An Efficient Model for Evaluating Gas Field Gathering System Design

Dempsey, John R.; Patterson, J.K.; Coats, K.H.; Brill, J.P.

doi:10.2118/3161-pa

Cited by 33 publications

(21 citation statements)

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“…Dempsey et al (1971) first presented a technique that iteratively solved reservoir, tubing-string, and gathering system models to accurately evaluate gasfield deliverability. The concept was extended to the black-oil system by Startzman et al (1977), and the scheme was modified by Emanuel and Ranney (1981) to operate efficiently when dealing with multiphase flow in large-scale problems. Hepguler et al (1997) and Tingas et al (1998) implemented similar schemes to couple existing commercial reservoir and network simulators.…”

Section: Introductionmentioning

confidence: 99%

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A Semi-Implicit Approach for Integrated Reservoir and Surface-Network Simulation

Liang¹,

Rubin²

2014

SPE Reservoir Evaluation &Amp; Engineering

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Conventionally, methods of coupling reservoirs and surface networks are categorized into implicit and explicit approaches. The term "implicit coupling" indicates that the two simulators solve unknowns together, simultaneously, or iteratively, whereas "explicit coupling" indicates that the two simulators solve unknowns sequentially and exchange their boundary conditions at the last coupled time t n .The explicit approach is straightforward to implement in existing reservoir and surface-network models and is widely used. Explicit coupling does have drawbacks, however, because well rate and pressure oscillations are often observed.In this paper, a new semi-implicit method for coupled simulation is presented. This technique stabilizes and improves the accuracy of the coupled model. The "semi-implicit coupling" overcomes the problems found in explicit-coupling methods without requiring the complexity of a fully implicit coupled model.The new approach predicts inflow-performance-relationship (IPR) curves at the next coupled time t nþ1 by simultaneously conducting well tests for all wells in the reservoir before actually taking the required timestep. All wells first flow simultaneously to the next coupled time t nþ1 with the well rates unchanged from the last coupled timestep. The timestep is rewound, and all well rates are reduced by a uniform fraction and then simultaneously flow again to t nþ1 . By extrapolating the resulting well pressures, the well's shut-in pressures at time t nþ1 are determined, and thus, straight-line IPRs are produced. The new IPR curves approximate better each well's drainage region at t nþ1 and each well's shut-in pressure at t nþ1 which helps to stabilize the explicitly coupled model.The new coupling technique normally does not require iteration between the reservoir and surface network and normally has the stability and accuracy characteristics of an implicitly coupled approach. Because the well tests already account for individual well-drainage regions, an explicit knowledge of the well-drainage region is not required. Because of the stabilized IPR, the approach also was found to reduce the overall computational time compared with explicit coupling.Applications of the new approach are presented that show significant improvements surpassing explicit coupling in both stability and accuracy. IntroductionIt has been widely recognized that when reservoir-deliverability forecasting and surface-network planning are required, integrated reservoir and surface-network simulation can provide more-realistic results than separate models of the reservoir and surface network. During the last 40 years, different methods to couple reservoir and network models were developed and studied by a number of investigators. Dempsey et al. (1971) first presented a technique that iteratively solved reservoir, tubing-string, and gathering system models to accurately evaluate gasfield deliverability. The concept was extended to the black-oil system by Startzman et al. (1977), and the scheme was modified by Emanuel and ...

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Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

A Semi-Implicit Approach for Integrated Reservoir and Surface-Network Simulation

Liang¹,

Rubin²

2014

SPE Reservoir Evaluation &Amp; Engineering

View full text Add to dashboard Cite

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“…Dempsey et al (1971) presented the concept of a simulation model combining both reservoir and surface-facility calculations applied to a gas/water system. A combined reservoir and surface-facility simulator applicable to large offshore oil reservoirs producing through a gathering-system network was presented by Startzman et al (1977) and refined by Emanuel and Ranney (1981).…”

Section: Introductionmentioning

confidence: 99%

Near-Well-Subdomain Simulations for Accurate Inflow-Performance-Relationship Calculation To Improve Stability of Reservoir/Network Coupling

