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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 45, 2015 

A publication of 

 
The Italian Association 

of Chemical Engineering 

www.aidic.it/cet 
Guest Editors: Petar Sabev Varbanov, Jiří Jaromír Klemeš, Sharifah Rafidah Wan Alwi, Jun Yow Yong, Xia Liu  

Copyright © 2015, AIDIC Servizi S.r.l., 

ISBN 978-88-95608-36-5; ISSN 2283-9216 DOI: 10.3303/CET1545305 

 

Please cite this article as: Amer D., Gadalla M., Ashour F., 2015, Gasification of coal and heat integration modification for 
igcc - integrated gasification combined cycle, Chemical Engineering Transactions, 45, 1825-1830  
DOI:10.3303/CET1545305 

1825 

Gasification of Coal and Heat Integration Modification for 

IGCC - Integrated Gasification Combined Cycle 

Dalia Amer*
,a

, Mamdouh Gadalla
a
, Fatma Ashour

b
 

a
Chemical Engineering Department, British University in Egypt, Cairo –Suez Desert Road, Sherouk City Gate 1, Cairo 

 Egypt 
b
Chemical Engineering Department, Cairo University, University Street 1, Giza, Egypt 

 Dalia.Amer@bue.edu.eg 

Use of energy is closely related to the development of an economy. The most useful form of energy in the 

modern world is electricity. IGCC has higher fuel flexibility (biomass, refinery residues, petroleum coke, etc.) 

and generates multiple products (electricity, hydrogen and chemicals like methanol and higher alcohols) and 

by-products - sulphur, sulphuric acid, slag, etc. IGCC plants include coal preparation unit, air separation unit 

(ASU) to separate oxygen from air to use it in the gasification process, gasification unit where an incomplete 

combustion for coal is made to produce Syngas, cleaning unit to remove acid gases and CO2 from Syngas 

and a power station that contains gas turbines and steam turbines to produce electricity (Emun et al., 2010).  

In this work Heat Integration study is made to an IGCC plant whose feedstock is coal- water slurry with a flow 

rate of 3,020 t/d. The study produces a comparison between the capital investment and operating costs of the 

existing and the integrated IGCC plant and investigates the effect of changing the feedstock content on 

thermal efficiency, net power and cold gas efficiency.  

The Heat Integration considers ΔTmin = 1.5 °C as for the existing plant, and results in savings of 47.5 % and 

5.4 % as in the required heating and cooling duties. Three different feedstocks with the same flow rate 3020 

t/d are used in this work to study their effects on the efficiency of IGCC plant; coal, coal-water slurry and a 

mixture of 93 % coal and 7 % ricestraw. Thermal efficiencies resulted due to the change in feedstock are 

37 %, 36.6 % and 36.8 %, net powers are 337.5 MW, 334 MW and 337 MW while the cold gas efficiencies are 

71.5 %, 70 % and 72 % for coal, coal-water slurry and (93 % coal and 7 % ricestraw). 

1. Introduction  

IGCC uses a coal gasification system to convert coal into a synthesis gas (syngas) and produce steam. The 

hot Syngas is processed to remove sulphur compounds, mercury and particulate matter before it is used to 

fuel a combustion turbine generator, which produces electricity. The heat in the exhaust gases from the 

combustion turbine is recovered to generate additional steam. This steam, along with that from the syngas 

process, then drives a steam turbine generator to produce additional electricity. Syngas consisted mainly of 

hydrogen, carbon monoxide, carbon dioxide and water. Syngas is used in petrochemical industries to produce 

various products such as methanol and ammonia. IGCC plants are major heating and cooling utilities 

consuming plants and therefore require extensive utility management. There are many ways to make this 

management; Heat Exchanger Network design and Process Heat Integration are widely used methods (Liew 

et al., 2014). Feedstock type such as (coal, coal-water slurry or a mixture of coal and biomass) has a great 

effect on the performance of the IGCC power plants which are thermal efficiency, net power of the plant and 

cold gas efficiency. Thermal efficiency is a measure of performance of a power cycle and it is function in the 

plant net power, mass flow rate and lower heating value (LHV) of the fuel used. Cold gas efficiency is a 

measure of performance of gasification unit and it is function in mass flow rates and lower heating values 

(LHV) of Syngas and fuel used in the plant. The main objectives of this work are decreasing the heating and 

cooling utilities consumption of the IGCC plant and increasing the efficiency of IGCC plant by changing the 

feedstock type. 

