Format And Type Fonts


 

 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 39, 2014 

A publication of 

 
The Italian Association 

of Chemical Engineering 

www.aidic.it/cet 
Guest Editors: Petar Sabev Varbanov, Jiří Jaromír Klemeš, Peng Yen Liew, Jun Yow Yong  

Copyright © 2014, AIDIC Servizi S.r.l., 

ISBN 978-88-95608-30-3; ISSN 2283-9216 DOI: 10.3303/CET1439254 

 

Please cite this article as: Palacios-Bereche R., Ensinas A.V., Modesto M., Nebra S.A., 2014, Extraction process in the 

ethanol production from sugarcane – a comparison of milling and diffusion, Chemical Engineering Transactions, 39, 1519-

1524  DOI:10.3303/CET1439254 

1519 

Extraction Process in the Ethanol Production from 

Sugarcane – A Comparison of Milling and Diffusion 

Reynaldo Palacios-Bereche
a
, Adriano V. Ensinas

a,b
, Marcelo Modesto

a
, 

Silvia A. Nebra*
a,c

 
a 
Centre of Engineering, Modelling and Social Sciences, Federal University of ABC (CECS/UFABC), Rua Santa Adélia 

166, Bangu, Santo André, SP, Brazil, CEP 09210170,  
b 
École Polytechnique Fédérale de Lausanne, Switzerland,  

c
 Interdisciplinary Centre of Energy Planning, University of Campinas (NIPE/UNICAMP), Cidade Universitária “Zeferino 

Vaz”, Rua: Cora Coralina, 330, P.O.Box: 6166, CEP: 13083-896, Campinas, SP, Brazil 

silvia.nebra@pq.cnpq.br 

The objective of the extraction process in the ethanol production from sugarcane is to separate the 

sucrose-containing juice from the remainder of the cane, mainly fibre. The two currents, products of this 

process, are the juice and the bagasse. The juice is used to produce ethanol and the bagasse is the fuel 

for the boilers. Two types of devices are employed to perform this operation: mills and diffusers. Each one 

of them consumes different types of energy: mills consume mechanical energy, diffusers consume 

basically thermal energy. As both devices utilize an important quantity of energy, their effect in the energy 

balance of the factory needs to be taken into account. Aiming to discuss and characterize these effects, 

simulations of the complete ethanol production process, including the cogeneration system, were carried 

out using the Aspen Plus software, considering both devices. Process integration was also performed 

targeting to reduce the energy consumption. These results are presented and compared. Considering the 

integrated ethanol production process, with extraction -condensing steam turbines in cogeneration system, 

working with mills, it can produce an electricity surplus of 83.4 kWh/t of sugarcane, however, for the same 

conditions, working with the diffusion extraction process a production of 91.3 kWh/t of cane can be 

obtained, including also a small increase of 2 % in the ethanol production.  

1. Introduction 

The industrial process of ethanol production begins with the preparation of the cane and the extraction of 

the juice, which will be used in the sequence as the principal raw material for the final product. 

The pre-treatment system consists of feed tables for whole stick cane discharge, carrier rollers, leveller 

knives, set of knives and shredder. Heavy duty knives are necessary depending of the kind of extraction 

system.  

Extraction systems usually adopted are composed by mills and/or diffusers. In Brazil, from 455 total mills 

in 2011, 23 uses diffusers; the use of diffusers is increasing in the last years (Oliverio et al., 2013). Mills 

are generally connected to direct drive turbines that consume steam (22 bar, 300 ºC) as driving force, but 

electric engines are increasingly being used due to their best energy performance. The diffuser is another 

option for juice extraction. The principle of the diffuser is the application of imbibition water in the cane for 

the extraction of the juice through a lixiviation process. The water and the juice re-circulated in the piece of 

equipment are heated with low pressure saturated steam (2.5 bar or lower).  

As both types of equipment consume different energy inputs, their impact in the factory energy balance is 

completely different and deserve to be analysed. Comparison of the energy consumption between milling 

and diffusers has been done by some authors; see for instance Hoekstra (1995). The change of the 

traditional milling systems by diffusers should increase 3 to 6 % the sugar production at very reasonable 

cost (Van Hengel, 1990). The introduction of diffusers in place of mills changes the energy profile of 

factories (Birkett, 1999).  



 

 

1520 

 
This paper aims to assess both extraction systems: mills and diffusers using direct drive steam turbines or 

electrical engines, evaluating their influence on electricity generation. Two types of cogeneration systems 

were simulated that use back pressure and extraction – condensing steam turbines. The energetic 

integration through the Pinch method was performed for the diffusor extraction system.  

