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CHEMICAL ENGINEERINGTRANSACTIONS 
 

VOL. 61,2017 

A publication of 

 

The Italian Association 
of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Petar Sabev Varbanov, Hon Loong Lam, Peng Yen Liew, Jiří Jaromír Klemeš 
Copyright © 2017, AIDIC Servizi S.r.l. 

ISBN978-88-95608-51-8; ISSN 2283-9216 

Development of Process Flow Sheet for Syngas Production 

from Sorption Enhanced Steam Gasification of Palm Kernel 

Shell 

Muhammad Shahbaza, Suzana Yusupa,*, Muhammad Ammara, Abrar Inayatb, 

David Onoja Patricka 

aBiomass Processing Lab, Centre of Biofuel and Biochemical Research, Department of Chemical Engineering, Universiti 

Teknologi PETRONAS, Bandar Seri Iskandar, 32610, Perak, Malaysia. 
bDepartment of Sustainable and Renewable Energy Engineering, University of Sharjah, 27272 Sharjah, United Arab 

 Emirates 

 drsuzana_yusuf@utp.edu.my 

This study discusses the production of synthesis gas from palm kernel shell via sorption enhanced steam 

gasification. A flowsheet model that has been presented incorporates the reaction kinetics and mass balance of 

syngas production process. It was assumed that the reactions involved in steam gasification of biomass with 

carbon dioxide adsorption, including gasification, methanation, methane reforming, water gas shift, boudouard 

and carbonation reaction. A parametric study has been performed to investigate the effect of temperature, 

steam/biomass ratio and sorbent/biomass ratio on the product gas compositions and heating values of the final 

product. It was concluded that the hydrogen content in product gas increased in the temperature range of 650 

- 750 ̊ C. The effect of sorbent/biomass ratio was investigated in the range of 0.5 - 1, which showed an increasing 

trend for hydrogen production while the CO2 contents reduced in the final product gas. The mass balance has 

also been presented for each of the equipment in flow sheet developed for synthesis gas production. 

1. Introduction 

Fossil fuel would not be core energy source in future energy trade due to its depletion and problems related with 

its usage, including greenhouse gas emissions, global warming, acid rain, torment weather changes and 

imbalance energy trade (Ahmed et al., 2010). Biomass is accounted as a promising option for alternative and 

new source due to various benefits such as renewability, CO2 neutrality, sustainability and weather moderation. 

The abundant availability of biomass about 200 - 700 EJ/y can increase its global energy share that is 14 % 

currently and eventually decreased 84 % share of fossil fuel (Shahbaz et al., 2016a). Among two routes of 

energy extraction from biomass biological and thermochemical conversion processes, thermochemical 

conversion gasification process is more promising for the extraction of energy in the form of syngas and methane 

that are currently obtained from fossil sources. Syngas has utter importance due to its various applications in 

the energy sector and chemical synthesis like hydrogen, synthetic methane, Fisher-Tropsch diesel, methanol, 

fertilizers and higher hydrocarbon products (Hernández et al., 2016).  

Steam gasification of biomass has a distinction among other gasification process by offering advantages like 

higher heating value of product gas, quality syngas with enrichment of H2 and applicable both small and large 

scale (Shahbaz et al., 2016a). The research work has been conducted to convert biomass through gasification 

with both experimental and modelling approaches. Several studies based on simulations and modelling 

approach have been reported previously. Two types of modelling approaches have been used for gasification 

process including kinetic and equilibrium modellings. In equilibrium modelling, thermodynamics of system and 

reactions have been implemented for the development of model. In kinetic modelling, the kinetics of major 

reactions are used and a process is modeled to predict the gas composition and yield at given set of operating 

parameters. The kinetic modelling approach is complex but provides precise outcome compared to equilibrium 

modelling (Ahmed et al., 2010). Sreejith et al. (2014) used equilibrium modelling approach for gasification of 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1761277

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Shahbaz M., Yusup S., Ammar M., Inayat A., Patrick D.O., 2017, Development of process flow sheet for syngas 
production from sorption enhanced steam gasification of palm kernel shell, Chemical Engineering Transactions, 61, 1675-1680  
DOI:10.3303/CET1761277  

1675



biomass and predicted hydrogen production of 59.3 vol % at 700 °C and steam/biomass ratio of 1. The removal 

of CO2 from the syngas increased the H2 in the product gas. The utilization of sorbent such as CaO for CO2 

adsorption in gasification process not only enhanced the hydrogen content in syngas but also reduced the 

energy requirement within system and enabled the gasification process to occur at a lower temperature of 800 

°C (Rupesh et al., 2016). To date, very few studies have been reported on CaO sorbent modelling work.  

