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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 50, 2016 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Katharina Kohse-Höinghaus, Eliseo Ranzi
Copyright © 2016, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-41-9; ISSN 2283-9216 

Devolatilization and Fragmentation of Solid Lignin-rich 
Residues from Bioethanol Production in Lab-scale Fluidized 

Bed Reactors  
Roberto Solimene*a, Antonio Cammarotaa, Riccardo Chironea, Paolo Leonib, 
Nicola Rossib, Piero Salatinoc 
aIstituto di Ricerche sulla Combustione - Consiglio Nazionale delle Ricerche P.le V. Tecchio, 80, 80125, Naples, Italy 
bEnel Ingegneria e Ricerca S.p.A, Via Andrea Pisano 120, 56122 Pisa, Italy 
cDipartimento di Ingegneria Chimica, dei Materiali e della Produzione Industriale  - Università degli Studi di Napoli Federico 
II P.le V. Tecchio, 80, 80125, Naples, Italy 
solimene@irc.cnr.it 

The waste stream of second generation bioethanol production plant mainly consists of lignin - a polymer of 
several units of not fermentable phenylpropane - coming from lignocellulosic biomasses. This stream can be 
used only partly to energetically support the process of bioethanol production (about 40%), whereas the fate of 
the remaining 60% has to be found. Fluidized bed combustion technology can be considered as a viable 
option to recover thermal power from this waste stream. However, the understanding of the mechanisms of 
thermo-conversion and attrition of these lignin-rich particles in fluidized beds is scarce and it deserves further 
investigations. To this end, the combustion of lignin-rich residues were studied in lab-scale fluidized beds with 
the aid of different diagnostic and experimental protocols to analyze devolatilization, char burn-out and 
fragmentation of single fuel particles. Comparing devolatilization times with transversal mixing time of typical 
industrial-scale fluidized bed combustors, wet fuel particles larger than 10mm can be fed directly to the 
combustor chamber, whereas pre-dried fuel was extremely reactive with the risk of localized emissions of heat 
and micro- and macro-pollutants once fed to the fluidized bed reactors. Particles do not undergo primary 
fragmentation, whereas probably secondary and not percolative fragmentation occurs during the late stage of 
char burn-out.  

1. Introduction 

The deployment and the exploitation of alternative fuels became more and more relevant to reduce the 
emissions of greenhouse gases and to limit the dependence on countries supplying fossil fuels. In this 
perspective, the Community legislation regulated, with the 209/28 EC Directive, the minimum amount of 
biofuel at 10% for automotive fuels by 2020. OECD estimates predict that the production of second-generation 
bioethanol, i.e. ethanol produced from lignocellulosic biomass and scraps of agricultural crops will be of 155 
billion litres by 2020. The composition of lignocellulosic biomass is typically: cellulose (35-45%), hemicellulose 
(25-30%) and lignin (25-30%). The cellulose and hemicellulose are made of fermentable sugars, while the 
lignin is a polymer consisting of several units of not fermentable phenylpropane. As a consequence, the 
residues of second generation bioethanol production, typically the solid residues after ethanol distillation and 
separation, are characterized by high lignin content. These residues can be used only in part to energetically 
support the process of bioethanol production (about 40%), whereas the fate of the remaining 60% has to be 
found. These lignin-rich residues can be exploited for the production of some chemicals (Ragauskas et al., 
2014), as well as in thermochemical processes like combustion (Eriksson and Kjellström, 2010; Ren et al., 
2015), co-combustion (Buratti et al., 2015), gasification (Barisano et al., 2013) or pyrolysis (De Wild et al., 
2014). Fluidized bed combustion technology can be considered as a viable option to recover thermal power 
from this waste stream. However, the understanding of the mechanisms of conversion and attrition of lignin-
rich particles coming from a second-generation bioethanol production plant in fluidized beds is scarce and it 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1650014

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Solimene R., Cammarota A., Chirone R., Leoni P., Rossi N., Salatino P., 2016, Devolatilization and fragmentation of 
solid lignin-rich residues from bioethanol production in lab-scale fluidized bed reactors, Chemical Engineering Transactions, 50, 79-84 
DOI: 10.3303/CET1650014 

79



deserves further investigations. To this end, the combustion of these lignin-rich residues were studied in lab-
scale fluidized beds with the aid of different diagnostic and experimental protocols to analyze devolatilization, 
char burn-out and fragmentation of single fuel particles. Devolatization experiments based on the analysis of 
the time-resolved CO2 concentration were carried out to characterize the devolatilization process considering 
both wet and pre-dried fuel particles. Fragmentation and char burn-out experiments were performed using the 
basket technique retrieving fragmented and un-fragmented particles from the fluidized bed after 
devolatilization (primary fragmentation) and after char burn-out (secondary or percolative fragmentation). 

