http://journal.uir.ac.id/index.php/JGEET 
 

 
 

E-ISSN : 2541-5794  
     P-ISSN : 2503-216X  

Journal of Geoscience,  
Engineering, Environment, and Technology 
Vol 04 No 01 2019 

 

 
 Erfando, T., et al / JGEET Vol 04 No 01/2019  49 

 

RESEARCH ARTICLE 
 

The Key Parameter Effect Analysis of The Polymer Flooding on 
Oil Recovery Using Reservoir Simulation 

Tomi Erfando 
1
*, Novia Rita

1
, Romal Ramadhan

1
 

1
 Petroleum Engineering Department, Engineering Faculty, Universitas Islam Riau Jl. Kaharuddin Nasution 113 Pekanbaru, Riau, 28284 Indone sia 

 
* Corresponding author : tomyerfando@eng.uir.ac.id 
Received: September 10, 2018; Accepted: January 1, 2019. 
DOI: 10.25299/jgeet.2019.4.1.2107 

 
Abstract 

As time goes by, there will be decreasing of production rates of a field along with decreasing pressure. This led to the necessity 
for further efforts to increase oil production. Therefore, pressure support is required to improve the recovery factor. Supportable 
pressure that can be used can be either water flooding and polymer flooding. This study aims to compare recovery factor to 
scenarios carried out, such as polymer flooding with different concentrations modeled in the same reservoir model to see the 
most favorable scenario. The method used in this research is reservoir simulation method with Computer Modeling Group (CMG) 
STARS simulator. The study was carried out by observing at the pressure, injection rate, and polymer concentration on increasing 
field recovery factor. This study used cartesian grid with the assumption of homogeneous reservoir, there are no faults or other 
geological condition in the reservoir, and driving mechanism is only solution gas drive. This reservoir, oil type is light oil with 

I and layer of conglomerate rock. The simulation result performed with various scenarios provides a good 
result. Where the conditions case base case field recovery factor of 6.7%, and after water flooding produced 25.5% of oil, whereas 
with tertiary recovery method is polymer flooding was carried out with four concentrations of 640 ppm, 1,500 ppm, 3,000 ppm, 
and 4,000 ppm obtained optimum values at 4,000 ppm polymer concentration with recovery factor 28.9%, SOR reduction final 
value 0,5255, polymer adsorption of 818,700 ppm, reservoir final pressure 1,707 psi, and an increase in water viscosity to 0.94 
cP. 
 
Keywords: Polymer flooding, SOR reduction, polymer adsorption 
 

 
1. Introduction  

The rate of oil production will decrease over time, 
due to reduced reservoir pressure and reduced amount 
of oil reserves in the field. In early stages of primary 
recovery, several oil wells used artificial technology lift, 
but this technology was no longer optimal in producing 
oil to the surface (El-Khatib, 2001). Therefore, efforts 
are needed to increase oil production and recovery 
factors from the area, the effort to be carried out is 
water injection or waterflood (Erfando et al., 2017; 
Erfando and Herawati, 2017; Rita, 2016). 

Water flooding is a proven method for improving 
offtake rate and ultimate recovery from conventional 
oil reservoirs. Although relatively inexpensive and 
straightforward to operate, the dynamics and eventual 
performance of waterflooded reservoirs are controlled 
by complex interactions of several factors. Due to this 
complexity, it has been challenging to develop a robust, 
consistent and yet simple normalizing parameter for 
comparing the performances and recoveries of 
different reservoirs under waterflood (Tetegan et al., 
2015). 

The conversion of conventional waterflood to a 
polymer flood entails significant injectivity reduction, 
up to 50% or more. The maintenance of complete 
voidage replacement (VRR = 1) would thus require an 

increase in the number of injectors or a reduction of 
total production rate or both. As both interventions 
reduce the economic returns (San Blas and Vittoratos, 
2014). 

Polymer flooding was initially used in 1960s and 
since then has been used frequently to increase sweep 
efficiency by reducing the mobility mismatch of oil and 
aqueous phase. It helps in near wellbore region to 
improve the water flooding process. In waterflooding 
projects, an increase in injected water viscosity is 
expected. The key measure of success of these projects 
is the stability of the displacement process during 
water injection (Temizel et al., 2017). 

