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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 SVarbanov, Rongxin Su, Hon Loong Lam, Xia Liu, Jiří J Klemeš
Copyright © 2017, AIDIC Servizi S.r.l. 
ISBN978-88-95608-51-8; ISSN 2283-9216 

Comparative Study of Adaptability for S-zorb Unit Based on 
Exergy Analysis and Entransy Analysis 

Li Xia, Yuanli Feng, Shuguang Xiang* 

Institute of Process System Engineering, Qingdao University of Science and Technology, Qingdao, Shandong, China 
xsg@qust.edu.cn 

The mathematical models for calculating the energy utilization efficiency of heat exchanger networks (HENs) 
based on exergy analysis method and entransy analysis method are built, respectively. With the goal of 
maximum energy recovery, the HENs of the gasoline adsorption desulfurization (S-zorb) unit are analysed by 
these two models. The exergy loss is accurately calculated using subsection integral by temperature-enthalpy 
(T-H) diagram. The entransy dissipation is calculated by the integration of the cold and hot composite curves 
in the temperature-heat flow rate (T-Q) diagram. The results are obtained in three different ∆Tmin15 K, 20 K 
and 25 K. Then, the adaptability of the two methods to the HENs of the S-zorb unit was further compared. For 
the S-zorb unit, the exergy efficiency decreases, respectively 89.89 %, 88.21 %, 86.49 %, and save utility 
about 82.90 %, 72.13 %, 67.46 %. The entransy transfer efficiency also decreases 92.41 %, 91.07 %, 89.73 
%, and save utility about 80.03 %, 72.33 %, 64.63 %. Compared with exergy analysis method, the calculation 
process of entransy dissipation is simpler, and the results are closer to reality. The entransy analysis method 
is more suitable for the analysis of energy utilization efficiency of the HENs of S-zorb unit. 

1. Introduction 

The first law of thermodynamics only reflects the quantitative relationship of energy, but does not reflect the 
quality of energy. Aiming at this problem, Rant (1956) introduced a new thermodynamic parameter which was 
called “exergy”. Ahern (1980) proposed exergy analysis method which can effectively analyse the value, 
cause and location of the exergy loss. At present, exergy analysis method has been widely studied in many 
fields, such as petroleum and chemical industry (Ghannadzadeh and Sadeqzadeh, 2016), blast furnace 
smelting (Liu et al., 2015), pneumatic pulsator system (Wolosz and Wernik, 2016), environmental resource 
(Park et al., 2014), ecosystem (Mabrouka et al., 2016). 
Scholars have been looking for ways to improve the energy utilization efficiency in petrochemical industry 
(Oravec et al., 2015). In the study of HENs synthesis, Linnhoff (1990) has introduced the concept of exergy 
loss into the design of HENs. After a great deal of research, the exergy analysis method used for HENs 
synthesis is divided into graphic method (Stijepovic et al., 2014) and formula method (İpeka et al., 2017), 
objective function method (Miladi et al., 2016) etc. However, due to the complexity of the calculation process 
of the exergy, the use of exergy analysis method for HENs in petrochemical industry is limited. 
Based on the nature of heat transfer phenomena, Guo et al. (2007) introduced a new physical quantity, 
entransy. In recent years, some scholars have introduced the idea of entransy into HENs synthesis (Li et al., 
2016), such as heat exchanger design, graphical method. But no research has been done on using entransy 
dissipation for computing the entransy transfer efficiency of a petrochemical unit. 
The exergy analysis method and entransy analysis method are based on the second law of thermodynamics, 
but they have their own characteristics. For the HENs synthesis of petrochemical unit, which method is better? 
In this work, with the goal of maximum energy recovery, the HENs of the S-zorb unit are analysed by these 
two methods. The energy utilization efficiency of the HENs for the S-zorb unit is respectively calculated using 
the exergy analysis method and entransy analysis method. Then, the adaptability of the two methods to the 
HENs of the S-zorb unit was further compared. 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1761302