2. Experimental 

A stainless steel atmospheric bubbling fluidized bed combustor 41 mm ID and 1 m operated at 1123K was 
used for lab-scale devolatilization, fragmentation and combustion experiments (Figure 1). Two different 
configurations of the reactor were used for the experimental tests. In the first configuration (Figure 1A), used 
for particle fragmentation experiments, the top section of the fluidization column was left open to the 
atmosphere. A stainless steel circular basket could be inserted from the top in order to retrieve fragmented 
and un-fragmented particles from the bed. The second configuration (Figure 1B), used for single particle 
combustion/devolatilization experiments and char burn-out/fragmentation experiments, also consisted in 
leaving open the top section of the fluidization column. A stainless steel probe was inserted from the top of the 
column in order to convey a fraction of the exit gases directly to the gas analyzers. The analysis of the time-
resolved CO2 concentration was used to characterize both the devolatilization process considering wet and 
pre-dried fuel and char burn-out. The details of the experimental apparatus and procedures are reported in 
previous published works (Scala et al., 2000; Chirone et al., 2008; Solimene et al., 2010). The properties of 
the investigated fuel are reported in table 1 in terms of lower heating value, proximate and ultimate analysis, 
metal and components analysis.  

 

 

 

 

 

 

Figure 1: The experimental apparatus for devolatilization/fragmentation characterization: A) basket-equipped 
configuration; B) open-top configuration. 

Table 1: Properties of lignin-rich residues 

LHV (as received), kJ/kg  5645 Metal analysis (dry basis), %w
Proximate analysis (as received), %w Al 0.36 
Moisture 60.7 Ca 0.30 
Volatile matter 25.0 Fe 0.17 
Fixed carbon 8.1 Mg 0.07 
ash 6.1 P 0.07 
Ultimate analysis (dry basis), %w Si 1.12 
Carbon 47.0 Na 0.26 
Hydrogen 5.4 Ti 0.02 
Nitrogen 1.2 Components (dry basis), %w 
Sulphur 0.1 extractives 18.1 
Chlorine 0.0 lignin 57.9 
ash 15.6   
Oxygen (by difference)  30.6   
The lignin content was obtained by Klason method. Silica sand was used as bed material in the size range 
0.30-0.42mm. Some experiments with configuration-B experimental apparatus were carried out using a video 

80



camera to visualize the bed surface during the combustion of both wet and pre-dried single fuel particles in 
order to characterize the phenomenology of the thermo-conversion of lignin-rich solid residues.  

3. Results and discussion 

3.1 Phenomenology 
Figure 2 reports a sequence of snapshots of the surface of fluidized bed captured during the thermal 
conversion of both a wet (figures 2a, b, c and d; particle size 12mm) and a pre-dried (figures 2e, f, g and h; 
particle size 7.5mm before drying) fuel particle at a fluidization velocity of 0.4m/s using air as fluidizing gas. 
The analysis of the images allows to observe the thermo-conversion process since the fuel particle 
periodically appeared on the bed surface: it had a dark colour during drying and devolatilization stage (particle 
temperature smaller than that of the bed) while it was characterized by a bright colour during char combustion 
being its temperature larger than bed temperature. On the whole, it can be highlighted the following sequence 
of events during the combustion of a wet lignin particle: 1) once fed the particle inside the bed, it was not 
evident the presence of flames around it (t=2.2s); 2) small intermittent flames appeared nearby the particle 
without entirely enveloping the particle (t=4.5s and 14.3s); 3) once the devolatilization step was finished 
(t=69s), char combustion takes place: during this stage fragmentation phenomena were not evident. The 
phenomenology observed during the conversion of the dry lignin particle (see figures 2e, f, g and h) is similar 
to that highlighted for the wet fuel particle. However, the following differences have to be underlined: 1) 
devolatilization step began just once the particle was fed to the fluidized bed (t=2s); 2) volatiles flames were 
wide and intense completely inclosing the particle and generating a large amount of soot (t=2s and t=4s). Char 
burn-out of the pre-dried fuel particle did not present qualitatively significant differences with respect to wet 
fuel case (t=10.5s, t=55s and t=98.7s).  
Ash particles of lignin-rich residues separated from bed material and collected at the end of the tests were 
analysed by SEM-EDX methodology and two images are reported in figure 3 referring to ash particles 
obtained after the combustion of wet and pre-dried fuel particles. It can be observed that: i) the shape of the 
ash particles was similar to that of the mother particle; ii) the structure presented a significant macroporosity 
with a more compact shell and a large void in the center of the particles; iii) the size of the pores in the outer 
shell was such to be penetrated by the bed material. On the whole, it seems that the ash particles are 
characterized by a very fragile structure much similar to that observed in the case of sewage sludge ash 
particles (Solimene et al., 2010; Urciuolo et al., 2012). EDX analysis shows a metal composition similar to that 
of the native fuel. Ash particles obtained during combustion tests carried out with wet and pre-dried fuel do not 
present significant differences in terms of both physical and chemical features.  