2. Production System 

Figure 1 presents the block diagram of the ethanol production process adopted in this study. The process 

simulation was carried out using software Aspen Plus ®. Cane dry cleaning, and two different extraction 

systems were assumed. In the juice treatment, the following operations were adopted: screening, heating, 

liming, decantation, and mud filtration. Since the must for ethanol production is prepared from sugarcane 

juice; treated juice should be concentrated until an appropriate sugar concentration for fermentation 

process (approximately 17 %). The concentration of treated juice takes place in a multiple-effect 

evaporation system (5 effects) (Dias et al., 2009). Vapour bleedings resulting from the concentration 

process are used for heating raw juice in the treatment step. Must sterilization is carried out by a HTST-

type treatment (High Temperature Short Time), with heating to 130 °C followed by fast cooling down to the 

fermentation temperature of 32 °C (Dias et al., 2009). In this study, fermentation was based on the Melle-

Boinot process (cell-recycle batch fermentation). Following that, the wine is sent to distillation and 

rectification columns where hydrated ethanol (93.7 % wt. of ethanol) and vinasse (0.02 % wt. of ethanol) 

are separated. For ethanol dehydration, a process of extractive distillation with monoethylene glycol was 

simulated. The main operational parameters of the modelled plant are: mill capacity, 2,000,000 t cane/y; 

crushing rate, 500 t cane/h; season operations h, 4,000 h/y; and bagasse production, 277 kg/t cane. The 

specific parameters for unit operations were adopted according to Palacios-Bereche et al. (2013). 

 

 

 

Figure 1: Scheme of the ethanol production process from sugarcane 

2.1 Milling and diffusor 

A scheme of both systems is presented in Figure 2. Both systems are preceded by a sugarcane 

mechanical preparation system (Rein, 2007).  

Milling units perform extraction in successive and gradual compression stages. The combined 

arrangement of a series of mills form what is called “milling tandem”. Imbibition water is added in counter-

current to the bagasse. The combination of imbibition with mechanical crushing allows attaining extraction 

rates similar to those of diffusers (Oliverio et al., 2013). Up to 70 to 80 % of the sugars contained in the 

juice are extracted in the first stage of the tandem.  



 

 

1521 

 

Figure 2: Scheme of the extraction systems: a) milling, b) diffuser 

The operating principle of the diffuser is that the imbibition water percolates through a bed consisting of the 

cane fibrous material (the prepared sugarcane), employing gravity as driving force, the extraction of the 

juice is made through a lixiviation process (Rein, 2007). The diffuser can be combined with a first stage of 

milling. It can reach an sucrose extraction of 98.5 %, milling presents a lower extraction parameter 

(Oliverio et al., 2013). The diffuser is followed by a dewatering mill to reach a value of 50 % (w.b.) of 

moisture content in the bagasse, same value than the milling system (Modesto et al., 2009) 

Table 1 reports the value of the parameters adopted in the simulation of the extraction systems.  

3. Cogeneration System  

The system is constituted by boilers, back pressure turbines and/or extraction condensation turbines, 

electric generators, deaerator, pumps. Bagasse is used as fuel. The main characteristics are reported in 

Table 2. Two products are obtained: steam at 2.5 and 6 bar and electric energy. The values selected for 

the temperatures and pressure of the steam are the highest found nowadays at the Brazilian industry.  

Table 1: Parameters adopted in the extraction systems 

Parameter Milling Diffuser 

Imbibition water (kg/t of cane)
1,2

 300  358.4 

Temperature of imbibition water (°C)
3,4

 50 85 

Sugar extraction efficiency (%)
5,6

    96.2 98 

Bagasse moisture content (%)
2
 50 52 

Mechanical power demand (kWh/t of cane)
2
 16   9 

Diffuser operational temperature (°C)
6
   80 

Raw juice temperature (°C)
6
   60 

Bagasse temperature (°C)
6
   63 

Recirculation rate in the juice heat exchangers (%)
6
  300 

Juice temperature in the output of the heat exchangers (°C)
6
   90 

1
Elia Neto et al. (2009) for milling; 

2
Ensinas et al (2007) for diffuser; 

3
Ensinas (2008); 

4
Fernandez-Parra (2003); 

5
Palacios-Bereche (2011) for milling; 

6
Rein (2007) 

Table 2: Main parameters adopted in the modelling and simulation of the cogeneration system 