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Xia L., Feng Y., Xiang S., 2017, Comparative study of adaptability for s-zorb unit based on exergy analysis and 
entransy analysis, Chemical Engineering Transactions, 61, 1825-1830  DOI:10.3303/CET1761302  

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2. Exergy analysis method and entransy analysis method of HENs 

2.1 Exergy analysis method of HENs 

Exergy analysis method of HENs is based on the first and second laws of thermodynamics. Its aim is to study 
the effective use of energy in the process. Through the calculation of the exergy efficiency of HENs, energy 
analysis method can evaluate energy use efficiency of HENs. 
Based on the T-H diagram, the balanced composite curves of hot and cold streams (including utilities) can be 
made. The exergy loss of the HENs is calculated by using the integral method (Jin et al., 2008). 

( ) ( ) ( )1 2
1 1

0 0 0
0∆

n

n

Q Q Q
L H C H C H CQ Q

H C H C H C

T T T
E T T δQ T T δQ T T δQ

T T T T T T−
= − + − + ⋅ ⋅ ⋅ + −  

⋅ ⋅ ⋅
  

(1) 

where ∆EL denotes the exergy loss, TH and TC are changed continuously with the line relations between 
temperature and enthalpy, T0 denotes ambient temperature. 
According to Eq(1), the exergy efficiency of stream is: 

( )00
1

,

0 , ,
1

∆
1

∆ (1 / )

n
n

Q
H C

i H CL
e o n

H
h,i m h i

i

T
T T δQ

T TE
η

E Q T T

=

=

− 
⋅

= − =
−

  

(2) 

where the subscripts i denotes the stream numbers;
 
 Tm,h,i denote the log mean temperature difference. 

In order to determine the weak links in the process,
 
 exergy loss rate eL,i is the ratio of the exergy loss of each 

part to the exergy loss of all equipment: 

0

1,i
,

,i , 0 , , , 0 ,c,
1 1 1

( )
∆

(1 / ) (1 / )

n
n

Q
H Co

iL H C
L i n n n

L h i m h i c i m i
i i i

T
T T δQ

E T T
e

E Q T T Q T T

=

= = =

− 
⋅

= =
− − −  

  (3) 

According to the different heat transfer temperature differences, the calculation exergy efficiency using the Eq 
(2) is ηe,1, ηe,2.... The result of exergy loss rate by Eq(3) reveals that there exist larger energy consumption of 
the equipment, such as heat exchanger, cooler, air cooler, steam generator, etc. 

2.2 Entransy analysis method of HENs 

The quantity of entransy (absolute zero is taken as the zero temperature potential) can be written as 

nh

i=1
H h,iE E=  ,

nc

i=1
=C c,iE E , 

2 2
, , , , ,out

1
( )

2h,i
h i h i in h iE CP T T= − , 

2 2
c, c, ,out , ,

1
( )

2c,i
i i c i inE CP T T= −   (4) 

where CP denotes heat capacity flowrate, the subscripts in and out denote the inlet and outlet states, 
respectively. 
In addition, the calculation of the quality of entransy can be obtained by the integration of the cold and hot 
composite curves with the Q-axis in T-Q diagram

 
(Wu and Guo, 2013). The entransy dissipation of the whole 

heat transfer process is: 

n n n n

,

h c h c
2 2 2 2
, , , , , , ,

i=1 i=1 i=1 i=1

1 1
∆ ( ) ( )

2 2h i c,i
h,i c,i h i in h i out c i out c i,inE E E CP T T CP T T= − = − − −      (5) 

Therefore, the entransy transfer efficiency is: 

 −

 −
==

=

=
n

1i

2
i,,

2
i,,i,

n

1i

2
i,,

2
i,,i,

0

)(

)(

outhinhh

incoutcc

H

C

TTCP

TTCP

E

E
η   (6) 

According to the calculation of different entransy transfer efficiency of different energy targets, the maximum 
heat transfer capability of hot streams of HENs is determined. 
From the whole process, the calculation of entransy and entransy dissipation in entransy analysis are not 
affected by ambient temperature, but the calculation of exergy and exergy loss in exergy analysis are affected. 
In addition, the exergy loss

 
needs to be calculated by the integral method, and the calculation process is 

complex.
 
