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E-ISSN : 2541-5794  
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Journal of Geoscience,  

Engineering, Environment, and Technology 
Vol 6 No 3 2021 

 

 
Putra, D.F. et al./ JGEET Vol 6 No 3/2021 131 

 

RESEARCH ARTICLE 
 

A Tracer Streamline Practice For Re-Evaluation Waterflood Pattern To 

Introduce A Cyclic Water Injection Scheme 

Dike Fitriansyah Putra1*, Lazuardhy Vozika Futur 1, Mursyidah Umar1 
1 Department of Petroleum Engineering, Islamic University of Riau, Jl. Kaharuddin Nasution No.113 Pekanbaru 28284, Indonesia 

 

* Corresponding author : dikefp@eng.uir.ac.id 

Tel.: +62-812-987-44099 

Received: Nov 8, 2019; Accepted: Aug 30, 2021. 

DOI: 10.25299/jgeet.2021.6.3.4064 

 
Abstract 

Waterflood introduces in the oil field a couple of years ago. Several waterflood schemes have been implemented in the fields to get the best 

incremental oil, such as peripheral injection, pattern waterflood, and etcetera. Many waterflood schemes are not working properly to boost the oil 
recovery due to unpredicted and unexpected water tide array. Then, the tracer practice started to be used for getting a better picture of the 

transmissibility reservoir as well as the direction of water pathway. This practice honors the parameters, such pressure, water cut, GOR, and rates. 

The streamline modeling is used to map the tracer, and it concludes that the selection of location of the injector should be based on the highest oil 
recovery achieved. Subsequently, the cyclic water injection method is one alternative. Apparently, this approach yields a quantify incremental 

recovery.  This research utilizes the pressure different approach to figure out the route of water in the formation. The inter-well tracer technique in 

this modeling study is a tool to review communication between injectors and producers in the existing pattern. Many scenario should be tried to 
find the best options for the new pattern opportunities. In parallel, a innovative scheme of waterflood technique should be implemented too for 

escalating oil recovery. The stream pathway observes a new potential of the waterflood scheme. It is called "cyclic injection" scheme.  The novelty 

of this approach is the ability to solve the poor sweep efficiency due to improper pathway of water influx in the oil bearing". 
 

Keywords: Tracer Test, Cyclic Water Injection, Water-flood, Streamlines 
 

 

 

1. Introduction  

The possibility of increasing oil productivity in the field is 

to utilize water injection to displace oil to producers. The water 

enters the formation and stimulate the production by increasing 

the amount of oil produced from the field (Asadollahi, 2012). 

Unfortunately, under improper pressure maintaining system as 

well as the higher offtake rate impact the decline  of reservoir 

pressure.  

The water injection is the most popular method to boost oil 

production. Notwithstanding many characteristics of the 

reservoir are favorable, there are also some characteristics of 

the reservoir that are detrimental, such as reservoir 

heterogeneity, especially the value of high permeability, it 

reflects poorly on water injection. The very high permeability 

can disturb the sweeping effect in the waterflood scheme 

(Alhuthali et al., 2007). Waterflood conformance control on 

reservoir heterogeneity is a common challenge in an oil field 

(Thrasher et al., 2016). 

The study’s aim is to review the existing pattern 

performance by utilizing the inter-well tracer test as a tool. 

Then, a streamline simulator is used to analyze the tracer test 

flow path. Afterward, we discover the best scenario for the new 

pattern as well as a new scheme of waterflood to increase oil 

recovery. This study focuses on selecting the best scenario 

based on several parameters, including tracer time 

breakthrough, tracer production concentration, cumulative 

tracer production, and how the tracer flows in the streamlined 

model.  

In the Petroleum Industry, tracer tests are typically used to 

evaluate the communication between the injector and producer 

as well as the reservoir transmisibility. The tracer survey 

provides a variety of information about the heterogeneity of the 

reservoir, such as the fluid flow path and conformance problem. 

The flow path is defined as preferential pathways reservoir fluid 

to move from one point (injection wells) to the other point in 

the reservoir (production wells). This path is geologically 

homogeneous or highly heterogeneous due to layering, thief 

zones, natural fracturing, faulting, or flow-barriers. That means, 

it is necessary to establish flow paths using a fluid carrier 

containing various kinds of tracers (Guan et al., 2005).  