In kinetic modelling, very little work has been made. Sreejith et al. (2014) developed a simulation model for air-

steam gasification with enabling CO2 sorption by using kinetic data from the literature. The modelling approach 

included different processes during biomass gasification like drying, pyrolysis and char gasification and H2 

content found to be increased with the use of sorbent. In Malaysia, 198 million tons per annum palm oil waste 

residue are available, which comprises of palm kernel shell (PKS), palm oil fronds (POF) and empty fruit 

bunches (EFB) (Shahbaz et al.,2016b). Recently, the research has been reported for both experimental and 

modelling approach to utilize palm oil waste in gasification. In modelling approach, Inayat et al. (2010a) 

developed a kinetic model for in-situ steam gasification of EFB. The effect of different parameters including 

temperature and steam/biomass ratio on hydrogen yield has been studied. A flow sheet was also developed for 

EFB steam gasification with the use of sorption process through the kinetic model approach and system 

performance was evaluated. It was found that gasification efficiency was increased by 10 % due to the use of 

CaO (Inayat et al., 2010b). PKS is the major constituent of palm oil residue; it was studied experimentally in an 

integrated catalytic steam gasification system by Khan et al. (2014).  

To date, limited research has been reported for steam gasification of palm oil waste with sorbent. Particularly, 

in the case of PKS steam gasification, no study has been reported on process modelling. The objective of this 

paper is to develop a flowsheet model with the use of sorption method by using kinetics of reactions. In addition, 

the effect of parameters ranges such as temperature from 650 °C to 750 °C, sorbent/biomass ratio from 0.3 

wt/wt to1 wt/wt and steam/biomass ratio from 1 to 2 are varied to study their effect on syngas production as well 

as on heating values of the product gas. The predicted results are compared with experimental results that are 

performed using setup model developed through kinetic modelling approach. 

2. Methodology  

2.1 Experimental setup 

The pilot scale sorption enhanced gasification system was used to validate the developed process through 

kinetic modelling is shown in Figure 1. The system consisted of feeding system, fluidized bed gasifier, steam 

generation system, water treatment and gas cleaning system. The biomass used in this study was PKS and its 

proximate and ultimate analysis is given in Table 1. The PKS was fed into the fluidized bed gasifier through 

screw feeding system. Steam was generated in the boiler and heated up to 350 °C in the superheater. The 

steam reacted with biomass in the fluidized bed gasifier. CaO was placed in the fluidized bed gasifier as a bed 

material. The solid particles were removed from product gas through a cyclone separator and CaCO3 was 

removed at the bottom of the gasifier. The product gas was cooled down to 25 °C and sent to the gas analyzing 

system. 

 

Figure 1: Process flow diagram of sorption enhanced steam gasification process 

 

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Table 1: Ultimate analysis and proximate analysis 

Ultimate Analysis Proximate analysis 

Biomass Composition Wt (%) Component  Wt (%) 

Carbon 48.78 Moisture  9.70 

Hydrogen 5.70 (dry mass) fraction basis 

Nitrogen 1.01 Volatile matter 80.81 

Sulfur 0.21 Fixed carbon 14.25 

Oxygen (by difference) 44.2 Ash  4.94 

HHV (MJ/kg) 18.82   

2.2 Technical Approach 

The system has been modelled for syngas production through steam gasification of PKS with capturing of CO2 

with the utilization of CaO. The production of syngas through gasification process is the result of a complex set 

of reactions that occured at different stages of the process including decomposition of biomass, followed by the 

combustion and pyrolysis. The gasification process is a mixture of exothermic and endothermic reactions. The 

most influencing reactions in steam gasification are methane formation, water gas shift reaction, methane 

reformation and boudouard reactions at higher temperature. The CO2 capturing through carbonation reaction is 

also an important reaction in which CaO sorbent is used within the process. The reactions that are involved in 

the gasification process are given in Table 2. By using the reaction kinetics of the mentioned reactions, a 

mathematical model is formulated.  