 The entransy analysis greatly simplifies the calculation process. 

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3. Comparison of exergy analysis and entransy analysis in HENs of S-zorb unit 

S-zorb technology is a kind of adsorption desulfurization technology developed by ConocoPhillips company for 
FCC gasoline fraction. The process flowsheet of S-zorb unit is shown in Figure 1.The hot and cold stream 
data of HENs is shown in Table 1, the utilities data can see Table 2 (Li et al., 2011). 

 

Figure 1: The process flowsheet of S-zorb unit 

Table 1: Stream data 

Stream Stream description Supply 
Temperature [K]

Target 
Temperature [K] 

CP 
[kW·K-1] 

H1A The top export stream of R101 707 519 83.06 
H1B The top export stream of R101 519 405 120.06 
H2 The top stream of D104 405 308 12.06 
H3 The top stream of C201 324 303 4.25 
H4 The bottom product of C201 424 313 62.2 
H5 The stream of E106 345 313 0.63 
H6 The condensated water of D202 419 316 1.95 
C1A Mix hydrogen materials 353 523 104 
C1B Mix hydrogen materials 523 685 82.72 
C2 The bottom of D121 300 352 3.86 
C3 The bottom reboiler of C201 424 427 543.38 
C4 Demineralized water 313 370 69.93 
C5 The circulating hydrogen through F101 320 632 0.89 

Table 2: Utilities data 

Utilities Number Stream Supply 
Temperature[K]

Target 
Temperature[K] 

CP 
[kW·K-1] 

Hot 
utilities 

HU1 [F101] Mix hydrogen materials 650 685 89.17 
HU2 [E203] The reboiler of C201 424 427 543.33 
HU3 [F101] Circulating hydrogen 320 632 0.89 

Cold 
utilities 

CU1 [H1A] The top export stream of R101 421 404 86.18 
CU2 [E104,A101] The top stream of D104 405 308 12.06 
CU3 [E204] The bottom product of C201 363 313 58.38 
CU3 [E202,A201] The top stream of C201 324 303 4.24 
CU4 [E106] The stream of E106 345 313 0.63 

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3.1 Analysis of existing HENs 

Select the ambient temperature T0 = 298.15K, pressure = 0.1013MPa. 
(1) Exergy analysis 
The exergy of hot streams and cold streams are 14,270 kW and 13,860 kW, respectively. The exergy loss is 
3,125kW, the exergy efficiency is 78.10%, the total exergy loss rate is 21.90%. In addition, the exergy loss 
rates of HU1, CU1, CU3 are highest in the utilities. The values are 55.25%, 12.99% and 10.86%, respectively. 
(2) Entransy analysis 
The entransy of hot streams and cold streams are 18,970 MW·K and 18,090 MW·K. The entransy dissipation 
is 13,430 MW·K, the entransy transfer efficiency is 80.04 %, the total entransy dissipation rate is 19.96 %. In 
addition, the entransy dissipation rates of HU1, CU1, CU2, CU3 are highest in the utilities. The values are 
10.98%, 2.31% and 5.45%. 
Exergy analysis and entransy analysis has obtained the location of the energy loss for S-zorb unit. Compared 
with exergy analysis method, the results of entransy analysis method are closer to reality. 