Parameter       Value 

Generated steam pressure (bar) 100 

Generated steam temperature (°C) 530 

Turbines isentropic efficiency (high and medium pressure) (%)
1
 80 

Turbine isentropic efficiency (low pressure) (%)
2
 70 

Generator efficiency (%)   97.6 

Turbines Mechanical efficiency (%)   98.2 

Isentropic efficiency of the direct drive turbines (%)  55 

Pump Isentropic efficiency (%) 70 

Boiler thermal efficiency % (LHV base) 86 

Electric power demand of the conventional process (kWh/t of cane) 12 

Condenser pressure (bar)
3
      0.1 

1
 Turbines of electric generation; Ensinas et al. (2007); 

2
 Sanchez Prieto (2003); 

3
 for the cycle with extraction – 

condensation turbines 



 

 

1522 

 
4. Thermal integration 

The thermal integration was performed considering the most interesting energetic option, which is an 

extraction system constituted by a diffuser and electric drivers. Table 3 shows the streams taken into 

account in the thermal integration.  

Figure 3 shows the grand composite curve - GCC for three situations. According the method adopted 

(Palacios Bereche et al., 2014), Figure 3 (a) is referred to the integration of the currents without assuming 

the possibility of using vapour bleedings from the evaporation system. Horizontal bars represents each 

one of the effects of the evaporation system, it can be seen that only the fourth stage intercepts the GCC; 

if the operating pressure of this effect is reduced, the entire evaporation system can be included in the 

process without an increment of the hot utilities. Figure 3 b shows the magnitude of the vapour bleeding 

that could be used in the process. Different options of thermal integration plus bleedings in the evaporation 

system can be implemented. Analysing the curves, and checking different options, a final decision was 

taken: to adopt an evaporation system of only two effects, with bleedings  

of 45.8 t/h in the first effect and 32.9 t/h in the second. For this option (Figure 3 c), a minimum 

consumption target of 116.3 MW is obtained.  

Table 3: Streams included in the thermal integration 

Hot streams 
Ti 

(°C) 

Tf 

(°C) 

∆H* 

(MW) 

 
Cold streams 

Ti 

(°C) 

Tf 

(°C) 

∆H* 

(MW) 

Sterilized juice 130 32 41.8  Juice - HX Diffuser 80 90 17.9 

Phlegmasse 103.8 35 3.1 

 Juice – Direct vapour - 

Diffuser 76.3 80 8.5 

Vinasse 109.3 35 37.9  Imbibition water 25.0 85 12.5 

Anhydrous ethanol  78.3 35 8.8  Juice treatment 60.2 105 29.6 

Vapour condensates 115 35 10.0  Juice pre-heating 98.1 115 2.9 

Condenser - column D 84.9 35 20.5  Juice for sterilization 95.5 130 15.2 

Condenser -  column B 81.6 81.6 26.4  Final wine 31.2 90 35.0 

Condenser extractive 

column 78.3 78.3 7.6 

 

Reboiler column A 109.3 109.3 45.5 

     Reboiler column B 103.8 103.8 22.5 

    

 Reboiler extractive 

column 140.5 140.5 7.3 

    

 Reboiler recuperative 

column 149.6 149.6 2.5 

 
a) b) c) 

Figure 3: a) GCC and evaporation system, b) GCC and potential use of vapour bleedings, c) Final GCC 

with the evaporation system of two effects 

5. Results and discussion 

Five situations are analysed: MST- milling with direct driven turbines, MEE – milling drive by electric 

engines, DST – diffuser with direct driven turbines, DEE – diffuser with electric engines, DEE-TI – diffuser 

with electric engines and thermal integration. Moreover, two configurations are included, relatives to the 

cogeneration system: the first one considers that only back pressure turbines are used, so it presents a 



 

 

1523 

bagasse surplus, the second one considers the use of extraction condensation turbines, with total 

consumption of the available fuel.  

Figure 4 shows the results obtained. The best result is obtained with the DEE-TI system, configuration II, 

with an electricity surplus of 91.3 kWh/t of cane. Comparing the cases DST and DEE in configuration I, the 

bagasse surplus of these cases are the lowest. 