Polymer flooding has been used to enhance oil 
production and reduce water cut for a long time. 
However, there are still many fundamental challenges 
in characterizing the multiphase-fluid flow, even the 
single-phase-fluid flow, associated with polymer 
flooding. Various EOR techniques are being tested and 
used for recovering some of the oil left behind after 
conventional waterflooding. Among the EOR 
approaches, polymer flooding may be one of the most 
widely used, promising, and cost-effective methods. 
The preinjection of polymers has been proposed as a 
means for improving reservoir sweep efficiency by 
reducing permeability contrasts (Li et al., 2014). 

http://journal.uir.ac.id/index.php/JGEET
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50  Erfando., T., et al. / JGEET Vol 04 No 01/2019   
 

Hydrocarbon recovery increases when oil as 
displaced fluid and water as the displacing fluid has a 
mobility ratio near one. When volumetric sweep 
efficiency increases, the mobility ratio decreases. If the 
mobility ratio is higher than one, polymers or gels can 
help to increase the viscosity of injected fluids for 
increasing oil recovery. Polymer flooding and gel 
treatment are one of the most common EOR techniques 
that have been used over four decades due to its 
reasonable recovery rates and suitable application. 
Polymers are added to the injection fluid to increase its 
viscosity, thereby reducing their mobility ratio, and 
resulting in increased oil recovery (Cenk et al., 2017). 

Recently, there are increasing interest on polymer 
flooding due to its high enhanced oil recovery (10%- 
20% OOIP in field tests in Daqing) and much lower cost 
compared to surfactant-polymer (SP) flooding and 
alkali-surfactant-polymer (ASP) flooding (Guo, 2017).  

This study was carried out without considering the 
cost of polymer prices and polymer flooding process, 
the only focused on which concentration worked best 
on increasing oil recovery. 

2. Materials and Methods 

2.1. Reservoir Fluid and reservoir rock 
characteristics 

Table 1. Reservoir fluid characteristics (Pertamina, 2016) 

Oil Properties 

Density 0.835 

Viscosity 1.13 cp 

Formation Volume Factor 1.14 rb/stb 

API Gravity 40.3
0
 API 

Specific Gravity 0.82 

Oil Type Light Oil 

Bubble Point Pressure 993 psig 

 

Table 2. Reservoir rock characteristics (Pertamina, 2016) 

Parameter Value Unit 

Rock Type Conglomerate - 

Thickness 20 Ft 

Porosity 16.5 % 

Horizontal Permeability 100 mD 

Vertical Permeability 100 mD 

Rock Compressibility  5. 10−6 psi−1 

2.2 Methods 

The method used in this research is reservoir 
simulation method with Computer Modeling Group 
(CMG) STARS simulator. This research was conducted 
by taking field data on Barito Basin, Borneo Island, 
Indonesia 

3. Polymer Properties 

This study used gel polymer (Pregel) with a 
molecular weight of 10,206 lb/lb mole, the density of 
1,000 [lb/ft]

3
 and viscosity of 20 cP. Analysis of 

concentration is polymer needed to optimize oil 

recovery in the process of polymer flooding. The 
concentration polymer used in this study was 640 ppm, 
1,500 ppm, 3,000 ppm, and 4,000 ppm. The parameter 
of polymer flooding: injection is carried out 1.2 PV, 
with the total fluid injected 614,473 barrels of polymer 
solutions for 2.5 years, with polymer solutions injected 
per day is 670 barrels for 916  injection. Injection 
pressure is set at 2,000 psi. 

The selection of polymer flooding concentrations is 
based on Gao, Jiang, Zhang, et al., 2016 paper, according 
to them, oil displacement experiment results show that 
when the polymer solution dosage is 640 ppm, the 
incremental oil recovery is only 1.98% with polymer 
concentration increasing from 1000 ppm to 3000 ppm. 
When the polymer dosage is reach 1280 ppm. PV, the 
incremental oil recovery is also only 2.2% with polymer 
concentration increasing from 1000 ppm to 3000 ppm. 
Only increasing both polymer concentration and 
dosage, can good oil displacement effect be obtained 
when the polymer dosage reaches up to 1280 ppm. PV 
and polymer concentration increases to 2000 ppm; the 
incremental oil recovery can reach above 10%. Thus, the 
incremental oil recovery can be increase greatly by 
increasing both polymer concentration and dosage 
after polymer flooding. 

Table 3. Polymer flooding parameters of injection 

No Parameter Value 

1 PV 1.2 PV 

2 Injection Rate 670 bpd 

3 Injection Time 916 days 

4 Injection Pressure 2,000 psi 

4. Result and Discussion 

4.1. Polymer Concentration Analysis 

According to (Gao et al., 2016) high concentration 
polymer flooding can further enlarge sweep volume 
and improve mobility ratio between the displacing 
fluid and crude oil, which is effective to exploit the 
remaining oil after polymer flooding. High 
concentration polymer flooding after polymer flooding 
has good mobility control ability and can enlarge swept 
volume to enhance oil recovery. Meanwhile, High 
concentration polymer has good viscoelasticity, which 
is able to pull residual oil and reduce all kinds of 
residual oil volume, thus increases microscopic 
displacement efficiency. 