 



 
1826 

 

Figure 1: IGCC Block Flow Diagram 

2. ΔTmin and Heat Exchanger Network of the existing IGCC  

Heat Integration study is made for the existing IGCC plant with a coal-water slurry feedstock in order to reach 

the minimum heating and cooling energy targets and save total annualized cost of the process. ΔTmin in this 

case considers 1.5 °C as shown in Table 1 which is small due to the presence of the ASU in the IGCC plant 

where a cryogenic process occurred to separate oxygen gas from air in order to use it in the gasification 

process.  

Table 1: ∆Tmin of the existing IGCC plant with slurry feed 

Heat Exchangers Names  Thin( 
o
C) Thout( 

o
C) Tcin( 

o
C) Tcout( 

o
C) ΔTin( 

o
C) ΔTout( 

o
C) 

INTRC1 & INTRC1 CW 93.89 33.22 30.56 88.32 5.57 2.66 

INTRC2 & INTRC2 CW 114.5 33.3 30.56 100.3 14.2 2.74 

INTRC3 & INTRC3 CW 76.53 36.06 30.56 72.41 4.12 5.5 

GOXCLR1 & GOXCLR1 

CW 

267.9 35 30.56 176.7 91.2 4.44 

N2CLR1 & N2CLR1 CW 243.9 35 30.56 171.8 72.1 4.44 

N2CLR2 & N2CLR2 CW 230.1 35 30.56 171.8 58.3 4.44 

GOXCLR2 & GOXCLR2 

CW 

215.7 35 30.56 169.4 46.3 4.44 

HX-2 (AIR-1 to AIR-1A) 20 -170 -181.8 13.04 6.96 11.8 

HX3(BOTLPC&BOTLPCA) -171.3 -179.8 -193.4 -181.4 10.1 13.6 

HX-3(N2HPC & N2HPC-A) -177.1 -179.8 -181.4 -178.6 1.5 1.6 

RSC & RSC CW 1438 818.8 215.6 363.3 1074.7 603.2 

CSC 1 & CSC1 CW 818.8 402.5 215.6 352.2 466.6 186.9 

CSC 2 & CSC1 CW 818.8 402.5 215.6 352.2 466.6 186.9 

N2CLR 71.54 -34.44 -37.15 -6.787 78.32 2.71 

SG & (Treat to Treat 2) 152.4 140.1 -6.787 93.33 59.07 146.88 

ACLR & GTAIRCLR 536.8 502.7 198.3 399.1 137.7 304.4 

HX1 (PRD1 & PRD1-A) 415.8 132.2 22.25 69.28 346.52 109.95 

HX2 (PRD2 & PRD2-A) 210.4 0 -22.58 22.22 188.18 22.58 

HX-3A(PRD2-Bto PRD2C) 0.555 -23.33 -36.37 -3.507 4.062 13.04 

HX1 (PRD1 to FD2-A) 427 402 366.7 390.8 36.2 35.3 

HX2 (PRD2 to FD3) 507 394 239.2 366.7 140.3 154.8 

HX3 (PRD3 to COOLNH3) 472 454 219 239.2 232.8 235 



 
1827 

 

Figure 2: Heat Exchanger Network for the external heaters and coolers only in the existing IGCC plant 

The cost of heating and cooling utilities used in the existing IGCC is 12,496,960 $/y as shown in Table 2 

Where the cost of cooling water is 0.067 $/t and the high pressure steam cost is 17 $/t (Emun et al., 2010). 

Table 2: Cost of heating and cooling utilities for the existing IGCC plant  

Utility Name  Tin(°C) Tout(°C) Utility load 

(kJ/h) 

CP 

(kJ/h°C) 

Utility flowrate 

(kg/h) 

Utility cost 

($/y) 

Cooling water 20 40 9.81 × 10
8
 4.183 11,726,034 6,285,154 

HP steam 250 249 8.84 × 10
7
 2.196 40,255 5,474,681 

Refrigerant 1 -25 -24 1.62 × 10
7
 4 4,050,000 354,975 

Refrigerant 2 -40 -39 1.42 × 10
7
 1.341 10,589,113 382,150 

Table 3: All information for the existing IGCC plant 

Parameters  Existing IGCC plant 

Qh consumed (MW) 24.55 

Qc consumed (MW) 214.67 

Heating and cooling utilities cost ($/y) 12,496,960 

Cost of Bituminous coal ($/y)  35,166,666 

Net power of the existing IGCC plant (MW) 322 

Electricity selling price ($/y) 188,576,000 

Operating and maintenance (O & M) cost (20 % of the electricity selling cost) ($/y)  37,715,200  

Total operating cost (heating and cooling duties cost + cost of coal + O&M cost) ($/y) 85,378,826 

Cost of additional heat exchanger area ($)  - 

Total fixed cost (plant fixed cost + cost of additional heat exchanger area) ($)  892,801,900  

Plant life time (y)  10  

Annualized fixed cost  (total fixed cost / plant life time) ($/y)  89,280,190  

Total annualized cost (total operating cost + annualized fixed cost) ($/y)  174,659,016  



 
1828 

 
The cost of Bituminous coal is 52.72 $/t and the cost of electricity is 71 $/MWh (US. Energy Information 

Administration, 2015). The minimum heating and cooling energy targets are obtained through the Composite 

Curve as shown in Figure 3. 