 

 

 
(a) (b) 

Figure 4: (a) Electricity and bagasse surpluses for the first configuration. (b) Electricity surplus for the first 

and second configuration 

In the case of milling, a production of 81.9 L/t of cane is obtained, a little lower than the diffuser, where  

83.6 L/t of cane are obtained. The standard steam consumption is of 467.5 kg/t of cane for milling use and 

500.9 kg/t of cane in the case of diffuser, but when thermal integration is introduced, the steam 

consumption diminishes to a value of 385.9 kg/t of cane.  

The thermal integration assumed that a vapour bleeding of the first effect is used in the reboiler of the 

second distillation column and vapour bleeding of the second effect is used in the juice treatment and in 

the diffusor heat exchangers and direct injection.  

From these results, the thermal total consumption of the diffuser reaches 51.4 kWh/t of cane, similar to 

that reported by Modesto et al. (2009). 

6. Conclusions 

Modelling and simulation of different extraction systems were made. The use of diffusers shows a greater 

consumption of steam that conducts also to a greater production of electricity in the cogeneration system. 

But, with thermal integration, the consumption of steam is significantly reduced and also, the electricity 

produced if back pressure turbines are used, but if extraction condensation turbines are included, the 

electricity generation in this case is the highest.  

Acknowledgments 

The authors wish to thank to CNPq (Process PQ 304820/2009-1) for the researcher fellowship and the 

Research Project Grant (Process 470481/2012-9), and FAPESP for the Post PhD fellowship (Process 

2011/05718-1) and the Research Project Grant (Process 2011/51902-9).  

References 

Birkett L., 1999, Integrating a Cane Diffuser into an Existing Sugar Factory, International Sugar Journal, 

101(1201), 99–104. 

Dias M.O.S., Ensinas A.V., Nebra, S.A., Maciel-Filho R., Rossell C.E.V., Wolf Maciel M.R., 2009, 

Production of bioethanol and other bio-based materials from sugarcane bagasse: Integration to 

conventional bioethanol production process, Chem. Eng. Res. Des., 87, 1206-1216. 

Elia Neto A., 2009, Guide for Water Reuse and Conservation in the Sugar Cane Industry, (in Portuguese). 

Agência Nacional de Águas (ANA), Brasilia, Brazil.  

Ensinas A.V., 2008, Thermal Integration and Thermoeconomic Optimization applied to Industrial Process 

of Sugar and Ethanol from Sugarcane (in Portuguese), Ph.D. Thesis, University of Campinas, 

Campinas, Brazil.  



 

 

1524 

 
Ensinas A.V., Modesto M., Nebra S.A., 2007, Analysis of Different Cane Juice Extractions Systems for 

Sugar and Ethanol Production: Influences on Electricity Generation and Final Products Exergetic 

Costs, Proceedings of ECOS 2007, Padova, Italy, 25-28 June 2007, 727-734. 

Hoekstra R.G., 1995, Energy Consequences of Diffusion versus Milling, Proc. South African Sugar 

Technologists Association, Durban, South Africa, June, 205–207. 

Modesto M., Zemp R., Nebra S.A., 2009, Ethanol Production from Sugar Cane: Assessing the Possibilities 

of Improving Energy Efficiency through Exergetic Cost Analysis. Heat Transfer Engineering, 30(4), 

272-281. 

Oliverio J.L., Avila A.C.R.D., Faber A.N., Soares P.A., 2013, Juice Extraction Systems: Mills and Diffusers 

– The Brazilian Experience, Proc. Int. Soc. Sugar Cane Technol., 28, 1-18.  

Palacios-Bereche R., 2011, Modeling and Energetic Integration of the Ethanol Production from Sugarcane 

Biomass (in Portuguese), Ph.D. Thesis, University of Campinas, São Paulo, Brazil. 

Palacios-Bereche R., Mosqueira-Salazar K.J., Modesto M., Ensinas A.V., Nebra S.A., Serra L.M., Lozano 

M.A., 2013, Exergetic Analysis of the Integrated First and Second Generation Ethanol Production from 

Sugarcane, Energy, 62, 46-61. 

Palacios-Bereche R., Ensinas A.V., Modesto M., Nebra S.A., 2014, New Alternatives for the Fermentation 

Process in the Ethanol Production from Sugarcane: Extractive and Low Temperature Fermentation, 

Energy, 70, 595-604. 

Rein P., 2007, Cane Sugar Engineering, Verlag Dr. Albert Bartens K. G, Berlin, Germany. 

Van Hengel A., 1990, Diffusion as Steam Saver, Zuckerind, 115(7), 551–554. 

http://www.ingentaconnect.com/content/tandf/uhte;jsessionid=27wvdlirflxf3.alexandra