CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 57, 2017 

A publication of 

 
The Italian Association 

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

Guest Editors: Sauro Pierucci, Jiří Jaromír Klemeš, Laura Piazza, Serafim Bakalis 
Copyright © 2017, AIDIC Servizi S.r.l. 

ISBN 978-88-95608- 48-8; ISSN 2283-9216 

Optimal Conditions of Thermal Treatment Unit for the Steam 
Reforming of Raw Bio-oil in a Continuous Two-step Reaction 

System 
Beatriz Valle*, Borja Aramburu, Aingeru Remiro, Aitor Arandia, Javier Bilbao, 
Ana G. Gayubo 
Chemical Engineering Department, University of the Basque Country, P.O. Box 644, 48080, Bilbao, Spain 
beatriz.valle@ehu.es 

The separation of pyrolytic lignin in a previous thermal treatment step is essential for the viability and 
efficiency of the continuous hydrogen production by steam reforming (SR) of raw bio-oil. This work aimed to 
establish the conditions of this thermal step that maximize the bio-oil fraction liable to valorization in the 
subsequent SR reactor, and that lead to a better behavior of the catalyst. The influence that temperature (400-
800 ºC) and steam-to-carbon ratio S/C (1.5-6.0) have on the composition of resulting volatile stream and on 
the solid fraction (pyrolytic lignin) deposition was analyzed by feeding raw bio-oil, and a mixture of raw bio-oil 
and with 20 wt% of ethanol. The thermal treatment temperature affects both the yield of pyrolytic lignin (which 
decreases with temperature, especially in the range 400-500 °C) and its composition (so that the H/C ratio 
decreases as the temperature is higher). The yield of liquid fraction and its total content of oxygenates 
decrease notably above 500 °C. Levoglucosan content decreases, while that of phenols (especially above 
650 °C), carboxylic acids (mainly acetic acid) and acetaldehyde increase markedly as temperature is raised. 
Temperature rise enhances formation of gaseous products (mainly CO and CO2), with H2, CH4 and 
hydrocarbons being promoted above 600 °C. The effect of thermal step temperature on the Ni/La2O3-Al2O3 
catalyst behavior was studied by analyzing the evolution with time-on-stream of bio-oil conversion and product 
yields. Consequently, 500 °C is the thermal treatment temperature that leads to a better compromise between 
H2 yield and catalyst stability, since the resulting oxygenated composition causes less deactivation of the 
reforming Ni/La2O3-Al2O3 catalyst, thereby attaining complete and stable bio-oil conversion and H2 yield 
close to 90 %. 

1. Introduction 

The availability of lignocellulosic biomass and the advantages of obtaining bio-oil through simple and highly 
developed fast pyrolysis technologies (Meier et al., 2013) make the bio-oil a promising renewable raw 
material. The catalytic steam reforming (SR) of bio-oil, which avoids the costly dehydration steps required for 
other valorization strategies, is an interesting route for the sustainable production of hydrogen (Chattanathan 
et al., 2012). However, the direct valorization of raw bio-oil is hampered by its high complexity, corrosivity and 
thermal instability, which makes the long-term storage problematic, creates plugging problems in the reactor 
and affects the catalyst deactivation. Several strategies have been proposed in the literature to address these 
problems, although its satisfactory and scalable solution remains an ongoing challenge. Among the different 
treatments used are: i) Fractionation by molecular distillation at 80 ºC and 100 Pa (Guo et al., 2010); ii) 
Treatment at high pressure (200 bar) and moderate temperatures 200-300 ºC (De Miguel Mercader et al., 
2010) to reduce oxygen and water content; iii) Dehydration-cracking in situ in the pyrolysis reactor, using acid 
catalysts to reduce the concentration of some compounds, such as methoxy-phenols (Atutxa et al., 2005; 
Zhang et al., 2009); iv) In-line transformation by dehydration-cracking with HZSM-5 zeolite catalysts of the 
volatile stream resulting from pyrolysis (French and Czernik, 2010), v) Co-feed with low-cost alcohols 
(methanol, ethanol, butanol), which causes that reactive carboxylic acids and carbonyl compounds of the bio-
oil become their corresponding esters and acetals (esterification) (Moens et al., 2009), thus improving the bio-