High concentration polymer flooding (HCPF) has 
been one of the enhanced oil recovery (EOR) methods 
since conventional polymer flooding because its higher 
viscoelasticity can improve the oil displacement 
efficiently. HCPF produced liquid is characterized by 
high viscosity, and strong emulsification tendency and 
stability. The emulsification effect of the low water cut 
produced liquid is more obvious as the polymer-
containing concentration rising up, leads to the phase 
inversion point, at which the emulsion transformed 
from water-in-oil (W/O) to oil-in-water (O/W) or 
water-in-oil-in-water (W/O/W) (Yang et al., 2015).  

Polymer flooding is an advanced stage that is 
carried out after water flooding as tertiary oil recovery. 
The polymer is injected to reduce water mobility as a 



 
Erfando., T., et al. / JGEET Vol 04 No 01/2019 51 

 

driving fluid by increasing its viscosity. For this reason, 
it is necessary to regulate concentration polymer in an 
effort to reduce water mobility so that it is more 
optimal in the oil pressing process. 

Fig.  1 shows that for each increase in concentration 
polymer, the recovery factor for the field also increases. 
polymer flooding 640 ppm of produces recovery oil of 
28.5% of the total OOIP. While polymer flooding with a 
concentration of 1,500 ppm can increase oil production 
to 28.6%. For injection with a concentration of 3,000 
ppm can produce oil of 28.8% from OOIP, and a 
concentration of 4,000 ppm can increase oil recovery by 
28.9%. 

 
Table 4. Comparison of polymer concentration on oil recovery 
 

Polymer 
concentrations, 
Ppm 

Oil production 
cumulative, BBL 

Oil recovery 
factor, 
% 

640 90,306 28.5 

1,500 90,723 28.6 

3,000 91,219 28.8 

4,000 91,332 28.9 

 
RF increase is not too significant for polymer 

flooding even though the concentration polymer that 
has been injected has been increased with a large 
enough value, because injection with concentrations 
above 640 ppm requires greater pressure to reach the 
production well, this is related to the injection viscosity 

polymer which is increasingly thick with increasing 
concentration, because concentration polymer too high 
can cause blocking in small permeability. 

Based on the value of RF and the cumulative 
production obtained in this study, the maximum 
results were shown on polymer flooding with a 
concentration of 4,000 ppm which resulted in RF of 
28.9% of total reserves with cumulative production of 
91,332 barrels of total OOIP on the field. 

This study was carried out without considering the 
cost of polymer prices and polymer flooding process, 
the only focused on which concentration worked best 
on increasing oil recovery. 

4.2. SOR Reduction Analysis 

According to Sheng et al., 2015 Technical screening 

criteria for polymer flooding are empirical, mainly 

based on field-project data and technical knowledge 

describing polymer flooding. Many parameters can 

affect the polymer-flooding process, but the most 

critical are reservoir temperature, formation-water 

salinity, divalent contents, clay contents, oil viscosity, 

and formation permeability. Most polymer-flooding 

projects were carried out in sandstone reservoirs. 

Fewer applications were carried out in carbonate 

reservoirs because anionic polymers such as 

hydrolyzed polyacrylamide (HPAM) have high 

adsorption in carbonates. Also, various carbonate 

reservoirs have a low-permeability matrix, which large 

polymer molecules may not be able to enter. 

 

 

Fig 1. Effect of polymer concentration on oil recovery factor 



 
52  Erfando., T., et al. / JGEET Vol 04 No 01/2019   
 

 

 

Fig.  2. SOR reduction after polymer flooding by various concentrations  

Fig. 2 shows the deployment in the conditions initial 

and final after three years of production. Based on 

picture 4.8 the SOR condition of the initial field is at a 

value of 0.765. Then after producing for three years the 

final saturation of the field decreases. The difference in 

oil saturation values in the final condition on the entire 

field is caused by oil pressure by polymer flooding two 

and a half years. Thus, oil saturation in the reservoir is 

reduced. Reducing the oil saturation value in the final 

condition shows the amount of oil that has been 

produced from the field. 

Oil saturation in this reservoir is equal until it is 

produced, after production the saturation will 

decrease. The higher the concentration of polymer 

injection, the more oil production will be.  