The usefulness of the water injection tracer is to monitor the 

movement of water based on the assumption that the movement 

of the tracer reflects the movement of injected water. How true 

it depends on how closely tracer injection followed by 

formation water without a significant loss and delay. It depends 

how good a tracer chemical composition that is facing reservoir 

property (Zemel, 1995), As a rule of thumb, 40% tracer must be 

produced to ensure the production well-effluent tracer profiles 

reliable analysis (Hao et al., 2011).  

Cyclic Water Injection (CWI) is a periodic water injection 

technique. This technique introduced in 1960 and aims to 

increase production in the field, which has a heterogeneous 

reservoir (Yang et al., 2006). Since then, the cyclic water 

injection has several times applied in some fields in the world, 

in China, the United States, and Russia. Those have shown 

positive results (Shchipanov et al., 2008) 

CWI has a result that is not as good as other EOR methods.  

Because of a less incremental recovery when compared with 

other EOR methods, the CWI is considered an advanced 

waterflood (Rublev et al., 2012). 

CWI as a further development of conventional water 

injection based on two mechanisms (Langdalen, 2014):  

1. Changing the water injection rate. 

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


 
132  Putra, D.F. et al./ JGEET Vol 6 No 3/2021  
 

2. Change the water injection pattern. 

Basically, during cyclic water injection, the injection rate 

introduces alternately between the high rate and the regular rate 

or the low rate and stop the injection condition. The rate of 

water injection is directly proportional to the injection pressure. 

While the injection rate is high, then the pressure reservoir rises 

accordingly. Oppositely, whereas low injection rate into the 

reservoir cause pressure drops significantly. Once cyclic 

injection takes place, there should be a pressure pulse between 

the layers (Shchipanov et al., 2008) 

As for some of the advantages of the application of cyclic 

water injection, including: 

1. Increase oil production (Perez et al., 2014) 
2. Decrease water cut (Perez et al., 2014) 
Almost no cost incurred compared to conventional water 

injection (Shchipanov et al., 2008) Cyclic water injection based 

on two parameters:  

1. Pressurizing (Half-Cycle) 
Water injects in high flow rates, and the hydrocarbons 

produced in the same flow rate. The high flow rate on 

continuous water injection, the reservoir pressure increase 

significantly even may exceed the initial reservoir 

pressure.  The increasing of the pressure on the high-

pressure zone in the high permeability region can push 

water toward the low permeability region that is not swept 

yet by the scheme of continuous water injection. 

2. Depressurizing (Half-Cycle) 
Water injection stops, the reservoir pressure is 

steppingdown, and then the water is sweeping away 

andreplacing hydrocarbons located in the lower 

permeability region. Meanwhile, hydrocarbons that move 

away is heading from the high permeability zones towards 

the production wells. 

2. Methodology 

The streamline simulation is a numerical modeling that uses 

an implicit calculation for solving pressure equation as well as 

an explicit estimation for solving saturation/conservation 

equation (Al-Najem et al., 2012). The software simulator is 

Petrel 2017 Schlumberger; starting with several input data, then 

building 3D grid initially. It utilizes the finite difference 

approximation to derive pressure distribution for generating 

instantaneous velocity vectors perpendicular to the calculated 

pressure contours. The streamlines is traced by the velocity at 

the time of interest under a time varying-velocity (Putra et al., 

2021). 

The reservoir model is named PLC field. It can be 

categorized as a vast reservoir with porosity range within 30% 

to 35%, and the average permeability is 800 mD laterally. The 

current reservoir pressure is 310 bar, and the current 

temperature reservoir is 74oC. The datum point is in 1850 

ftTVD SS, and the Oil Gravity value is within 32-36oAPI and 

GOR value of 100 v/v. In this study, six scenarios are evaluated 

(Table 1) and set by using a ratio of 1: 1 and 1: 2.  

Fig 1 to Fig 4 show the history matching stage conducted 

before the tracer streamline (Putra, 2007) . 