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1757035

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Valle Pascual B., Aramburu B., Remiro A., Arandia A., Bilbao J., Gayubo A., 2017, Optimal conditions of thermal 
treatment unit for the steam reforming of raw bio-oil in a continuous two-step reaction system, Chemical Engineering Transactions, 57, 205-
210  DOI: 10.3303/CET1757035 

205



oil quality (acidity, viscosity, corrosivity) (Hilten et al., 2014); vi) Thermal treatment at atmospheric pressure, 
which reduces the concentration of phenols and high molecular weight compounds, which undergo 
repolymerization that lead to the formation of a solid (pyrolytic lignin) (Bertero et al., 2011); vii) In line retention 
of pyrolytic lignin in a thermal treatment step, and conversion of the remaining volatile compounds. This 
strategy is suitable for continuous operation and has been successfully used in processes for obtaining olefins 
(Gayubo et al., 2010), aromatics (Valle et al., 2010) and hydrogen (Remiro et al., 2013) (Figure 1).  

 
Figure 1: Continuous two-step process for the steam reforming of raw bio-oil. 

Therefore, the operation in a continuous two-step reaction system (thermal + catalytic) mitigates the problems 
related to the SR of raw bio-oil, because it enables the controlled deposition of pyrolytic lignin (in the thermal 
treatment unit) prior to the fluidized bed catalytic reactor. Given its importance for the overall process, this 
paper analyses the influence of thermal step operating conditions on the composition of the volatile stream 
that leaves this unit (i.e., feed to catalytic reactor), and on the amount and composition of the lignin deposited. 
The effect of thermal step temperature on the Ni-based catalyst behavior (located in the SR reactor) was also 
studied by analyzing the evolution with time-on-stream of bio-oil conversion and product yields, with the aim of 
establishing the conditions that lead to a better behavior (higher and more stable H2 yield). 

2. Experimental 

2.1 Feed and reaction equipment 

The effect that thermal step temperature (400-800 ºC) and steam-to-carbon ratio S/C (1.5-6.0) have on the 
composition of exiting volatile stream was analyzed by feeding raw bio-oil (C4.0H6.0O2.9), and a mixture of raw 
bio-oil (C3.5H6.1O3.3) with 20 wt% ethanol. The ethanol addition has a stabilizing effect: a low amount (< 5 wt%) 
prevents aging reactions for a few months of bio-oil storage, while higher amounts (≥ 10 wt%) slows them for 
at least one year (Diebold and Czernik, 1997). Both raw bio-oils were obtained by flash pyrolysis of pine 
sawdust in a semi-industrial plant located in Ikerlan-IK4 technology centre (Alava, Spain), with a biomass 
feeding capacity of 25 kg/h. 
The two-step reaction equipment was previously described (Remiro et al., 2013) and consists of a thermal 
treatment unit, which is a U-shaped steel tube where the pyrolytic lignin is deposited (in the inlet side), 
followed by the catalytic fluidized bed reactor, where the thermally treated feed (i.e., the volatile stream leaving 
the thermal step) is reformed over Ni/La2O3-Al2O3 catalyst. The raw bio-oil and the bio-oil/ethanol mixture 
were fed as droplets into the first unit (thermal step) at a feeding rate of 0.1 ml/min (injection pump Harvard 
Apparatus 22) and additional water (that required for setting an S/C ratio) was fed by 307 Gilson pump. The 
catalytic SR step was kept at 700 ºC, S/C = 6, and space-time (W/F0) = 0.27 gcatalysth/gfeed, which are suitable 
conditions to achieve high bio-oil conversion and H2 yield without exorbitant energy cost (Remiro et al., 2013). 

2.2 Reaction indices 

The SR of bio-oil proceeds according to Eq (1), followed by the water-gas-shift reaction (WGS), Eq (2). The 
SR of ethanol reaction is expressed by Eq (3). In addition, secondary reactions such as methanation, thermal 
decomposition, Boudouard reaction and inter-conversion reactions of oxygenates may occur, leading to the 
formation of by-products (CH4, CO/CO2, light hydrocarbons, carbon deposits, other oxygenates). 