Güyagüler

Zapata

Cao

et al. 2011

SPE Reservoir Evaluation &Amp; Engineering

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Externally coupled workflows that rely on exchanging inflowperformance relationships (IPRs) at the coupling points, such as those between reservoir and surface-network simulators, may exhibit oscillations because of the IPR calculated at the beginning of a timestep not being representative of the IPR at the end of the timestep. One solution is to have an implicitly coupled reservoir/surface system. This is often impractical because the reservoir and the surface network may be modeled using different applications, or the resulting coupled system may become too large and too complex to solve implicitly because of processing time and convergence issues. We propose the calculation of multipoint IPRs obtained by solving near-well subdomains for the subsequent timestep. A flexible reservoir-simulation architecture enables the dynamic creation and simulation of near-well subdomains at run time. Subdomains are created automatically within the vicinity of the well or may be defined dynamically from the pressure gradient. These near-well-subdomain simulations are embedded within the full-field simulation and extract all the required model properties (pressure/volume/temperature, rock) from the full-field model. The most recent fluxes from the global solution are used as boundary conditions for the near-well subdomains. In this paper, the subdomain IPRs are used within reservoir/network coupling workflows for which traditionally calculated IPRs result in oscillations and high errors. Sensitivity analysis is carried out on the extent of the subdomains and the size of the coupling timestep. A real field case is used to show that subdomain IPRs result in smooth pressure/ rate profiles as opposed to the oscillatory profiles obtained from explicitly calculated IPRs and that they also help reduce balancing errors between reservoir and surface models.

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“…It also provides a tool to set short-or medium-term targets for parameters, such as average reservoir pressure and injection schedules. Because of these reasons, many studies [1][2][3][4][5][6][7][8][9] have been performed where the reservoir was coupled with surface facilities.…”

Section: Introductionmentioning

confidence: 99%

“…Dempsey et al 1 , used an iterative scheme to couple solutions in the piping network and the reservoir. They solved a tightly coupled system where iterations were done over all solution processes within every time step during the simulation.…”

Section: Introductionmentioning

confidence: 99%

Coupled Facility and Reservoir Simulations to Optimize Strategies for a Mature Field

2011

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It is important to employ a good production injection strategy to optimize hydrocarbon recovery from a field. Reservoir constraints on the surface facility change as the field matures. It may be economical to revise the surface facility configurations rather than retaining the initial design of the surface facility to maintain the target production level of the field as reservoir conditions change. If reservoir pressure is not sufficient to maintain natural flow, there may be need for artificial lift mechanisms to keep the well flowing. Careful analysis of interdependence of the surface facility constraints and reservoir conditions are important in designing good quality production injection strategies for these circumstances. Coupled facility and reservoir simulations allow production optimization and determination of the impact of injection or disposal policies on reservoir management. Sometimes there are oscillations in computed production rates, which may be as a result from inaccurate treatment of a coupling algorithm, well management rules, optimization techniques, etc. Excessive fluctuations make the solution impractical to implement. In this paper, we examine the cause of well rate fluctuations in coupled simulations. We were able to keep oscillation levels at a very low level in our simulations by using a small coupling interval and by revising well management rules. We made case studies with reconfiguration of surface facility designs in two large fields to examine if those designs were capable of meeting the required production targets as the reservoir conditions change with time. Surface facility models were built using a commercially available software, which were coupled to Saudi Aramco's in-house reservoir simulator, POWERS. We examine scenarios where some facilities could be eliminated to reduce cost while maintaining required production target. We study the impact of reconfiguring the surface network and examine how surface constraints might change the overall production rate.

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An Efficient Model for Evaluating Gas Field Gathering System Design

Cited by 33 publications

References 0 publications

A Semi-Implicit Approach for Integrated Reservoir and Surface-Network Simulation

A Semi-Implicit Approach for Integrated Reservoir and Surface-Network Simulation

Near-Well-Subdomain Simulations for Accurate Inflow-Performance-Relationship Calculation To Improve Stability of Reservoir/Network Coupling

Coupled Facility and Reservoir Simulations to Optimize Strategies for a Mature Field

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