 

Fig 1. History Matching of Oil Production (Putra, 2007) 

 

Fig 2. History Matching of Water Production (Putra, 2007) 



 
Putra, D.F. et al./ JGEET Vol 6 No 3/2021 133 

 

 

 
Fig 3. History Matching of Gas Production (Putra, 2007) 

 

Fig 4. History Matching of Oil Cumulative (Putra, 2007) 

 
Table 1. Base case and six scenarios in the simulation model of cyclic water injection 

Case 
Injection Duration 

(Day) 

Stop Injection Duration 

(day) 
Injection Rate (sm3) 

Base Case Continuous - 5,220 

Scenario #1 1 1 10,440 

Scenario #2 1 2 15,660 

Scenario #3 7 7 10,440 

Scenario #4 7 14 15,660 

Scenario #5 30 30 10,440 

Scenario #6 30 60 15,660 

 

3. Result 

3.1 Injection Wells Screening and Selection  

In the PLC field, there are two existing water injection wells; 

those are A-41BWAT and A-41. Two tracer injection tests 

conducted to screen the appropriate injector for a cyclic 

candidate well.  

a. Tracer test in 41BWAT 

In A-41BWAT, tracer WN1 with 25.000 ppm 

concentrations is injected about 5,220 sm3 on July 1st, 2006, 

and continued until the end of the simulation run.  The total 

tracer produced on production wells A-36 up to 1,816.29 sm3 

or 34.795% of the injected tracer volume, A-40 up to 1,163.85 

sm3 or 22.296% of the tracer injected, and B-39B is 470.59 sm3 

or 9.015% of the injected tracer, the total data of reproduced 

tracer approximately 66.106% on injection applied to A-

41BWAT.  

Fig  shows the flow pattern of A-41BWAT toward 

production wells. If the water injected establishes flow pattern 

as Fig , the water that passes through the flow path towards the 

A-36 well is 0.42 fraction, the water that passes through the 

flow path towards the A-40 well is 0.33 fraction, whereas the 

water passing through a flow path towards B-39B well is 0.25 

fraction. Fig displays the layout of the wells to A-41BWAT as 

well as their distances. 



 
134  Putra, D.F. et al./ JGEET Vol 6 No 3/2021  
 

 

Fig 5. Tracer Production Concentration vs Time (WN1) 

 

Fig 6. The flow pattern of wells A-41BWAT toward production wells 

 
Fig 7. Layout wells and their distances to the injector (A-41BWAT) 

b. Tracer test in A-41 well 

A-41, it has been injected tracer, WN2 with concentration 

25.000 ppm, and volume about 5,220 sm3 on July 1st, 2006 and 

at the end of the simulation run, how much tracer has 

reproduced along with hydrocarbons is used as a benchmark to 

A-41BWAT whether this well is worthy for injector that can 

sweep fluid and raise pressure around the production well. The 

total tracer produced on producer A-36 up to 1,949.89 sm3 or 

37.354% of the tracer injected volume, A-40 is 1,180.546 sm3 

or 22.616% of the tracer injected, and B-39B is 442.242 sm3 or 

8.472% of the tracer injected, then the total volume tracer 

reproduced approximately 68.442% of volume injected.   

Fig 9.  shows the flow pattern of wells A-41 toward the 

production well. The water that passes through the flow path 



 
Putra, D.F. et al./ JGEET Vol 6 No 3/2021 135 

 

towards A-36 is 0.45 fraction; the water flow towards A-40 is 

0.32 fraction, whereas the water towards B-39B is 0.23 fraction. 

displays the layout of the wells to A-41 as well as their 

distances. 

 

 
Fig 8. Tracer Production Concentration vs. Time (WN2) 

 

Fig 9. The flow pattern of wells A-41 toward the production well 

 

Fig 106. Layout wells and their distances to the injector (A-41) 

3.2 Continuous Water Injection  

A benchmark between continuous water injection as a base 

case and water cycle injection as a study case is a comparison 

tool. The base case is continuous flowing injection at the rate of 

5,220 sm3. Fig 11 shows that without water injection at 5,220 

sm3, reservoir pressure drops by 3.806 bar per year. Therefore, 

it is necessary to perform the water injection to maintain 

reservoir pressure.  Fig 12 shows the performance of the 

production and injection since 2004. This scheme earned total 

oil and gas production amounted to 6,477,308 sm3 and 

828,968,960 sm3,  respectively. 



