CHEMICAL ENGINEERING TRANSACTIONS 
 

VOL. 56, 2017 

A publication of 

 
The Italian Association 

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

Guest Editors: Jiří Jaromír Klemeš, Peng Yen Liew, Wai Shin Ho, Jeng Shiun Lim
Copyright © 2017, AIDIC Servizi S.r.l., 
ISBN978-88-95608-47-1; ISSN 2283-9216 

A Simple Case Study on Application in Synthesising a 
Feasible Heat Exchanger Network 

Suraya Hanim Abu Bakara,b, Mohd Kamaruddin Abd Hamid*,a,b, Sharifah Rafidah 
Wan Alwia,b, Zainuddin Abdul Manana,b 
a
Process Systems Engineering Centre (PROSPECT), Research Institute of Sustainable Environment, Universiti Teknologi 

 Malaysia, 81310 UTM Johor Bahru, Johor, Malaysia 
b
Faculty of Chemical and Energy Engineering, Universiti Teknologi Malaysia, 81310 UTM Johor Bahru, Johor, Malaysia 

 kamaruddin@cheme.utm.my 

Heat exchanger network (HEN) is very important to optimise energy usage in process industry. Heat 
exchanger network synthesis is an important process synthesis problem where different tools and methods 
have been presented to solve this synthesis problem. In HEN synthesis, the feasibility of the HEN design is 
not taken into consideration. The HEN design may not be able to be implemented in industrial applications. It 
is essential to check the feasibility of a design before it is being implemented in the industry. The objective of 
this paper is to present the application of a new flexible and operable heat exchanger network (FNO HEN) 
methodology in synthesising a feasible HEN using a simple case study. The novelty of this work is to 
determine an optimal ∆Tmin value that gives minimum external energy requirement (EER) and heat exchanger 
area (HEA) as well as simultaneously analyse the feasibility of the HEN design in an easy, systematic and 
efficient manner. Using the new developed FNO HEN methodology framework, HEN design target, which is 
the value of ∆Tmin is determined to obtain the feasible HEN design. From process design point of view, ∆Tmin 
value determines the size of heat exchanger in the network as well as energy saving. A process simulator is 
used to check the process feasibility of the HEN designs. With the use of the feasible HEN trade-off plot, 
which is a plot of EER and HEA at different value of ∆Tmin with additional of feasibility area, the optimal 
feasible HEN design which satisfies external energy requirement (operability), heat exchanger area (capital) 
and process feasibility has been successfully determined. 

1. Introductions 
Supiluck and Kitipat (2015) claimed that integration of heat exchanger network (HEN) is one of causes that is 
able to give major impacts on energy conservation in industrial processes. Sun et al. (2013) have proposed a 
method of Super Targeting (ST) HEN that aims to optimise cost by considering multiple utilities with different 
type of heat exchanger. Akbarnia et al. (2009) studied the material piping cost and piping labour cost and they 
finally modified the current trade-off plot by considering the total piping cost. Yang et al. (2014) had applied 
Pinch Analysis to synthesis HEN with consideration of heat pump.  
Feasibility of HEN synthesis has been neglected and can be questionable. The objective of this paper is to 
find the optimal ∆Tmin value that gives minimum external energy requirement (EER) and heat exchanger area 
(HEA) as well as simultaneously analyse the feasibility of the HEN design. The basic requirement to 
synthesise HEN is by selecting HEN design target, which is the value of ∆Tmin. From process design point of 
view, ∆Tmin value determines the size of heat exchanger in the network. 

2. Methodology 
2.1 Problem statement  

The feasible HEN synthesis problem in this case study can be stated as follows: 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1756027

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Abu Bakar S.H., Hamid M.K.A., Wan Alwi S.R., Manan Z.A., 2017, A simple case study on application in synthesizing 
a feasible heat exchanger network, Chemical Engineering Transactions, 56, 157-162  DOI:10.3303/CET1756027   

157



Given two hot streams (to be cooled) and two cold streams (to be heated), it is desired to synthesis a feasible 
network of heat exchangers that can transfer heat from the hot streams to the cold streams.  Given the heat 
capacity flow rate of each process hot stream, FCP,u; its supply (inlet) temperature, T ; and its target (outlet) 
temperature, T , where, u is 1, 2. The heat capacity, fcP,v, and supply and target temperatures, t  and t , are 
given for each process cold stream, where, v is 1, 2. Available for service are 2 heating utilities and 2 cooling 
utilities whose supply and target temperatures are known.  Focus is given to synthesis a network of heat 
exchangers that is feasible where the control structure is assumed to be fixed. The data required for this 
simple case study is shown in Table 1. 