 

 

Figure 3: Composite Curve of the IGCC plant at ΔTmin = 1.5 °C 

The minimum heating and cooling energy targets are 15.38 MW for heating duty and 205.15 MW for cooling 

duty while the existing IGCC plant consumes 24.55 MW for heating duty and 214.67 MW for cooling duty so; 

the Heat Integration saves 9.17 MW as heating duty and 9.52 MW as cooling duty. These results are 

summarized in the following Table 4. 

Table 4: Results of Heat Integration of IGCC plant at ΔTmin = 1.5 °C 

ΔTmin( 
o
C)  Qhexist (MW) Qcexist (MW) Qhmin (MW) Qcmin (Mw) Qcsaved (MW) Qhsaved (MW) 

1.542  24.55 214.67 15.38 205.15 9.52 9.17 

 

The Heat Exchanger Network of the Heat integrated IGCC plant is made according to the Pinch Technology 

method as shown in Figure 4.  

 

 

Figure 4: Heat Exchanger Network at ΔTmin = 1.5 °C  



 
1829 

Table 5 shows the additional area to the IGCC plant after making Heat Integration which equals 9,624 m
2
. The 

cost of this additional heat exchanger area in 2003 is $ 494,545 which is calculated from this equation 1530 * 

(additional area)
0.63

 and this cost should be multiplied by 1.8 which is the cost index of year 2014 divided by 

the cost index of year 2003 to get the cost at 2014 that equals $ 890,181.  

Table 5: Load and area of the added heat exchanger 

Heat Exchanger Name New load (MW) Additional Area (m
2
) 

cooler& kettle reboiler 9.16 9,624 

 

The total cost of heating and cooling utilities is $/y 11,166,760 as shown in Table 6. 

Table 6: Cost of heating and cooling utilities for the Heat integrated IGCC plant 

Utility Name  Tin(°C) Tout(°C) Utility load 

(kJ/h) 

CP (kJ/h°C) Utility flowrate 

(kg/h) 

Utility cost ($/y) 

Cooling water 20 40 9.81 E8 4.183 11,200,096 6,003,251 

HP steam 250 249 8.84 E7 2,196 32,531 4,424,193 

Refrigerant 1 -25 -24 1.62 E7 4 4,075,000 357,166 

Refrigerant 2 -40 -39 1.42 E7 1.341 10,589,113 382,150 

Table 7: A comparison between the results of the existing IGCC plant and the Heat integrated IGCC plant  

 

From the previous table it is concluded that the Heat Integration for the existing IGCC plant with slurry feed 

saves total annualized cost by 1,241,182 $/y. 

3. Effect of changing the feedstock on the performance of the IGCC plant 

Changing the feedstock has a great effect on the performance of the IGCC plant. In this case three feedstocks 

with the same flow rate 3,020 t/d are used to study their effects on the performance of IGCC plant. The 

feedstocks used in this case are dry coal, coal-water slurry and a mixture of 93 % coal and 7 % ricestraw. 

Thermal Efficiency measures the performance of the power cycle which is obtained from Eq(13). Cold gas 

efficiency measures the efficiency of a gasification unit and it is obtained from Eq(14). Net power of IGCC 

plant is obtained from Eq(15) (Emun et al., 2010). 

   ( )  
    

(             )
     (13) 

Parameters  Existing IGCC 

plant 

Heat 

Integration for 

existing IGCC 

plant 

Qh consumed (MW) 24.55 15.38 

Qc consumed (MW) 214.67 205.15 

Heating and cooling utilities cost ($/y) 12,496,960 11,166,760 

Cost of Bituminous coal ($/y)  35,166,666 35,166,666 

Net power of the existing IGCC plant (MW) 322 322 

Electricity selling price ($/y) 188,576,000 188,576,000 

Operating and maintenance (O & M) cost (20% of the electricity selling 

cost) ($/y)  

37,715,200  37,715,200 

Total operating cost (heating and cooling duties cost + cost of coal + 

O&M cost) ($/y) 

85,378,826 84,048,626 

Cost of additional heat exchanger area ($)  - 890,181 

Total fixed cost (plant fixed cost + cost of additional heat exchanger 

area)  ($)  

892,801,900  893,692,081 

Plant life time (y)  10  10 

Annualized fixed cost  (total fixed cost / plant life time) ($/y)  89,280,190  89,369,208 

Total annualized cost (total operating cost + annualized fixed cost) 

($/y)  

174,659,016  173,417,834 



 
1830 

 
Where ηt is thermal efficiency, Mfuel is the mass flow rate of fuel used such as coal (kg/s), LHVfuel is the lower 

heating value of the fuel used (MJ/kg) and Pnet is the net power output (MW).  

