx.doi.org/10.1016/j.egypro.2014.11.1055 This article is reprinted with kind permission from Elsevier, sciencedirect.com
Paper 6: Bach, Quang Vu; Misljenovic, Nevena; Tran, Khanh-Quang; Salas Bringas, Carlos; Skreiberg, Øyvind. Influences of wet torrefaction on pelletability and pellet properties of Norwegian forest residues. Annual Transactions - The Nordic Rheology Society 2014 ;Volum 22.(1) s. 61-68