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CHEMICAL ENGINEERING TRANSACTIONS 

VOL. 56, 2017 

A publication of 

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

Guest Editors: JiříJaromírKlemeš, Peng Yen Liew, Wai Shin Ho, JengShiun Lim
Copyright © 2017, AIDIC ServiziS.r.l., 
ISBN978-88-95608-47-1; ISSN 2283-9216

Sensitivity Analysis of Industrial Heat Exchanger Network 
Design 

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

 kamaruddin@cheme.utm.my 

The problem of interaction between economic design and controller design of heat exchanger network (HEN) 
is addressed in this work. The feasibility and sensitivity issues are incorporated in the classical design of HEN. 
HENs in industry seem to be very efficiently operated. The network that may have operated efficiently perhaps 
is the one that is not fully optimised in term of flexibility and sensitivity. It is important to do synthesis and 
sensitivity analyses of the designed network. The objective of this paper is to investigate and compare the 
sensitivity criteria of the originally designed HEN of the fatty acid fractionation process (FAFP) and the new 
HEN design. In this study, the HEN designs are already fixed at the value of ∆Tmin = 40 °C. A new suggested 
HEN is redesigned from the original HEN of FAFP plant by obeying Pinch Analysis (PA) rules. The new HEN 
was redesigned by applying the PA stream splitting compared to the original HEN (that has been used in the 
industry), in which the design is not have stream splitting. The aim of this work is to determine the best 
optimised design whether the one that not followed Pinch Analysis rules or the other one. Using the new 
developed FNO HEN methodology framework, sensitivity analysis was applied which consists of two tests: 1) 
Flexibility Analysis and 2) Sensitivity Analysis. According to the results, the best candidate that satisfies the 
sensitivity and economy criteria is the new HEN design. It can be concluded that it is important to do stream 
splitting in order to obtain not only the best HEN in terms of design and economy criteria, but also in the matter 
of sensitivity criteria. 

1. Introduction

Synthesis of heat exchanger network (HEN) has been an important research field as it is one of the main 
criteria to optimise energy in process industries. Improve economic side of process industries. There are lots 
of research to improve synthesis of HEN. However the synthesis of a cost-effective HEN design focus on 
aiming to maximise heat recovery by considering the trade-off between the capital and operating costs for a 
given value of ∆Tmin. Sarut and Kitipat(2014) considered minimisation of total annual cost (TAC) of freshwater 
cost, piping cost, investment cost of heat exchanger unit, and hot/cold utility cost. The research solve the 
optimisation problem based on mathematical programming for simultaneous water and heat exchanger 
network design of fixed-flowrate system. Sun et al. (2013) investigated the effect of ∆Tmin contribution on cost, 
by considering multiple utilities. The research is by stream temperature vs. enthalpy plot supertargeting 
method. Akbarnia et al. (2009) applied PA to do super targeting by considering piping cost, materials of 
construction and pressure rating. The research just focus on reducing design and operational cost only. 
Kravanja and Glavi (1997) performed cost targeting on a heat exchanger network using a combination of PA 
and a complex algorithmic approach. They combined PA with the complex algorithmic approach to target cost 
and to reduce feasibility region defined over sets of discretised decision variables. The problem of interaction 
between economic design and controller design of HEN is addressed in this work. The feasibility and 
sensitivity issues are incorporated in the classical design of HEN. HEN in industry seem to be very efficiently 
operated. The network that may have operated efficiently perhaps is the one that is not fully optimised. The 

 

   

DOI: 10.3303/CET1756249

 
 
 

 
 
 
 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Bakar S.H.A., Hamid M.K.A., Wan Alwi S.R., Manan Z.A., 2017, Sensitivity analysis of industrial heat exchanger 
network design, Chemical Engineering Transactions, 56, 1489-1494  DOI:10.3303/CET1756249   