 
Table 5  The initial and final SOR differences after 

polymer flooding 
 

Scenarios SOR Initial SOR Final 

Polymer 640 ppm 0.7650 0.5275 

Polymer 1500 ppm 0.7650 0.5266 

Polymer 3000 ppm 0.7650 0.5257 

Polymer 4000 ppm 0.7650 0.5255 

4.3. Polymer Adsorption Analysis 

Adsorption is a process whereby contact between 
the fluid in the form of gas and liquid, with solid, where 

the substances in the fluid are absorbed by the surface 
of the solid, resulting in changes of the composition of 
the unadsorbed fluid. The adsorption process is usually 
characterized by mass transfer from liquid to solids. A 
liquid concentration higher before flowing in solid 
pores will cause higher adsorption on solid surface. 
Commonly used material as adsorbent are very 
ingredients porous, and adsorption takes place on pore 
walls or in certain locations within particles (Widyarso 
et al., 2006). 

According to Rita, 2011 the adsorption of reservoir 
rocks in polymer injection occurs due to the attraction 
between polymer molecules and reservoir rock and the 
magnitude of this force depends on the magnitude of 
the affinity of the reservoir rocks affinity the polymer. 
If the adsorption is very strong, the polymer becomes 
thinner, consequently the ability to increase the sweep 
efficiency decreases.  

The polymer concentration is directly proportional 
to the polymer adsorption of rock gradually, the higher 
concentration, the greater the adsorption occurring to 
the polymer solution on a rock surface. Conversely, the 
lower the concentration, the smaller the adsorption 
that occurs to the polymer solution on a rock surface. 

Polymer adsorption that occurs in all four 
concentrations carried out by the above polymer 
adsorption theory. Polymers with a concentration of 
640 ppm resulted in the lowest polymer adsorption, 
whereas polymers with 4,000 ppm concentrations 
resulted in the highest polymer adsorption. 



 
Erfando., T., et al. / JGEET Vol 04 No 01/2019 53 

 

 
 
 

 
 
 

 

 
Fig. 3. Polymer adsorption at various polymer concentrations 

 
 
Table 6. Polymer adsorption  at various concentration 

 

Scenarios Polymer adsorption 
(ppm) 

Polymer 640 ppm 680,000 

Polymer 1,500 ppm 790,000 

Polymer 3,000 ppm 818,500 

Polymer 4,000 ppm 818,700 

 
 

 
 

Fig. 4. Pressure final condition after polymer flooding 

 
Fig. 4 shows the deployment value of pressure on the 

field in the final condition. Observable from the color of 
its spread, there is a pressure difference in the 
reservoir. The highest pressure is on the injection wells 
with values ranging from 1,800 psi, then increasingly 

 
Fig.  5. Pressure on some concentrations of polymer flooding 

 
towards the production well the pressure decreases. 
This pressure drop is what causes the production to 
drop in the field. Therefore, polymer injection is 
required with the aim of keeping the pressure at a 
sufficient level in order to produce oil no less than the 
minimum production limit. 

There was a difference in reservoir pressure after 
polymer flooding at different concentrations. At 
polymer concentration of 640 ppm final pressure 
reservoir is 1,671 psi, while for polymer concentration 
1,500 psi, 3,000 psi, and 4,000 psi are 1,681 psi, 1,696 
psi, 1,707 psi. Fig.  5 shows the higher the polymer 
concentration injected, the greater the pressure 
increases.  

-100000

0

100000

200000

300000

400000

500000

600000

700000

800000

900000

09/2017 04/2018 10/2018 05/2019 12/2019 06/2020 01/2021 07/2021

A
d

s
o

rp
ti

o
n

 (
p

p
m

)

Time

640 ppm 1500 ppm 3000 ppm 4000 ppm



 
54  Erfando., T., et al. / JGEET Vol 04 No 01/2019   
 

  
Fig. 6 Pressure effects on production rate 

 

 Fig. 6 shows that simultaneous pressure changes 
follow oil production fluctuations. Changes in pressure 
from January 2018 to July 2018 occurred sharply as 
production relied only on reservoir pressure without 
any effort to maintain reservoir pressure. In July 2018, 
after polymer flooding, it can be seen in Fig. 7. that 
constant pressure changes until September 2020, then 
increased until 2021. The temporary increase in chart 
shows the decrease in oil production can be caused by 
water breakthrough that has reached well production, 
so oil production decreases because there is water 
produced at the same time. 

4.4 Increasing of Water Viscosity Analysis 

Polymer injection is an enhanced water injection to 
improve oil recovery by increasing its viscosity. 
Polymer injections of different concentrations will 
cause an increase in different water viscosity. Typically, 
these two parameters are directly proportional to each 
other. Low-concentration polymer injections will lead 
to a low increase in value when compared to higher-
concentration injections. 

