Re-development of the Frøy Field: Selection of the Injection Water

Østvold, Terje; Mackay, Eric James; McCartney, Ross; Davis, Ian; Aune, Egil

doi:10.2118/130567-ms

Cited by 5 publications

(1 citation statement)

References 6 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…One-Dimensional Reactive-Transport Model A 1D reactive-transport model (Parkhurst and Appelo 1999), as a hydrogeochemical simulator, is usually used for simulating a variety of reactions and processes in natural water or in batch and column laboratory experiments. However, recently, this 1D reactivetransport model has been applied to investigate the effect of scale formation on the produced-water composition during the mixing and movement of IW and FW from injector to producer (Fu et al 2012;Vazquez et al 2013).…”

Section: Behavior Of Ions In Produced Brinementioning

confidence: 99%

Predicted and Observed Evolution of Produced-Brine Compositions and Implications for Scale Management

Hu¹,

Mackay²,

Ishkov³

et al. 2016

SPE Production &Amp; Operations

View full text Add to dashboard Cite

Produced water was sampled and measured repeatedly during production from an offshore field, and an extensive brine-chemistry data set was developed. Systematic analysis of this data set enables an in-depth study of brine/brine and brine/rock interactions occurring in the reservoir, with the objective of improving the prediction and management of scale formation, along with improving its prevention and remediation.A study of the individual-ion trends in the produced brine by use of the plot types developed for the reacting-ions toolkit (Ishkov et al. 2009) provides insights into the components that are involved in in-situ geochemical reactions as the brines are displaced through the reservoir, and how the precipitation and dissolution of minerals and the ion-exchange reactions occurring within the reservoir can be identified. This information is then used to better evaluate the scale risk at the production wells.A thermodynamic prediction model is used to calculate the risk of scale precipitation in a series of individual produced-water samples, thus providing an evaluation of the actual scaling risk in these samples, rather than the usual theoretical estimate, on the basis of the endpoint formation-and injection-brine compositions and the erroneous assumption that no reactions in the reservoir impact the produced-water composition. Nonetheless, the usual effects of temperature, pressure, and brine composition are accounted for in these calculations by use of classical thermodynamics. The comparison of theoretical and actual results indicates that geochemical reactions taking place in this given reservoir lead to ion depletion, which greatly reduces the severity and potential for scale formation. However, ion-exchange reactions are also observed, and these too affect the scale risk and the effectiveness of scale inhibitors in preventing deposition.Additionally, comprehensive analysis by use of a geochemical model is conducted to predict the evolution of the produced-brine compositions at the production wells and to test the assumptions about which in-situ reactions are occurring. A good match between the predictions from this geochemical model and the observed produced-brine compositions is obtained, suggesting that the key reactions included in the geochemical model are representative of actual field behavior. This helps to establish confidence that the model can be used as a predictive tool in this field.

show abstract

Section: Behavior Of Ions In Produced Brinementioning

confidence: 99%

Predicted and Observed Evolution of Produced-Brine Compositions and Implications for Scale Management

Hu¹,

Mackay²,

Ishkov³

et al. 2016

SPE Production &Amp; Operations

View full text Add to dashboard Cite

show abstract

Scale Management

Vazquez

2023

Modelling Oilfield Scale Squeeze Treatments

View full text Add to dashboard Cite

Application of Multirate Tests to Scale Management: Part 1—Interpretation of Produced-Water Analyses

McCartney¹,

Tjomsland

Sandoy

et al. 2011

SPE Production &Amp; Operations

View full text Add to dashboard Cite

Summary Several multirate separator tests (MRTs) have been undertaken on wells in the Veslefrikk field that are on commingled production from the Brent Group and Intra Dunlin Sand. During these tests, produced-water samples were also collected. Integrated analysis of the results of interpretion of the produced-water analyses and the MRT results have provided a range of information for each production zone including the nature and composition of the produced water, seawater fraction of these produced waters, fraction of total water flow being produced, pressure, productivity index, oil and water rates, and water cut. This information can reduce the need for deploying production-logging tools (PLTs), allows the scaling potential between the deeper and the shallower zones to be evaluated, aids squeeze-treatment design, is beneficial for predicting formation damage from crossflow, and aids water-shutoff decisions. In this paper, the methods of interpreting the produced-water analyses are presented through the use of a field example. To aid interpretation, interpretation of other produced-water analyses from the field and reactive-transport modeling have been undertaken to better understand reactions occurring in the reservoir as a result of seawater injection and the effects of these reactions on produced-water compositions. In an accompanying paper (Tjomsland et al. 2011), the integrated MRT-analysis techniques are described and the results and applications of additional field examples are presented.

show abstract

Re-development of the Frøy Field: Selection of the Injection Water

Cited by 5 publications

References 6 publications

Predicted and Observed Evolution of Produced-Brine Compositions and Implications for Scale Management

Predicted and Observed Evolution of Produced-Brine Compositions and Implications for Scale Management

Scale Management

Application of Multirate Tests to Scale Management: Part 1—Interpretation of Produced-Water Analyses

Contact Info

Product

Resources

About