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latest, Kang et al. (2016) have consider multi period heat exchanger network based on sub-period durations, 
however the solution is based on total annual cost. Zhang et al. (2016) had done research on synthesis large-
scale heat exchanger network. The method to solve the problem is by using algorithm that combines 
deterministic and stochastic optimisations to obtain an optimal sub-network. In that case, the objective function 
is to minimise TAC. 
The sole solution of synthesis HEN is to minimise TAC. There is not many research on synthesis HEN and 
considering sensitivity analysis simultaneously. The objective of this paper is to evaluate the feasible HEN 
designs section in terms of analyses the HEN sensitivity. Two types of sensitivity analyses were evaluated: 
process flexibility (P2,1) and process sensitivity (P2,2). It should be noted that the controller structure selection 
(P2,3) was not evaluated in this stage since all the output temperatures (controlled variables) are already been 
paired with the flow rates of the external utilities. 

2. Methodology 

2.1 Problem statement   

The sensitivity heat exchanger network (S-HEN) problem can be stated as follows: 
Given three hot streams (to be cooled) and two cold streams (to be heated), it is desired to investigate the 
sensitivity of the synthesised heat exchanger network that can transfer heat from the hot streams to the cold 
streams. Given also the heat capacity, CP,u; and flow rate, F of each process hot stream, its supply (inlet) 
temperature, T ; and its target (outlet) temperature, T , where u = 1, 2, 3. Given the heat capacity, fcP,v, and 
supply and target temperatures, t  and t , are given for each process cold stream, where v = 1, 2.  In this 
case, the HEN designs are already fixed at the value of ∆Tmin = 40 °C and focus is given to investigate the 
sensitivity for the original HEN and the new suggested HEN designs as shown in Figure 1. 

2.2 Problem definition   

For this case study, all the stages of FNO HEN methodology framework as adapted from Abu Bakar et. al., 
(2015b) are implemented. As defined in the previous subsection, the HEN design for this case study is 
assumed to be fixed at ∆Tmin = 40 °C. Multi-objective function is adapted from Abu Bakar et al. (2013). Since 
the HEN design already fixed, therefore weight factor for design analysis objective function, w1 is set as zero, 
therefore the multi-objective function is redefined based on the problem statement. The new defined multi-
objectives function is shown in Eq(1).  

( ) ( ) ( ) ( ) ( )2 2,1 2 2,2 2 2,3 3 3,1 3 3,2max J w P w 1 P w P w 1 P w 1 P= + + + +    (1) 
• To achieve the steady state sensitivity objective, P2,1 is maximised, P2,2 is minimised and P2,3 is 

maximised. P2,1 is the flexibility, percentage of manipulated variables toleration, while P2,2 is the 
sensitivity of controlled variable, y with respect to disturbance variable, d and P2,3 is the controller 
structure pairing gain, the sensitivity of controlled variable, y with respect to manipulated variable, u. 

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

• w2 and w3 are weight factors for each objective function to determine optimum value J. 

3. Sensitivity design analysis 

3.1 Flexibility analysis 

Flexibility (F) test can be defined as capability of the network to tolerate the maximum changes of manipulated 
variables (u). Flexibility analysis is evaluated by calculating the percentage changes of the manipulated 
variables (feed flow rates) that can be tolerated by each feasible HENs (refer Eq(2)). The network that has the 
highest percentage changes in all network streams is regarded as the most flexible HEN design. This test can 
be performed by increasing the value of one of the manipulated variables. The next step is to observe if there 
is any operation warning in any heat exchanger within the network. For example, one of the feed stream flow 
rate (FH1) is adjusted and its value is increased until the operation warning either ‘temperature cross’ or ‘ft 
correction factors is low’ is observed. Once the operation warning is observed, the previous increment value is 
considered as the maximum value of the flow rate, and then the percentage is calculated. This procedure is 
repeated for all manipulated variables in the network. Then, the averages of percentage changes for all feed 
streams were calculated using Eq(2). The highest average was selected as the most flexible network. = ∑ 	%   (2) 

