Effect of salinity on oil production: review on low salinity waterflooding mechanisms and exploratory study on pipeline scaling

The past decades have witnessed a rapid development of enhanced oil recovery techniques, among which the effect of salinity has become a very attractive topic due to its significant advantages on environmental protection and economical benefits. Numerous studies have been reported focusing on analys...

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Published inOil & gas science and technology Vol. 75; p. 50
Main Authors Zhang, Tao, Li, Yiteng, Li, Chenguang, Sun, Shuyu
Format Journal Article
LanguageEnglish
Published Paris EDP Sciences 2020
Institut Français du Pétrole (IFP)
Subjects
Design
Economic analysis
Enhanced oil recovery
Environmental protection
Exploitation
Injection
Ion exchange
Literature reviews
Multiphase flow
Oil and gas production
Oil production
Oil recovery
Petroleum
Petroleum industry
Petroleum pipelines
Physics
Pipelines
Salinity
Scale formation
Scaling
Storage
Submarine pipelines
Transport
Water flooding
Water purification
Wettability
Working conditions
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Abstract The past decades have witnessed a rapid development of enhanced oil recovery techniques, among which the effect of salinity has become a very attractive topic due to its significant advantages on environmental protection and economical benefits. Numerous studies have been reported focusing on analysis of the mechanisms behind low salinity waterflooding in order to better design the injected salinity under various working conditions and reservoir properties. However, the effect of injection salinity on pipeline scaling has not been widely studied, but this mechanism is important to gathering, transportation and storage for petroleum industry. In this paper, an exhaustive literature review is conducted to summarize several well-recognized and widely accepted mechanisms, including fine migration, wettability alteration, double layer expansion, and multicomponent ion exchange. These mechanisms can be correlated with each other, and certain combined effects may be defined as other mechanisms. In order to mathematically model and numerically describe the fluid behaviors in injection pipelines considering injection salinity, an exploratory phase-field model is presented to simulate the multiphase flow in injection pipeline where scale formation may take place. The effect of injection salinity is represented by the scaling tendency to describe the possibility of scale formation when the scaling species are attached to the scaled structure. It can be easily referred from the simulation result that flow and scaling conditions are significantly affected if a salinity-dependent scaling tendency is considered. Thus, this mechanism should be taken into account in the design of injection process if a sustainable exploitation technique is applied by using purified production water as injection fluid. Finally, remarks and suggestions are provided based on our extensive review and preliminary investigation, to help inspire the future discussions.
AbstractList The past decades have witnessed a rapid development of enhanced oil recovery techniques, among which the effect of salinity has become a very attractive topic due to its significant advantages on environmental protection and economical benefits. Numerous studies have been reported focusing on analysis of the mechanisms behind low salinity waterflooding in order to better design the injected salinity under various working conditions and reservoir properties. However, the effect of injection salinity on pipeline scaling has not been widely studied, but this mechanism is important to gathering, transportation and storage for petroleum industry. In this paper, an exhaustive literature review is conducted to summarize several well-recognized and widely accepted mechanisms, including fine migration, wettability alteration, double layer expansion, and multicomponent ion exchange. These mechanisms can be correlated with each other, and certain combined effects may be defined as other mechanisms. In order to mathematically model and numerically describe the fluid behaviors in injection pipelines considering injection salinity, an exploratory phase-field model is presented to simulate the multiphase flow in injection pipeline where scale formation may take place. The effect of injection salinity is represented by the scaling tendency to describe the possibility of scale formation when the scaling species are attached to the scaled structure. It can be easily referred from the simulation result that flow and scaling conditions are significantly affected if a salinity-dependent scaling tendency is considered. Thus, this mechanism should be taken into account in the design of injection process if a sustainable exploitation technique is applied by using purified production water as injection fluid. Finally, remarks and suggestions are provided based on our extensive review and preliminary investigation, to help inspire the future discussions.
Author Li, Chenguang
Sun, Shuyu
Li, Yiteng
Zhang, Tao
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  surname: Sun
  fullname: Sun, Shuyu
BackLink https://hal.science/hal-02904294$$DView record in HAL
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Snippet The past decades have witnessed a rapid development of enhanced oil recovery techniques, among which the effect of salinity has become a very attractive topic...
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StartPage 50
SubjectTerms Design
Economic analysis
Enhanced oil recovery
Environmental protection
Exploitation
Injection
Ion exchange
Literature reviews
Multiphase flow
Oil and gas production
Oil production
Oil recovery
Petroleum
Petroleum industry
Petroleum pipelines
Physics
Pipelines
Salinity
Scale formation
Scaling
Storage
Submarine pipelines
Transport
Water flooding
Water purification
Wettability
Working conditions
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Title Effect of salinity on oil production: review on low salinity waterflooding mechanisms and exploratory study on pipeline scaling
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