3.2 The maximum energy recover HENs 

It is assumed that ∆Tmin is 20 K. Pinch Temperature 363 K is determined (see Figure 2). 
Selecting different ∆Tmin: 15 K, 20 K and 25 K, the results calculated by exergy analysis and entransy analysis 
are shown in Table 3, Table 4. The efficiency of different ∆Tmin is shown in Figure 3.When ∆Tmin is 15 K, 20 K 
and 25 K, the exergy efficiency is 89.89 %, 88.21 %, 86.49 %, saving utilities is 82.90 %, 72.13 %, 67.46 %. It 
is indicated that the larger the temperature difference, the lower quality of hot streams. When ∆Tmin is 15 K, 20 
K and 25 K, the entransy transfer efficiency is 92.41 %, 91.07 %, 89.73 %, saving utilities is 80.03 %, 72.33 %, 
64.63%. It is obvious that the larger the temperature difference, the more entransy dissipation, the more utility 
requirements, and the lower entransy transfer efficiency. 

0 5000 10000 15000 20000 25000 30000 35000 40000

300

400

500

600

700

 Hot stream
 Cold stream

 

T
(K

)

Q[kW]  

Figure 2: Composite Curves diagram 

Table 3: The results of exergy analysis method 

 ∆Tmin = 15 K ∆Tmin = 20 K ∆Tmin = 25 K
Hot streams exergy [kW] 13,880 13,750 13,610 
Cold streams exergy [kW] 13,730 13,860 13,990 
Hot utilities exergy [kW] 466.0 677.3 887.4 
Cold utilities exergy [kW] 89.488 228.2 170.0 
Exergy loss [kW] 1,403 1,622 1,840 
Exergy efficiency[%] 89.89 88.21 86.49 

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Table 4: The results of entransy analysis method 

 ∆Tmin = 15 K ∆Tmin = 20 K ∆Tmin = 25 K

Hot streams entransy [MW·K] 18,970 18,970  18,970 
Cold streams entransy [MW·K] 18,090 18,090 18,090 
Hot utilities entransy [MW·K] 564.3 819.6 1,073 
Cold utilities entransy [MW·K] 424.6 550.6 678.6 
Entransy recovery [MW·K] 17,530 17,270  17,020 
Entransy dissipation [MW·K] 1,015 1,144 1,269 
Entransy transfer efficiency [%] 92.41 91.07 89.73 
Entransy saving [%] 80.03 72.33 64.63 

 
According to Figure 3, the changing trend of entransy transfer efficiency is close to exergy efficiency. But 
entransy savings curve is more stable than exergy savings curve. In summary, exergy analysis and entransy 
analysis can analyse the energy utilization efficiency of the HENs. Compared with exergy analysis method, 
entransy analysis is more conducive to propose reasonable energy saving measures. 

15 20 25

64
66
68
70
72
74
76
78
80
82
84
86
88
90
92

 Exergy efficiency
 Entransy efficiency
 Exergy savings
 Entransy savings

 

η
(%

)

△T
min

[K]
 

Figure 3: The efficiency of different ∆Tmin 

4. Conclusions 

The exergy analysis and entransy analysis can be used to analyse the utilization of energy in the HENs. The 
calculation process of exergy loss in the exergy analysis is complex. Exergy analysis method is carried out 
under certain ambient temperature, the temperature is different in different research objects, and pay more 
attention to the use of heat can be converted into useful work to measure the heat quality of the entire system. 
But entransy analysis method is used to calculate the heat transfer efficiency of the actual system. It is 
obvious that the calculation process of entransy dissipation is simpler. 
The S-zorb unit of the industrial case study is shown in this paper. Setting temperature differences ∆Tmin is 15 
K, 20 K, 25 K, the similar changing trend can be obtained (see Figure 3). It is found that entransy savings 
curve is more stable than exergy savings curve. Exergy analysis and entransy analysis has obtained the 
location of the energy loss for S-zorb unit. It is found that the results of entransy analysis method are closer to 
reality. Entransy analysis has better adaptability to the HENs than exergy analysis. 

Acknowledgments  

This work is supported by the National Natural Science Foundation of China (21406124). 

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