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The results of the flexibility test are summarised in Table 1. The original designed HEN has a flexibility of 
79.51 % whereas the new designed HEN has a flexibility of 82.52 %. 
 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
(a) 

  

 

 

                                                                                                     

 

 

 

 

 

 

 

 

         

 (b) 

Figure 1: Aspen HYSYS simulation environment for (a) original designed HEN, (b) new designed HEN (Abu 
Bakar et al., 2015a) 

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Table 1: Flexibility results of the HEN designs 

U  Original HEN New HEN 
∆Tmin   
FH1(%) 100 100 
FH2(%) 100 36.13 
FH3 (%) 100 76.16 
FC1(%) 0.60 100 
FC2 (%) 96.93 100 
Average 79.51 82.46 

3.2 Sensitivity analysis 

The sensitivity analysis was implemented to measure the minimum effect of the controlled variables (stream 
temperature outputs) (y) or the minimum effect that the designed HENs can resist (minimum effect towards 
operational warnings) with respect to disturbance variables (feed temperatures) (d). Then, the derivative of the 
controlled variable with respect to disturbance is calculated (dy/dd) and the minimum of dy/dd is considered as 
the best option. 

=	∑  (3) 
In this case study, since all the output temperatures (controlled variables) are already controlled by 
manipulating the external utilities (Figure 1), the sensitivity analysis was done to measure the minimum effect 
towards operational warnings that the designed HENs can resist with respect to the changes in disturbance 
variables. This analysis can be performed by increasing the value of one of the disturbance variables. The 
next step is to observe if there is any operation warning in any heat exchanger within the network. For 
example, one of the disturbance variables (TH1) is adjusted and its value is increased until the operation 
warning either ‘temperature cross’ or ‘ft correction factors is low’ is observed. Once the operation warning is 
observed, the previous increment value is considered as the maximum value of the feed temperature, and 
then the percentage is calculated. This procedure is repeated for all disturbance variables in the network. 
Then, the averages of percentage changes for all feed temperatures were calculated. The results of sensitivity 
analysis are summarised in Table 2. The average tolerable changes of disturbance variables for a new 
designed HEN is about 48.21 %, whereas for the original HEN, it was found that this design is more sensitive 
to the changes of disturbance variables, with average sensitivity of 60 %. 

3.3 Optimal selection and verification 

For the economic analysis, the calculation for the capital cost is assumed to be a function of heat exchange 
area (HEA), while the calculation for the operating cost is assumed to be a function of external energy 
requirement (EER). Since the design has been fixed at ∆Tmin = 40 °C, the results of HEA and EER for both 
design is the same as shown in Table 3. 

Table 2: Sensitivity results of the original and new designed HENs 

Design Original HEN New HEN 
U   
TH1(%) 100 85.71 
TH2 (%) 0 0 
TH3(%) 0 0 
TC1(%) 100 87.86 
TC2 (%) 100 67.46 
Average 60 48.21 

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

No HEN Design Name Heat transfer area (m2) Operating duties (kW) 
1 Original HEN 46.32 1606.49 
2 New HEN 42.38 1606.48 

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3.4 Multi-objectives function 

All objective function values were collected from Stage 3 and Stage 4 and tabulated in Table 4. Both 
candidates were then validated by calculating the multi-objective function using Eq(1). Before calculating the 
multi-objective function, the value of the objective function needs to be normalised. Since all the values of the 
objective functions have different range and unit, therefore all objective function values need to be normalised 
with respect to its maximum value. In study, all the objective function terms are weighted equally, so that the 
decision-maker does not have any preference for one objective over another. The largest J value which is in 
bold shows the best overall candidate for this case study. The results of the multi-objective function calculation 
in Table 4 prove that the new HEN design resulted in the maximum J value. 