Increased viscosity is very important due to: one 
way to avoid the early breakthrough and high water-
cut is to deploy a polymer flood rather than a 
waterflood. Polymer flooding is an enhanced oil 
recovery technique that aims at improving the mobility 
ratio between the injected and in-situ fluids by 
viscosifying the injected water. Moreover, the 
increased viscosity also results in improved volumetric 
sweep efficiency (Anand and Ismaili, 2016). Increasing 
flooding-solution viscosity with polymers provides a 
favorable mobility ratio compared with water flooding 
and hence improves volumetric sweep efficiency. 
Flooding with a polymer solution exhibiting elastic 
properties has been reported to increase displacement 
efficiency, resulting in a sustained doubling of the 
recovery enhancement compared with the use of 
conventional viscous-polymer flooding (Clarke et al., 
2016). 

In this study, polymer flooding was performed at a 

means that the viscosity of pure water under these 
conditions is 0.5 cP. So by doing polymer flooding, the 
water viscosity will increase along with the polymer 
concentration injected. 

Polymer flooding has been used to improve the 
development effect and to enhance oil recovery for 
dozens of years, which is a type of common and 
matured technology. Polymers cannot be used on ideal 
conditions to sweep oil if the reservoir temperature 
exceeds 70 °C if it exceeds that temperature it will 
cause rapid thermal degradation (Wu et al., 2015). 

Scenarios above were done by comparing the four 
concentrations performed under the same conditions. 
At a concentration of 640 ppm, the viscosity value was 
0.55 cP, for a concentration of 1,500 ppm the viscosity 
increased to 0.59 cP, whereas for a concentration of 
3,000 ppm the viscosity increased by 0.82 cP, and for a 
concentration of 4,000 ppm the viscosity increased to 
0.94 cP. 

 

 
 Fig. 7. Increasing water viscosity by various concentrations of polymer flooding. 

0

0,1

0,2

0,3

0,4

0,5

0,6

0,7

0,8

0,9

1

9/17 4/18 10/18 5/19 12/19 6/20 1/21 7/21

W
a

te
r 

V
is

c
o

s
it

y
, 

(c
P

)

Time

640 ppm 1500 ppm 3000 ppm 4000 ppm



 
Erfando., T., et al. / JGEET Vol 04 No 01/2019 55 

 

 
Table 7. Polymer Viscosity at various concentration 

Polymer 

Concentration 

Polymer  

Viscosity 

640 ppm 0.55 cP 

1,500 ppm 0.59 cP 

3,000 ppm 0.82 cP 

4,000 ppm 0.94 cP 

 

5. Conclusion 

The most critical factor in the polymer flooding 
process is the injection concentration, because it will 
have impacts on SOR reduction and increased pressure 
from the reservoir, on the adsorption of polymers in 
rock matrix, and an increase in water viscosity which 
helps in increasing sweep efficiency. 

Based on the results of research and discussion that 
has been done, then the conclusions obtained from this 
study is the tertiary recovery method of polymer 
flooding conducted with four concentrations, the 
optimum value obtained at 4,000 ppm polymer 
concentration with recovery factor 28.9%, SOR 
reduction with final value 0,5255, polymer adsorption 
of 818,700 ppm, final reservoir pressure 1.707 psi, and 
water viscosity increase to 0.94. 
 

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© 2019 Journal of Geoscience, Engineering, 

Environment and Technology. All rights 
reserved. This is an open access article 

distributed under the terms of the CC BY-SA License 
(http://creativecommons.org/licenses/by-sa/4.0/). 

 
 

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https://doi.org/10.2118/172768-MS
https://doi.org/10.2118/172768-MS
https://doi.org/10.2118/172768-MS
https://doi.org/10.2118/172768-MS
https://doi.org/10.2118/172768-MS
http://creativecommons.org/licenses/by-sa/4.0/
http://creativecommons.org/licenses/by-sa/4.0/

	The Key Parameter Effect Analysis of The Polymer Flooding on Oil Recovery Using Reservoir Simulation
	1. Introduction
	2. Materials and Methods
	2.1. Reservoir Fluid and reservoir rock characteristics
	2.2 Methods

	3. Polymer Properties
	4. Result and Discussion
	4.1. Polymer Concentration Analysis
	4.2. SOR Reduction Analysis
	4.3. Polymer Adsorption Analysis
	4.4 Increasing of Water Viscosity Analysis

	5. Conclusion
	References