Table 1: Information for a simple case study (Abu Bakar et al., 2013) 

No Stream names Temperature (°C) Heat capacity flowrate, 
FCp (kW/°C)  

Enthalpy, ∆H (kW) 
Supply Target 

1 H1 250 60 0.1420 -29.81 
2 H2 200 80 0.1074 -12.89 
3 C1 70 180 0.1971 31.53 
4 C2 140 230 0.2279 20.51 

 
In order to solve the problem statement stated in Section 2.1, method from Abu Bakar et al. (2015a) has been 
adapted. It should be noted here that the controller structure for this case study has been assumed to be fixed. 
Therefore, weight factor 2 (w2) is set as zero. Multi-objective function from the method is redefined as shown 
in Eq(1). max J = w P , + w 1 P ,⁄ + w 1 P ,⁄                (1) 

• To achieve process design objectives, P1,1 is maximised. P1,1 is the performance criteria for 
maximisation of the energy recovery of the network. 

• To achieve economic objectives, P3,j is minimised. P3,1 is the capital cost and P3,2 is the operating 
costs. 

• w1 and w3 are the weight factor assigned to each objective term P1,1 and P3,i (i=1-2) . 

2.2 Feasibility test 

There are two things to consider in feasibility test. Firstly, all the information from Design Target and HEN 
Design Analysis stages were transfer into Aspen HYSYS process simulator (2015). Warning sign in Aspen 
HYSYS such as low ft correction factors and temperature cross are also considered in this test. A ‘ft correction 
factor’ is defined as a ratio of the true mean temperature difference to the log-mean temperature difference 
(see Eq(2)). The ‘ft  correction factor’ value must be greater than 0.75 for a heat exchanger to be feasible. 
Temperature cross warning should not occur if calculation in Design Target stage has been done correctly 
(Abu Bakar et al., 2015b). Secondly, it is done by calculating and analysing the ft correction factor for each 
heat exchanger in the network. ft correction factors lower than 0.75 is considered as infeasible (Shah and 
Sekulić, 2007). f = ∆T ∆T⁄ = q UA∆T⁄         (2) 
where: ∆T  = True mean temperature difference; ∆T  = Log mean temperature difference; q = Heat duties 
U = Overall heat transfer coefficient; A = Surface area. 

In Design Target and HEN Design analysis stages, HEN were synthesised at ∆Tmin = 10 °C, 15 °C, 20 °C and 
30 °C. Table 2 shows the output summary for both stages. From the information in Table 2, HENs were 
designed using grid diagram (see Figures 1 and 2). After grid diagram has been developed, it can be seen 
that HEN designs at 15 °C, 20 °C and 30 °C are producing the same network. Feasibility of these candidates 
is still a question and it needs to be analysed. For this reason, all results obtained in both stages have been 
used to simulate HEN in the Aspen HYSYS process simulator to analyse the feasibility of every single heat 
exchanger. 

 

 

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Table 2: Results Design Target and HEN Design Analysis stages for different ∆Tmin in the case study 

∆Tmin 
(°C) 

Maximum Energy 
Recovery (MER) 
(kW) 

External Energy 
Requirement (EER) 
(kW) 

Pinch 
Temperature (°C) 

Unit operation (unit) 

Cold Hot HE Cooler Heater 
10 28,508.4 13,680.9 140.0 150.0 4 0 2 
15 27,971.2 14,755.3 70.0 85.0 3 1 1 
20 27,434.0 15,829.7 70.0 90.0 3 1 1 
30 26,359.6 17,978.5 70.0 100.0 3 1 1 

 

Figure 1: Grid diagram process flow diagram of HEN candidates 10 °C  

 

Figure 2: Grid diagram process flow diagram of HEN candidates 15 °C, 20 °C and 30 °C 

3. Feasibility test results and discussions 
3.1 HEN in Aspen HYSYS simulator  

From the grid diagram, HEN designs were transferred into Aspen HYSYS simulator. HEN at ∆Tmin of 10 °C 
has four heat exchangers and two heaters. Network designs of other candidates are the same with three heat 
exchangers, one cooler and two heaters. The simulation for HEN designs at 10 °C, 15 °C, 20 °C and 30 °C as 
shown in Figures 3 and 4. 
 

 

Figure 3: HEN process simulation using Aspen HYSYS at ∆Tmin 10 °C 

159



 

Figure 4: HEN process simulation using Aspen HYSYS at ∆Tmin 15 °C, 20 °C and 30 °C 

3.2 ft  Correction calculation results 

After the feasibility test has been conducted, it can be seen that all of the designs are feasible. Table 3 shows 
values of ft correction factor for all heat exchangers in the HEN candidates and results summary of the 
feasibility analysis. The results were in line with HEN that has been simulated in Aspen HYSYS. 

Table 3: Value of ft correction factor and status of HEN design candidates 

∆Tmin (°C) ft correction factor Feasibility 
HE1 HE2 HE3 HE4 

10 0.7915 0.7913 0.9523 0.8813 Feasible 
15 0.9038 0.8777 0.9538 0.8792 Feasible 
20 0.8500 0.8871 0.8971 0.8671 Feasible 
30 0.7938 0.9084 0.7758 0.9084 Feasible 

3.3 Multi-objectives function 

All objective function values were collected from Design Target and HEN Design analysis are tabulated in 
Table 4. Since all the values of the objective functions have different units, therefore all objective function 
values need to be normalised. The normalised value, Px,xs were calculated by dividing it with the largest value 
of each objective function. Using the normalised objective function values, the value of multi-objective J is 
calculated using Eq(1). The best overall candidate is at ∆Tmin of 30 °C because it has highest J value. 