    ( )  
           

              
     (14) 

Where ηcg is cold gas efficiency, Msyngas and Mfuel are the mass flow rates of Syngas and fuel used (kg/s) 

respectively, LHVsyn and LHVfuel are the lower heating values (MJ/kg) for syngas and fuel used. 

                  (15) 

Where Pnet is net power output (MW), PGT is the net power output from the gas turbine (MW) and PST is the 

power output from the steam turbine (MW) and PAUX is the auxiliary power consumption in pumps, 

compressors, etc. (MW) and here in this case Pnet is obtained from the simulated IGCC plant on Aspen plus. 

LHV of coal and syngas are calculated as follows 

    (         ) (         )  (           ) (16) 

The effects of changing feedstock on the performance of IGCC plant is shown in Table 8. 

Table 8: Effect of changing feedstock on the performance of IGCC plant 

Feedstock Thermal 

efficiency % 

Net power 

(MW) 

Syngas rate 

(kg/h) 

LHV fuel 

(MJ/kg) 

LHV syngas 

(MJ/kg) 

Cold gas 

efficiency % 

Coal 37 337.54 4,398 26.5 10.18 76.53 

Coal & 

ricestraw 

36.9 337 3,875 25.18 11.07 77.25 

Slurry 36.6 334.29 4,107 26.1 10 76 

 

From the previous Table 3 it is obvious that the coal-slurry feedstock has the lowest thermal efficiency among 

the others due to the presence of water that consumes a large amount of heating energy to vaporize water 

during the gasification process. Dry coal has the highest net power due to its high heating value comparing 

with the other feedstocks (Sofia et al., 2014). The mixture of 93 % coal and 3 % ricestraw has the highest cold 

gas efficiency as ricestraw is gasified at lower temperatures than dry coal hence it consumes lower heating 

energy for gasification unit than the other feedstocks also, the presence of ricestraw increases the hydrogen 

content in the produced syngas that is used in petrochemical industries to produce methanol for example.  

4. Conclusions 

Heat integration study is made for an IGCC plant with coal-water slurry feed that resulted in savings of 9.17 

MW as heating duty and 9.52 MW as cooling duty also saves the operating cost by 1,330,200 $/y and saves 

total annualized cost by 1,241,182 $/y. Heat Integration increases the fixed capital investment of IGCC plant 

as it becomes 893,692,081 $ rather than 892,801,900 $ due to the addition cost of the new added heat 

exchanger. The effect of changing the feedstock on the performance of the IGCC is studied using three 

feedstocks (coal, coal-water slurry and a mixture of 93 % coal and 7 % ricestraw) and it is concluded that the 

highest thermal efficiency, net power, and cold gas efficiency are obtained when dry coal feed is used due to 

the highest heating value for dry coal feed while the lowest thermal efficiency, net power and cold gas 

efficiency are obtained when coal-water slurry feed is used due to the presence of water that consumes high 

energy to vaporize water during the gasification process. When ricestraw percent in the feed increases the 

sulfur content in the produced syngas increases which has harmful corrosive effect on the process equipment. 

References 

Emun F., Gadalla M., Majozi T., Boer D., 2010, Integrated gasification combined cycle (IGCC) process 

simulation and optimization, Computers and Chemical Engineering, 34, 331-338. 

Liew P.Y., Wan Alwi S.R., Klemeš J.J., Varbanov P.S., Manan Z.A., 2014, Utility-heat exchanger grid diagram: 

a tool for designing the total site heat exchanger network, Chemical Engineering Transactions, 39, 7-12 

DOI: 10.3303/CET1439002 

US. Energy Information Administration, 2015, Annual Energy Outlook, DOE/EIA-0383. 

Sofia D., Llano P.C., Giuliano A., Hernández M.I., Peña F.G., Barletta D., 2014, Co-gasification of coal-

petcoke and biomass in the Puertollano IGCC power plant, Chemical Engineering Research and Design, 

92, 1428-1440.