Dynamic Two-Phase Flow Simulator: A Powerful Tool for Blowout and Relief Well Kill Analysis

Rygg, O.B.; Smestad, Pal; Wright, Jamie

doi:10.2118/24578-ms

Cited by 6 publications

(3 citation statements)

References 2 publications

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“…(iv) the flow rate of hydrocarbons for each scenario is analyzed by way of transient fluid dynamic simulators (e.g., OLGA 5.3 in Rygg et al 1992; BlowFlow in Karlsen and Ford 2014) as a function of physical and geometrical properties of the reservoir and the well;…”

Section: Introductionmentioning

confidence: 99%

Probabilistic analysis of risk and mitigation of deepwater well blowouts and oil spills

Caia

Lullo

Ghetto

et al. 2018

Stoch Environ Res Risk Assess

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Section: Introductionmentioning

confidence: 99%

Probabilistic analysis of risk and mitigation of deepwater well blowouts and oil spills

Caia

Lullo

Ghetto

et al. 2018

Stoch Environ Res Risk Assess

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“…Apparently, there exists minimal work on the consequence analysis of a blowout. Current literature addresses well killing decision trees, relief well drilling, and spill response . Worth et al .…”

Section: Introductionmentioning

confidence: 99%

Dynamic Blowout Risk Analysis Using Loss Functions

Abimbola

Khan

2017

Risk Analysis

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Most risk analysis approaches are static; failing to capture evolving conditions. Blowout, the most feared accident during a drilling operation, is a complex and dynamic event. The traditional risk analysis methods are useful in the early design stage of drilling operation while falling short during evolving operational decision making. A new dynamic risk analysis approach is presented to capture evolving situations through dynamic probability and consequence models. The dynamic consequence models, the focus of this study, are developed in terms of loss functions. These models are subsequently integrated with the probability to estimate operational risk, providing a real-time risk analysis. The real-time evolving situation is considered dependent on the changing bottom-hole pressure as drilling progresses. The application of the methodology and models are demonstrated with a case study of an offshore drilling operation evolving to a blowout.

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“…Details of successful dynamic killing operations over the years have been reported by various authors 2,3,6,12,13 . In addition, advances in dynamic kill calculation models have been introduced 4,5,8,10,11,15 . Dynamic killing is constituted by a complex multi-phase fluid dynamic system in a complex geometry: blowout well, relief well and reservoir.…”

Section: Introductionmentioning

confidence: 99%

Software Simulation and System Design of Dynamic Killing Technique

Blotto

Tambini

Dellarole³

et al. 2004

Proceedings of SPE Annual Technical Conference and Exhibition

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TX 75083-3836, U.S.A., fax 01-972-952-9435. AbstractUncontrolled eruption of a well is one of the most critical accidents that can occur in the exploration and exploitation of hydrocarbon fields. Several well control methods have been developed to bring blowout wells under control as quickly as possible. The dynamic killing technique is typically adopted when a relief well needs to control the event. The method calls for bringing the blowout well under control by pumping water (or brine) at a flowrate sufficient to exceed the formation pressure of the blowing well. This phenomenon occurs through a combination of kill fluid static head and frictional pressure losses of kill fluid in the blowout well. Dynamic killing is constituted by a complex multi-phase fluid dynamic system with a complex geometry: blowing well, relief well and reservoir. An advanced model able to simulate the killing phenomenon during all its transients is necessary for applicability screening and system design. A software has been developed under an HSE R&D project and implemented by an integrated work team made up of the safety, production, drilling and reservoir engineering departments of oil and service companies. The dynamic killing software, by simulating the killing transient with a series of loops through submodels, correlates killing flowrate, breakthrough and killing time, relief bottom hole pressure and required killing pump head and power as outputs. This model is able to simulate the dynamic killing of an atmospheric or underwater blowout event. It is also able to analyze the in-string killing disabling the reservoir submodel. This paper fully describes the dynamic killing model in terms of both subroutines (blowing well, relief well and reservoir models) and software applications (method applicability, system design, main killing parameters). In addition, the results of software validation simulating dynamic killing cases in the field are reported. This analysis indicates good accuracy of the model in terms of transient duration and killing requirements.

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Dynamic Two-Phase Flow Simulator: A Powerful Tool for Blowout and Relief Well Kill Analysis

Cited by 6 publications

References 2 publications

Probabilistic analysis of risk and mitigation of deepwater well blowouts and oil spills

Probabilistic analysis of risk and mitigation of deepwater well blowouts and oil spills

Dynamic Blowout Risk Analysis Using Loss Functions

Software Simulation and System Design of Dynamic Killing Technique

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