Table 2 Reaction scheme and kinetic parameters (Inayat et al., 2010a) 

N

o 
Reactions 

Activation 

energy 

Frequency 

factor 

1 COHOHOHC 1.42.43.1 228.27.51.4   -6,000 2.0x105 

2 OHCHHOHC 2428.27.51.4 8.21.41.8   -1.62x108 4.40 

3 224 3HCOOHCH 
 15.0x103 3.0x105 

4 222 HCOOHCO   -6.4x103 1.0x106 

5 32 CaCOCaOCO   -44.5 10.20 

6 OHCOHCOOHC 2228.27.51.4 .01.415.2   -1.8x10-4 0.12 

 

Assumptions: Due to the limitation of modelling approach, some assumptions are made for the syngas 

production with CO2 capturing system. 

(1) Steady state process at atmospheric pressure and no temperature gradient within gasifier  

(2) Tar production is neglected and ash contents are considered to be inert. 

(3) The degradation of biomass occurs instantaneously through homogenous and heterogeneous 

gasification reactions. 

(4) The product gas mixture consists of hydrogen, methane, carbon mono oxide and carbon dioxides. 

(5) Since the process is continuous, there is no mass accumulation within the system. 

(6) The first order kinetics is assumed in this kinetic modelling approach. 

2.3 Model formulation 

Reaction kinetic model approach is used for the formulation of the model. The reactions assumed for the 

modelling of steam gasification with the enabled CO2 system are given in Table 2. In kinetic modelling, the rate 

equations are used for the description of reactions behavior. The first order kinetics is assumed in this kinetic 

modelling approach. The first order rate equations of mentioned reactions in Table 2 are considered for the 

formulation of the kinetic-based model using Eq(1). 

BAii
CCkr   (1) 

The notations used for rate of reaction are r and k is the constant of rate equation that is strongly influenced by 

temperature. In order to calculate the temperature dependence of rate constant k, Arrhenius equation is 

employed as mentioned in Eq(2). 

RT

E

ii eAk



  (2) 

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The activation energy and frequency factor described as E and A, are the main features of Arrhenius equation. 

In order to determine the production rate of volumetric flow, Eq(3) - Eq(6) are used. The kinetic parameters 

taken from literature are depicted in Table 2. 

643212 15.231.82.4 rrrrrRH   (3)        

6431 1.41.4 rrrrRCO   (4) 

6542 rrrRCO   (5)        

324 1.4 rrRCH   (6) 

The mass balance is calculated by using general mass balance equation as depicted in Eq(7). 

  outin mm                                                                                                                                               (7) 

The performance indicators include gasification efficiency along with higher heating value (HHVg) and lower 

heating value (LHVg) of syngas produced. The LHVg and HHVg are determined by using Eq(8) - (9). 

0042.0)4.857.2530(
42

CHHCOLHV
g

  (8) 

18.4)5.952.3018.30( 42  CHHCOHHV g  (9) 

The gasification efficiency is determined using correlation mentioned in Eq(10). 

fed  PKSdry  of moles

gasproduct  of moles Total


G
  (10) 

3. Results and Discussions 

The model developed for steam gasification of PKS with CO2 capturing using CaO is performed in a similar 

experimental set up for the validation of model in the same range of parameters, including temperature of 650-

750 °C, sorbent/biomass ratio of 0.3 - 1 and steam/biomass ratio of 1.0 - 2.0. The gas compositions predicted 

by the model have good agreement with experimental results in the temperature range as shown in Figure 2. It 

can be seen that H2 production is increased with the increase in temperature whereas CO production has the 

inverse effect. This increase in hydrogen content and the decrease in CO content are also observed which is 

due to the activity of in water gas shift reaction, methane reforming and carbonation reaction. The deviation of 

experimental and modelling results is due to the formation of tar that is not considered in modelling approach. 