CnHmOk + (n - k) H2O  n CO + (n+(m/2) - k) H2 (1) 

CO + H2O  CO2 + H2 (2) 

C2H6O + 3 H2O  2 CO2 + 6 H2 (3) 

The bio-oil and ethanol conversion is quantified from the molar flow-rate that enters and leaves (un-reacted 
bio-oil or ethanol) the catalytic reactor, Eq. (4). The H2 yield is calculated as a percentage of the stoichiometric 
potential of the feed, Eq. (5). The yield of carbon-containing products (CO, CO2, CH4 and C2-C4 hydrocarbons) 
is quantified by Eq. (6).  

ini,

outi,ini,
i

F

FF
X


  (4) 

Thermal
Treatment

Catalytic 
Reforming

Volatile 
stream

Raw 
Bio-oil

Pyrolytic lignin

H2
CO2,CO

206



100 x
F3F

flow molar H
Y

inEtOH,inoil,bio

2

H2

n

km/22n







 (5) 

100 x
FF

HCs),CH,CO(CO, i of flow molar
Y

inEtOH,inoil,bio

42
i






 (6) 

3. Results and discussion 

3.1 Composition of the thermally treated feed 

Table 1 shows the effect of temperature in the thermal treatment unit on the composition of the volatile stream 
that leaves this step, analyzed by gas chromatography (MicroGC Agilent 3000). This stream is composed of 
gaseous products (Total Gas) and condensable products (Total Liquid). The results of Table 1, which 
correspond to the feed of bio-oil/ethanol mixture, reveal an almost exponential growth of gaseous compounds 
as the temperature is raised from 400 to 800 °C, with CO and CO2 being the major products. These 
compounds come from the decarbonylation/decarboxylation reactions of oxygenates, which are promoted by 
increasing temperature. Furthermore, the cracking/decomposition reactions which involve the formation of H2, 
CH4 and light hydrocarbons (mainly ethene) become important above 600 °C. 
Regarding the effect of S/C ratio on the composition of the volatile stream when feeding raw bio-oil at 500 ºC 
(Table 2), it can be observed that an increase of S/C from 1.5 to 3.5 seems to promote the WGS and/or 
reforming reactions in the thermal step at 500 °C, as suggested by the increase of H2 and CO2 content along 
with a decrease of CO, although practically the same gas yield is obtained for both S/C ratios. However, a 
further increase in the S/C ratio up to 6.0 leads to a drastic reduction in the formation of CO/CO2, thereby 
reducing greatly the total gas yield. 

Table 1: Effect of temperature of the thermal step on the composition (wt %) of the product stream. 

Conditions: Feed, bio-oil/ethanol mixture; S/C, 6. 

 400 ºC 500 ºC 600 ºC 700 ºC 800 ºC 
H2 -- -- 0.2 0.3 0.5 
CH4 -- 0.1 0.4 0.9 1.1 
CO 0.3 0.7 2.1 3.6 3.9 
CO2 1.2 1.6 1.8 3.0 4.3 
C2-C4 Paraffins -- -- 0.1 0.1 0.1 
C2-C4 Olefins -- 0.1 0.4 0.8 0.7 
Total Gas 1.6 2.6 5.1 8.8 10.6 
Water 82.6 81.6 81.5 81.3 81.1 
Organics 15.8 15.8 13.4 9.9 8.3 
Total Liquid 98.4 97.4 94.9 91.2 89.4 

Table 2: Effect of S/C ratio of the thermal step on the composition (wt %) of the product stream.       

Conditions: Feed, raw bio-oil; 500 ºC. 

S/C 1.5 3.5 6.0 
H2 0.4 0.8 0.2 
CH4 1.7 1.3 0.4 
CO 16.3 12.7 3.7 
CO2 11.9 15.9 4.0 
C2-C4 Paraffins 0.4 0.3 0.1 
C2-C4 Olefins 1.6 1.8 0.3 
Total Gas 32.2 32.8 8.7 
Water 44.1 52.1 78.0 
Organics 23.7 15.1 13.3 
Total Liquid 67.8 67.2 91.3 

Table 3 shows the effect that the thermal step temperature has on the composition (analyzed by GC/MS 
QP2010 Shimadzu) of the liquid fraction collected after volatile stream condensation, when feeding raw bio-oil 
at S/C = 6. These results evidence the significant effect of raising temperature, especially above 650 °C, with 
the increase in the phenolic compounds content and the decrease in the levoglucosan content being 
particularly notable. A remarkable increase in the content of carboxylic acids (mainly acetic) and acetaldehyde 
is also noticed as the temperature is increased up to 700 °C.  