  
Figure 2: Bed surface images during the thermo-conversion of a single fuel particle at a fluidization velocity of 
0.4m/s using air as fluidizing gas. a-d) 12mm wet fuel particle; e-h) pre-dried fuel particle of 7.5mm diameter 
before drying. 

3.2 Primary fragmentation and devolatilization  
Primary fragmentation experiments show that wet fuel particles do not undergo fragmentation during 
devolatilization, as matter of fact the multiplication factor (Nout/Nin, number of particles collected by basket 
divided the number of particles fed to the reactor) remains equal to 1 whereas a particle shrinkage of about 
78% was observed. The level of particle shrinkage is comparable with that obtained when particles were dried 
in oven, indicating that it is likely that the particle shrinkage during particle devolatilization in the fluidized bed 
is related to the drying stage rather than to the pyrolysis process.  

81



 

Figure 3: SEM images of cross sections of ash particles obtained after the combustion of wet and pre-dried 
fuel particles 

Figure 4 shows the time-resolved CO2 concentration profiles measured at the exhaust during the combustion 
of a both wet and pre-dried fuel particle. The sizes of the wet and of the pre-dried particle before drying stage 
were 10 and 9.5mm, respectively. These profiles can be analyzed to achieve in-situ the main characteristics of 
the devolatilization and char burn-out of fuel particles in fluidized bed reactors (Chirone et al., 2008). Two main 
steps can be distinguished: 1) an initial step just after particle injection characterized by a pronounced peak 
related to the progress of fuel devolatilization; 2) a final step corresponding to the combustion of the residual 
char. The CO2 concentration time series can be deconvoluted into these two sequential steps in order to 
estimate the characteristic times of devolatilization and char burn-out. To this end, it was assumed the CO2 
release as the convolution of two Gaussian-like probability distribution functions. The time instant t=0 and that 
of the end of devolatilization t=td were chosen as upper and lower limits of the time interval, centred around 
the maximum value, where the 95% of probability falls. From the analysis of figure 4, it is evident the peak 
associated to the combustion of volatile matter followed by a slow decay of CO2 concentration due to the char 
combustion 

 

Figure 4: Time-resolved CO2 concentration profile during the devolatilization and char combustion of a both 
wet and pre-dried fuel particle.  

The comparison between the time-resolved CO2 concentration profiles obtained with wet and pre-dried fuel 
particles highlights in quantitative way what it was observed qualitatively in the phenomenology section by 
visive observation of bed surface during fuel conversion. Specifically, it can be observed: 1) devolatilization of 
pre-dried fuel particle was quicker and, in turn, the CO2 concentration reached larger values in a very short 
time interval; 2) the complete conversion time (combustion of volatiles + char combustion) remained constant. 
It is likely that the drying step of the wet fuel particle takes place in parallel with the fuel pyrolysis with the 
obvious consequence of reducing the temperature of both pyrolysis and combustion of volatile matter and of 
increasing the duration of drying/devolatilization step. On the other hand, the devolatilization step of the pre-
dried fuel and the combustion of volatile matter are not mitigated by the vaporization of the moisture present in 
the fuel generating a char less porous and reactive than that achieved by the wet fuel. Overall, the overall 
complete combustion time for the pre-dried fuel is similar to that of the wet fuel, whereas td estimated by the 
analysis of data present in figure 4 are 70 and 20s for the wet and the pre-dried fuel particle, respectively. 

time,s

0 50 100 150 200 250

C
O

2
 c

o
n

c
e
n

tr
a

ti
o

n
,%

v

0

2

4

6

8

10

12

0 50 100 150 200 250

a) wet particle φ10mm b) pre-dried particle φ9.5mm

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Devolatilization time plays an important role for the localization and release pattern of volatile matter during 
fluidized bed combustion of solid fuels and, as a consequence, for the even heat release inside the reactor as 
well as the generation of macro- and micro-pollutants (Aprea et al., 2013; Solimene et al., 2010; Solimene et 
al., 2012). The comparison of devolatilization time with the transversal mixing time of typical industrial-scale 
fluidized bed combustors sheds light on the distribution of volatiles along the transversal section of the reactor. 
For instance, short devolatilization times determine a release of volatile matter localized nearby the feeding 
point of the solid fuel. The transversal mixing time (tmix) can be estimated on the basis of the transversal sizes 
of the reactor (Lx, Ly): 

r

yx
mix

D

LL
t

4
≅  (1) 

where Dr is the transversal dispersion coefficient evaluated by different diagnostic techniques for coarse 
particle like fuel particles in the order of 0.12 m2/s. Taking into account the typical transversal size of industrial 
fluidized bed combustors, tmix is in the order of 100s. As a consequence, the comparison of devolatilization 
times of lignin-rich fuel particles with transversal mixing time of typical industrial-scale fluidized bed 
combustors highlights that: 1) wet fuel particles larger than 10mm fed directly to the combustor chamber 
should generate a rather uniform distribution of volatile matter along the transversal size of the reactor; 2) the 
dry fuel is extremely reactive and once fed to the fluidized bed it could generated localized emissions of heat 
and micro- and macro-pollutants.  