 
136  Putra, D.F. et al./ JGEET Vol 6 No 3/2021  
 

 

Fig 117. Pressure and injection rates base case 

 

 

Fig 128. Oil, gas, and water production rates Field PLC (Continuous Water) 

3.3 Cyclic Water Injection  

It is having selected the candidate injector for the water 

cycle well, which is A-41. The selection parameter is bottom 

hole pressure at the injectors when A-41BWAT or A-41 serves 

as the injector. The bottom hole pressure in A-41BWAT 

exceeds the fracture pressure of the formation. It can impact 

formation damage. Fig 13 shows bottom hole pressure in the 

well A-41BWAT reached 450.99 bar, while the fracture 

pressure of the formation is the PLC field - first segment is 

357.6 bar. It is found in the research conducted by (Bale, 2008). 

Oppositely, the A-41 has a bottom hole pressure of 302.18 bar, 

which is still quite low from the fracture pressure limit. Hence 

A-41 is appropriate and suitable to be the cyclic water injector. 

 

Fig 139. Bottom hole pressure in the well A-41 and A-41BWAT (Cyclic Water Injection) 



 
Putra, D.F. et al./ JGEET Vol 6 No 3/2021 137 

 

 

Fig 1410. Incremental Oil and Gas Production and Watercut Decline compare to base-case 

3.4 The Simulation Result for Each Scenario 

Table 2.  displays the scenario with parameters, such as 
values cumulative oil production, cumulative production of gas, 

water cut average, and peak values of different BHP. The results 

table exhibits scenario #4 has a higher value of oil production 

cumulative and gas production cumulative. Oppositely, 

scenario 4 has a decline water-cut, meanwhile bottom hole 

pressure at 347.729 bar.  It is lower 10 bar than the fracture 

pressure limit.  

Fig 1410.  shows the incremental of oil up to 7.6% and gas 

up to 10.7%; meanwhile, water decline down to 5.45% from 

scenario #4. 

The oil & gas incremental trend of this study is close to the 

result of the field trial at the oil field of East Unity, Sudan, in 

the year 2012. According to research conducted by (Musa and 

Ibrahim, 2012) The East Unity oil field can provide oil gains 

incremental within range 2 to 7%. The incremental of gas 

production is obtained up to 10.68%, while the water-cut drops 

down to 5.4%. Another research has been conducted by (Yang 

et al., 2006) in the Gudao field, and the study obtained the 

water-cut reduction down to 0.2 to 3%. These phenomena show 

that the cyclic water injection scheme can be an opportunity to 

improve water-flood field performance. 

a. The influence of cyclic water injection to the flow rate of 
oil and gas 

The cyclic water injection scheme can alter the flow rate of 

oil and gas as well as the flow path. This phenomenon is 

impacted by pressurizing and depressurizing phase. The 

pressurizing phase pushes the water into the zone that has not 

reached yet by continuous water injection. The depressurizing 

phase has a reverse flow from the low permeability zone 

towards the high permeability zone. It impacts oil mobility from 

the trap sector due to sucking occurrence. Indriecty, it improves 

production withdrawal to the producer.  

Fig 15 show the up and down curves of scenario #4 

compared to the base case in terms of oil and gas production. In 

the pressurizing phase, the production rate goes down because 

the water sweeps a high permeability zone. Meanwhile, in the 

depressurizing phase, oil flow rate goes up because the reverse 

flow from the low permeability zone towards the high 

permeability zone carries residual oil in it. This phenomenon 

has been stated by (Langdalen, 2014) that the increase of oil 

production in cyclic water flooding is provided within the 

depressurizing phase. 
Table 2. Parameters of Oil and Gas cumulative, Water cut and Peak BHP 

No. The model name 
Oil Production Cumulative 

(sm3) 

Gas Production 

Cumulative (sm3) 

Water cut average 

(%) 

Peak BHP 

(Bar) 