Table 4: Multi-objective function calculation of the designed HEN candidates 

 Maximum Energy 
Recovery (MER) 
(kW) 

Heat Exchanger 
Area (HEA)  
(m2) 

External Energy 
Recovery (EER) 
(kW) 

 

Design/Control value, Px,x P1,1 P3,1 P3,2  
∆Tmin 10 °C 28,508.00 2,946.30 13,680.90  
∆Tmin 15 °C 27,971.20 2,661.40 14,755.30  
∆Tmin 20 °C 27,434.00 2,294.30 15,829.70  
∆Tmin 30 °C 26,359.60 1,601.30 17,978.50  
Normalise value, Px,xs P1,1s P3,1s P3,2s  
∆Tmin 10 °C 1.000 1.000 0.761  
∆Tmin 15 °C 0.981 0.903 0.821  
∆Tmin 20 °C 0.962 0.779 0.880  
∆Tmin 30 °C 1.000 1.000 0.761  
Multi-objective function value P1,1 1/P3,1s 1/P3,2s J 
∆Tmin 10 °C 1.000 1.000 1.314 3.314 
∆Tmin 15 °C 0.981 1.107 1.218 3.308 
∆Tmin 20 °C 0.962 1.284 1.138 3.382  
∆Tmin 30 °C 0.925 1.840 1.000 3.765  

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3.4 F-HEN Trade-off Plot 

The F-HEN trade-off plot is a plot of EER and HEA at different value of ∆Tmin with additional of feasibility area. 
The plot is important to show at which ∆Tmin the HENs are feasible. To construct F-HEN trade-off plot, EER 
versus ∆Tmin was constructed first as shown in Figure 5. Then, plot of HEA versus ∆Tmin was plotted in the 
same graph as shown in Figure 6. Finally, the feasibility area was drawn in the same graph as presented in 
Figure 7. The figure shows the best HEN candidate (in terms of EER and HEA) that satisfies the design 
criteria can be identified at the intersection point between EER and HEA lines, which is approximately at ∆Tmin 
of 20 °C. The similar concept also has been used by Dimian et al. (2014) to identify the optimal HEN design 
using common trade-off plot which energy and capital cost versus ∆Tmin. 
 

 

Figure 5:  External energy requirement at different HEN design of ∆Tmin 

 

 

Figure 6: External energy requirement and heat exchanger area at different HEN design of ∆Tmin 

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Figure 7: HEN trade-off plot with feasibility area for this case study  

4. Conclusions 
The optimal solution for the feasible HEN design of this case study which satisfies external energy 
requirement (operability), heat exchanger area (capital) and process feasibility has been successfully 
analysed. FNO HEN methodology framework has been successfully developed. The new trade-off plot which 
incorporates the feasibility area has been successfully developed and tested using a simple case study. The 
use of feasible trade-off plot helps in obtaining the optimal and feasible HEN design in an efficient and 
systematic manner.  

Acknowledgments  

The financial support from Research University Grant (RUG) Tier 1 (Q.J130000.2546.12H67), Universiti 
Teknologi Malaysia (UTM) is acknowledged. 

Reference  

Abu Bakar S.H., Hamid M.K.A., Wan Alwi S.R., Manan Z.A., 2013, Flexible and Operable Heat Exchanger 
Networks, Chemical Engineering Transactions 32, 1297-1303. 

Abu Bakar S.H., Hamid M.K.A., Wan Alwi S.R., Manan Z.A., 2015a, Selection of minimum temperature 
difference (∆Tmin) for heat exchanger network synthesis based on trade-off plot, Applied Energy 162, 
1259-1271. 

Abu Bakar S.H., Hamid M.K.A., Wan Alwi S.R., Manan Z.A., 2015b, Effect of Delta Temperature Minimum 
Contribution in Obtaining an Operable and Flexible Heat Exchanger Network, Energy Procedia 75, 3142-
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Akbarnia M., Amidpour M., Shadaram A., 2009, A new approach in pinch technology considering piping costs 
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Aspen HYSIS V8.8, 2008, Aspen Technology Inc., Houston, United States. 
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Shah R.K., Sekulić D.P., 2007. Fundamentals of Heat Exchanger Design, Wiley, Canada. 
Sun K.N., Wan Alwi S.R., Manan Z.A., 2013, Heat exchanger network cost optimization considering multiple 

utilities and different types of heat exchangers,Computers and Chemical Engineering 49, 194-204. 
Supiluck K., Kitipat S., 2015, Heat Exchanger Network Synthesis/Retrofit using MINLP Stage-wise 

Superstructure with Non-isothermal Mixing, Chemical Engineering Transactions 43, 1273-1278. 
Yang M., Xiao F., Liu G., 2014, Heat exchanger network design considering heat pump performance, 

Chemical Engineering Transactions 39, 1099-1104. 
 

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