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

 Flexibility 
(control) 

Sensitivity 
(control) 

Capital Cost 
(design) (m2) 

Operating cost 
(design) (kW) 

 

Design/Control value, Px,x P2,1 P2,2 P3,1 P3,2  
Original HEN 79.51 60 46.32 1606.49  
New HEN 82.46 48.21 42.38 1606.48  
Normalise value, Px,xs P2,1s P2,2s P3,1s P3,2s  
Original HEN 0.96 1 1 1  
New HEN 1 0.8 0.92 1  
Multi-objective function value, P2,1s 1/ P2,2s 1/ P3,1s 1/ P3,2s J 
Original HEN 0.96 1 1 1 3.96 
New HEN 1 1.25 1.09 1 4.34 

3.5 Sensitivity HEN trade-off plot 

The sensitivity criteria analysis of HEN consists of feasibility and sensitivity tests as shown in Figure 2. In the 
figure, design number 1 represents the original HEN design while design number 2 represents the new HEN 
design. It can be clearly seen that the original HEN (design number 1) has a smaller feasibility (blue dot) 
compared to the new HEN design (design number 2). In terms of the sensitivity criteria (red dot), the original 
HEN has a higher value compared to the new HEN. 
According to the FNO HEN methodology framework, from the process control point of view, the design 
candidate with the highest flexibility value is the optimal one. This is because it is more robust and capable in 
maintaining the sensitively variables with higher flow rate. HEN design with higher sensitivity criteria is not a 
good design since it will be too sensitive to the smaller changes in disturbances, hence making it very difficult 
to be controlled. The optimal network from operation point of view is the one that has smaller sensitivity criteria 
with higher flexibility criteria.   

 
Figure 2:  Flexibility and sensitivity analysis of two different HEN designs  

40

45

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60

65

79

79,5

80

80,5

81

81,5

82

82,5

83

0 1 2 3

Se
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iti
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ty
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)

Fl
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)

HEN Candidates
Flexibility Sensitivity

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4. Conclusion 

The investigation on the sensitivity HEN (S-HEN) of the FAFP case study has been successfully done using 
FNO HEN methodology framework. Although the process design criteria have been fixed in the beginning of 
this case study, from the process design results, two different HENs have been obtained in this research. 
Based on these two designs, the sensitivity criteria have been performed for both design candidates. From the 
results, the best candidate that satisfies the sensitivity and economy criteria is the new HEN design. According 
to process design point of view, the new HEN was designed by applying the PA stream splitting compared to 
the original HEN (that has been used in the industry), which its design does not have stream splitting. It can be 
concluded that it is important to do stream splitting in order to obtain not only the best HEN in terms of design 
and economy criteria, but also in the matter of sensitivity criteria. 

Acknowledgements  

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

References  

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, Initial analysis on heat exchanger 
networks of fatty acid fractionation plant to optimize energy recovery and controllability, Chemical 
Engineering Transactions 45, 97-102.  

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

Akbarnia M., Amidpour M. S., 2009, A new approach in pinch technology considering piping costs in total cost 
targeting for heat exchanger network, Chemical Engineering Research and Design 87, 357-365.  

Kang L., Liu Y., Wu L., 2016, Synthesis of multi-period heat exchanger networks based on features of sub-
period durations, Energy 116, 1302-1311. 

Kravanja Z., Glavi P., 1997, Cost targeting for HEN through simultaneous optimization approach : a unified 
pinch technology and mathematical programming design of large HEN, Computers and Chemical 
Engineering 21, 833-853. 

Sarut T., Kitipat S., 2014, Water and heat exchanger network design for fixed-flowrate system, Chemical 
Engineering Transactions 39, 193-198. 

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. 

Zhang C., Cui G., Chen S., 2016, An efficient method based on the uniformity principle for synthesis of large-
scale heat exchanger networks, Applied Thermal Engineering 107, 565-574. 

 
 

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