1 base Case 6,476,550 828,900,224 0.954 283.896 

2 Scenario #1 6,493,495 830,278,336 0.949 301.997 

3 Scenario #2 6,510,715 831,706,432 0.947 322.526 
4 Scenario #3 6,542,294 836,500,480 0.943 315.692 

5 Scenario #4 6,588,822 843,135,168 0.939 347.729 

6 Scenario #5 6,570,901 846,228,480 0.940 340.375 
7 Scenario #6 6,587,363 859,280,960 0.939 400.018 

 
Fig 1511. The oil flow rate in the base case and scenario #4 



 
138  Putra, D.F. et al./ JGEET Vol 6 No 3/2021  
 

 

 

Fig 1612. The gas flow rate of the base case and scenario #4 

b. The influence of cyclic water injection on the reservoir 
pressure 

In addition to the sweeping effect, the cyclic water injection 

also affects the pressure in the reservoir. The reservoir pressure 

is dynamically up and down in pressurizing and depressurizing 

phases alternately. 

Fig 17 shows the difference pressure trend between the base 

cases versus the cyclic water injection scheme. The base case 

falls steadily, while the pressure cyclic scenario #4 shows the 

up and down pressure trend that displays the pressurizing phase 

with the injection rate is 15.660 sm3 while the depressurizing 

phase at zero sm3.  

Fig 16 exhibits both continuous water injection and cyclic 

water injection can withstand the reservoir pressure. It means 

cyclic water injection can maintain reservoir pressure as good 

as continuous. Another author stated that the injection rate 

differences, such as cyclic water injection, cause pressure 

fluctuations reservoir (Shchipanov et al., 2008) 

 

 
Fig 1713. Pressure reservoir in the base case and scenario #4 

c. The influence of cyclic water injection to oil saturation 

Cyclic water injection affects the sweeping flow path due 

to pressurizing and depressurizing period. Fig 18 and Fig 19 Fig 

15. show significant differences in oil saturation between 

continuous and cyclic water injection.  Some localized parts of 

the reservoir that are not swept yet by the continuous water 

injection can be flashed by cyclic water injection.  Up to 7.64% 

of un-sweep areas can be improved by cyclic water injection. 

(Stirpe et al., 2004) stated that there are differences in localized 

effects of cyclic continuous water injection compare to 

continuous water injection. The difference lies in the zone that 

has low permeability 

 
Fig 14. Oil saturation 1 January 2013 (as seen from the west) 



 
Putra, D.F. et al./ JGEET Vol 6 No 3/2021 139 

 

 

Fig 15. Oil saturation 1 January 2013 (seen from above)

d. Flow-path in scenario #4 

Fig 20 exhibits the dynamic flow path alteration in cyclic 

water injection, on July 24, 2006, while the injection is on, the 

streamline established a flow path through high permeability 

zone and continuous until the injection closed on July 31, 2006. 

Once the injection is shut-in, the flow path changed 

dramatically towards the low permeability zone. The 

streamlined model shows flow path alteration differently until 

August 13, 2006, that has a different flow path. The water 

injection penetrates the low permeability zone during the 

depressurizing phase to sweep the residual oil and gas in that 

zone. 

 

Fig 16. Flow paths in scenario #4 

4. Conclusion 

Based on the simulation study conducted, the conclusions 

derived from this study is the connectivity between both A-

41BWAT and A-41 to the producers is the excellent one. The 

total tracer reproduced at the production wells reach up to 

66.1% in A-41BWAT and 68.44% in A-41 that above the 40% 

requirement for reliable tracer analysis. Another conclusion is 

the cyclic water injection increase oil and gas production up to 

7.64% and 10.68% respectively and decrease water-cut down 

to 5.45%. And finally, the cyclic water injection can sweep the 

oil and gas within inaccessible areas of continuous water 

injection. Approximately up to 7.6 %  un-sweep zone can be 

swept by cyclic water injection 

Acknowledgements 

The authors are grateful to the LPPM of the Islamic 

University of Riau (Kontrak Penelitian No.374/ 

KONTRAK/LPPM-UIR/4-2018) for the financial support as 

well as the Petroleum Engineering Department of UIR for their 

technical support, in this case, it is represented by the Study 

Centre of Energy, Data Science, and Numerical Simulation.  

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