A similar trend is also observed by Acharay et al. (2010) for H2 and CO in the presence of CaO. The CO2 found 

to be decreasing from temperature 650 to 700 °C which is due to the carbonation reaction, whereas, the CO2 

content increases above 700 °C due to reverse carbonation reaction. The release of CO2 from CaO3 is also 

reported by Rupesh et al. (2016) at 727 °C and Khan et al. (2014) at 675 °C. Methane formation decreased with 

an increase in temperature due to methane reformation reaction that was enhanced with the elevation of 

temperature. The enrichment of H2-content in syngas at elevated temperature is the result of methane reforming 

reaction that is responsible for CO/H2 ratio.  

 

Figure 2: Effect of temperature on syngas composition. 

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The effect of sorbent on syngas composition can be seen in Figure 3a. It is found that the H2 production has a 

direct relationship with sorbent/biomass ratio and an inverse relation with CO2. The increase in H2 content is 

due to water gas shift reaction, as the partial pressure of CO2 is reduced by adsorption,the equilibrium shift in 

the forward direction resulting in higher production of H2 and CO. Khan et al. (2014) also reported the increase 

of H2 content with the increase in CaO/biomass ratio from 0.5 - 1.5. Steam is very effective gasifying agent when 

syngas is required with higher H2 content. It is clear from Figure 3b that the H2 content is increased sharply with 

the increase in steam/biomass ratio of 1-1.5 and then the rise is steeper. The CO and CO2 contents are also 

decreased with the increase in steam addition. On the other hand, methane formation decreases from 45 vol % 

to 10 vol %. The addition of steam enhances the activity of water gas shift reaction and methane reformation 

reaction, resulting in the enrichment of H2 content and the reduction in methane content. Rupesh et al. (2016) 

also reported the enrichment of H2 content in the presence of CaO by increasing the steam/biomass ratio from 

0 - 2 and with the similar justification. 

 

Figure 3: (a) Effect of sorbent/biomass ratio (b) Effect of steam/biomass ratio on syngas production 

Figure 4 shows the mass balance of developed sorption enhanced gasification system. It is depicted that H2 

production is 159.6 g/h from 1800 g/h of biomass feed. The productions of other gasses are 833.3 g/h of CO 

and 203.5 g/h of methane. The production of CO2 is 407.4 g/h which is very low that shows the activity of CaO 

sorbent. It can be justified that 1,800 g/h of CaO resulted in 2,476.3 g/h CaCO3 due to the carbonation reaction. 

It could be concluded that only 18 % of steam is used for hydrogen production and the remaining steam is used 

to provide fluidization of biomass and CaCO3 is recovered in the form of condensate. A large amount of 

unreacted steam in steam gasification is a drawback of steam gasification and is discussed by many authors 

(Inayat et al, 2010a).  

 

Figure 4: Mass balance of gasification system 

The gasification performance is assessed on the basis of heating values of product gas. The lower and higher 

heating values decrease with the increase in temperature as shown in Figure 5a. The reduction of heating 

values is due to the decrease in methane and CO contents that have more contribution in heating value than 

H2. Figure 5b shows the gasification efficiency is increased from 60 to 85 % with the increase in temperature 

from 650 to 750 ˚C. The increase in gasification efficiency explained an increase in the gas yield.  

(b) (a) 

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Figure 5: (a) Effect of temperature on LHVg and HHVg (b) Effect of temperature on Gasification efficiency 

4. Conclusions 

In this study, a model was developed for steam gasification of PKS with enabled CO2 capturing using CaO 

sorbent. The model predicted results were validated with experimental data performed at the operating 

conditions of the model. It was predicted that syngas composition was highly influenced by temperature and H2 

content increased from 65 % to 79 % with an increase in temperature. Syngas production was very sensitive to 

steam/biomass ratio. By increasing the steam/biomass ratio from 1 - 2, the increase of 30 % in H2 content and 

the decrease of 50 % in methane content were observed. The use of sorbent/biomass ratio was found very 

effective for CO2 sorption. The CO2 formation dropped about 20 % with an increase in sorbent/biomass ratio 

from 0.5 to 1. The HHVg of 17.2 MJ/NM3 and LHVg of 15.2 MJ/NM3 of product gas with a maximum of 85 % 

gasification efficiency showed the good performance of the system. 

Acknowledgement 

The authors are grateful to Ministry of Higher Education Malaysia for financing this research under Long-term 

Research Grant Scheme (LRGS). The authors would like to thank the Universiti Teknologi PETRONAS Malaysia 

for providing the facility and support. 

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