207



Table 3: Effect of temperature on the concentration of organic compounds (water-free basis) of liquid resulting 

from the thermal step. Conditions: Feed, raw bio-oil; S/C, 6. 

Compounds Raw bio-oil 500 ºC 550 ºC 600 ºC 650 ºC 700 ºC 
Ketones 11.8 10.1 12.8 12.7 20.4 10.8 

acetone 0.4 0.3 0.5 1.0 2.3 2.6 

1-hydroxy-2-propanone 6.4 4.2 6.1 6.8 13.1 6.8 

Acids 25.8 18.5 17.3 23.3 41.1 60.8 
acetic acid 15.3 11.3 13.5 21.1 36.1 55.8 

Esters 7.3 4.3 5.5 4.4 2.8 1.7 
Aldehydes 13.5 4.9 4.9 5.8 9.5 5.2 

acetaldehyde 8.2 0.4 0.9 1.9 5.0 4.7 

Phenols 5.6 4.8 5.2 5.7 13.0 15.3 
Ethers 1.7 0.7 0.4 0.5 1.1 1.0 
Alcohols 7.1 3.9 3.6 2.9 2.9 1.6 
Sugars 27.2 52.9 50.3 44.8 9.2 3.5 

Levoglucosan 24.3 47.7 46.0 41.8 8.3 3.2 

3.2 Effect of thermal step conditions on pyrolytic lignin deposition 

The effect that thermal step temperature has on the yield and composition (expressed as molecular formula 
derived from the elemental analysis) of the pyrolytic lignin (PL) deposited is shown in Table 4, for the feed of 
bio-oil/ethanol mixture at S/C = 6. The effect that S/C ratio has on the PL deposition when feeding raw bio-oil 
at 500 °C is shown in Table 5. The yield of PL deposited (water-free basis) is calculated by Eq. (7). 

100x
(g) fed oil-Bio

(g) deposited lignin Pyrolytic
(wt%) Yield PL   (7) 

Table 4: Effect of temperature on the yield and composition of pyrolytic lignin deposited in the thermal step. 

Conditions: Feed, bio-oil/ethanol mixture; S/C, 6. 

Temperature, ºC PL yield, wt % Composition 
400 12.6 C6.7H3.8O1.0 
500 4.5 C7.5H2.8O0.5 
600 3.5 C7.6H1.9O0.4 
700 2.0 C7.8H1.0O0.3 

Table 5: Effect of S/C ratio on the yield and composition of pyrolytic lignin deposited in the thermal step. 

Conditions: Feed, raw bio-oil; 500 ºC. 

Steam-to-carbon ratio (S/C) PL yield, wt % Composition 
1.5 5.2 C7.1H2.8O0.7 
3.5 4.4 C7.1H2.8O0.7 
6.0 4.2 C7.1H2.8O0.7 

The amount of PL retained and its elemental composition depends to a greater extent on the temperature than 
on the S/C ratio. Thus, the PL yield decreases markedly from 12.6 wt% to 2 wt% when the temperature is 
raised from 400 ºC to 700 °C, and its composition tends to be less hydrogenated (Table 4). Nevertheless, the 
PL deposition is hardly attenuated by increasing the S/C ratio from 1.5 to 6.0 (Table 5), and its elemental 
composition does not change. A more detailed study on the influence that thermal step temperature has on 
the composition and properties of the PL deposited was reported elsewhere (Ochoa et al., 2014) in order to 
establish possible exploitation pathways of this solid material, which would allow a complete valorization of 
raw bio-oil. 
Taking into account that the afore-mentioned results correspond to experiments without catalyst, they must be 
a consequence of thermal cracking reactions and of possible reactions between oxygenated compounds, 
which are favored by increasing temperature. It is expected that the change in the volatile stream composition, 
caused by the thermal treatment temperature and pyrolytic lignin deposition, will influence the results of the 
subsequent steam reforming step with Ni-based catalyst (Section 3.3). 