3.3 Char combustion 
Char particles obtained by means of the procedure of primary fragmentation (fluidization velocity 0.8m/s, 
fluidizing gas nitrogen) and without undergoing fragmentation, were used for the tests of char burn-out and 
secondary or percolative fragmentation. The tests were carried out at a fluidization velocity of 0.8m/s using as 
fluidizing gas a mixture of nitrogen/air at a concentration of O2 of 4.5%v. The time-resolved CO2 and CO 
concentration profiles at the exhaust during the conversion of a single fuel particle were measured and 
elaborated. The carbon conversion was obtained as a function of time by means of: 

( )
0

')'()'(
)( 2

c

t

o
COCOc

c
W

dttCtCQM
tX

 +=  (2) 

 where, Mc, Q, CCO2, CCO and Wc0 are carbon molecular weight, the inlet fluidizing gas flow rate, CO2 
concentration, CO concentration and the initial carbon content of the char particle. This latter is calculated as 
the difference between the mass of the injected char particle and the ash mass of the parent particle. The ash 
particles after the complete conversion of the single char particle were retrieved by the basket technique in 
order to investigate char fragmentation phenomena.  

 

Figure 5: Time series of the CO2 concentration measured at the exhaust and of the carbon conversion during 
a test of char burn-out of a single particle of about 9.3mm. Fluidization velocity: 0.8m/s; fluidizing gas: a 
mixture of nitrogen and air with O2 concentration of 4.5%v. 

Figure 5 reports the time-resolved CO2 concentration and carbon conversion profiles measured during a 
typical test carried out with a char particle of about 9.3mm. The time series in figure 5 shows that: 1) the 
carbon conversion initially increased almost linearly with time (CO2 concentration slowly decreased with time); 

time, s

0 200 400 600

C
a

rb
o

n
 c

o
n

v
e

rs
io

n
 (

X
c
),

 -

0.0

0.2

0.4

0.6

0.8

1.0

C
O

2
 c

o
n

c
e

n
tr

a
ti

o
n

, 
%

v

0.00

0.02

0.04

0.06

0.08

0.10

0.12

0.14

Xc
CO2 concentration

83



2) a change of slope was observed at about 470-480s (a maximum of CO2 concentration was correspondingly 
observed); 3) the carbon conversion stabilized at a value of about 0.94 (CO2 concentration reached the 
baseline value). It is worth to note that 24 ash fragments were collected at the end of the run. On the whole, 
the analysis of these results highlights that: 1) char particle conversion is initially controlled by external 
diffusion; 2) it is likely that particle fragmentation occurs in the late stage of particle conversion at about 70%; 
3) carbon elutriated with fine particles accounts for about 6% and it is probably related to the event of char 
fragmentation. It is worth to note that the observed char fragmentation depends on fluidization velocity 
because it was noted at fluidization velocity of 0.8m/s but it was not observed in previous experiments carried 
out at 0.4m/s. As a consequence, the char fragmentation can be considered secondary and not percolative, as 
a matter fact, this latter, differently from that observed, does not depend on fluidization velocity.  

4. Conclusions 

The fluidized bed combustion of lignin-rich residues coming from a second generation bioethanol production 
plant were investigated in lab-scale fluidized beds with the aid of different diagnostic and experimental 
protocols to analyze devolatilization, char burn-out and fragmentation of single fuel particles. The comparison 
of devolatilization times with transversal mixing time of typical industrial-scale fluidized bed combustor pointed 
out that wet fuel particles larger than 10mm can be fed directly to the combustor chamber, whereas pre-dried 
fuel was extremely reactive with the risk of localized emissions of heat and micro- and macro-pollutants once 
fed to the fluidized bed reactor. Fuel particles do not undergo primary fragmentation, whereas probably 
secondary and not percolative fragmentation occurs during the late stage of char burn-out.  

Acknowledgments 

The support of Mr. Alfonso Vitagliano in the set-up of the experimental apparatus and in the experimental 
campaign and the support of Miss Paola Brachi in the biomass components analysis is gratefully 
acknowledged. 

References 

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biomass combustion in a pilot scale fluidized bed combustor, Chemical Engineering Transactions 32, 
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