208



3.3 Effect of thermal step temperature on the reforming activity of the Ni-based catalyst 

Figure 2 shows the effect of the thermal step temperature on the evolution with time-on-stream of bio-oil and 
ethanol conversion (Graphs a-b), and the yields of H2 and carbon-containing products (Graphs c-f), obtained 
in the SR of bio-oil/ethanol mixture in the two-step reaction system (thermal + reforming with Ni/La2O3-Al2O3 
catalyst). The catalytic step was maintained at 700 °C, S/C = 6, and space-time of 0.27 gcatalysth/gfeed.  

 

Figure 2: Effect of thermal step temperature on the evolution with time on stream of bio-oil (a) and ethanol (b) 

conversion, and on the yields of H2 (c), CO2 (d), CO (e) and CH4 (f) during the SR of bio-oil/ethanol mixture. 

Catalytic step: 700 ºC; S/C, 6; W/F0, 0.27 gcatalysth/gfeed. 

As shown in Figure 2a, there is a complete initial conversion of the thermally treated bio-oil in the whole range 
of temperature (400-700 °C), which remains constant for 4 h when the thermal step is carried out at 
temperatures below 500 °C, and for 1.5 h for higher temperatures. When the thermal treatment is performed 
at 400 °C, a H2 yield of around 80 % is obtained (Figure 2c), which remains almost constant in 4 h reaction. 

0.8

0.9

1.0

0 1 2 3 4 5

Xbio-oil

time on stream, h

400 ºC

500 ºC

600 ºC

700 ºC

a

0.8

0.9

1.0

0 1 2 3 4 5

XEtOH

time on stream, h

400 ºC

500 ºC

600 ºC

700 ºC

b

40

60

80

100

0 1 2 3 4 5

YH2

time on stream, h

c

20

40

60

80

100

0 1 2 3 4 5

YCO2

time on stream, h

d

0

10

20

30

40

50

0 1 2 3 4 5

YCO

time on stream, h

e

0

5

10

15

20

0 1 2 3 4 5

YCH4

time on stream, h

f

209



An increase of 100 °C in the thermal unit leads to a remarkable increase of the H2 yield, thereby obtaining 
values close to 90 % for temperatures higher than 500 °C, along with low CH4 yield (Figure 2f) and negligible 
yields of hydrocarbons (not shown). However, although the thermal treatment at 600 °C involves an initial H2 
yield slightly higher than that obtained at 500 °C, it decreases more sharply with time-on-stream (Figure 2c), 
with this effect being even more remarkable after thermal step at 700 °C. 
These results can be mainly explained by the higher content of phenols, aldehydes and ketones in the stream 
that enters the catalytic reactor, whose formation in the thermal step is favored by increasing the operating 
temperature (Table 3), and which causes a rapid deactivation of the catalyst (Aramburu et al., 2014). 

4. Conclusions 

It has been found that operating temperature in the thermal treatment step (pyrolytic lignin deposition) has a 
notable effect on the composition of the volatile stream that enters the catalytic reforming reactor, whereas the 
S/C ratio hardly affects. Thus, increasing the temperature in the range 400-800 °C the gas fraction yield 
increases (with CO and CO2 as major compounds, along with H2, CH4 and hydrocarbons). 
Furthermore, the increase in temperature has consequences on the liquid fraction of volatile stream: i) Above 
500 °C, the liquid fraction yield and its total content of oxygenated compounds decrease; ii) its oxygenated 
composition is different from that of raw bio-oil, with lower concentration of thermally unstable compounds 
(such as levoglucosan) and higher concentration of phenols (especially above 650 °C), carboxylic acids 
(mainly acetic acid) and acetaldehyde, which have the negative effect of favoring the reforming catalyst 
deactivation by coke deposition. In addition, the increase of thermal step temperature decreases the yield of 
pyrolytic lignin and also its H/C ratio. 
Consequently, 500 °C is the thermal step temperature that leads to a better compromise between H2 yield and 
Ni/La2O3-Al2O3 catalyst stability, with complete and stable bio-oil conversion and H2 yield close to 90 %. 

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