A Fully Compositional Streamline Simulator

Crane, Martha; Bratvedt, Frode; Bratvedt, Kyrre; Childs, P R N; Olufsen, Rudi

doi:10.2118/63156-ms

Cited by 58 publications

(32 citation statements)

References 48 publications

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“…The streamline method is similar to an implicit pressure, explicit saturations approach for oil-water or black-oil systems, or an implicit pressure, explicit compositions approach for compositional problems [8,29], with the difference that the transport equations are solved on the specialized transport grid formed by the streamlines. The two distinct time step sizes in this process are the time step between pressure updates (the global time step) and the time step used in the numerical transport solve along streamlines to move saturations or compositions between pressure updates (the local time step).…”

Section: The General Streamline Simulation Processmentioning

confidence: 99%

“…The computational efficiency of streamline methods for many-reservoir settings make them especially suitable for history matching and optimization problems, and commercial streamline simulators are applied for such purposes. Streamline simulation has recently been extended to handle (near-) miscible gas injection processes [8,29], as well as flow in fractured reservoirs [11].…”

Section: Introductionmentioning

confidence: 99%

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Parallel implementations of streamline simulators

2008

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We discuss various strategies for parallelizing streamline simulators and present a single-phase shared memory implementation. The choice of a shared memory programming model is motivated by its suitability for streamline simulation, as well as the rapid advance of multicore processors, which are readily available at low-cost. We show that streamline-based methods are easily parallelizable on shared memory architectures through their decomposition of the multidimensional transport equations into a large set of independent 1D transport solves. We tested both a specialized explicit load balancing algorithm that optimizes the streamline load distribution across threads to minimize the time that any of the threads are idle, and the dynamic load balancing algorithms provided by OpenMP on the shared memory machines. Our results clearly indicate that built-in schedulers are competitive with specialized load balancing strategies as long as the number of streamlines per thread is sufficiently high, which is the case in field applications. The average workload per thread is nominally insensitive to workload variations between individual streamlines, and any load balancing advantage offered by explicit strategies is not sufficient to overcome associated computational and parallel overhead. In terms of the allocation of streamlines or streamline segments to threads, we investigated both the distributed approach, in which threads are assigned streamline segments, and the owner approach, in which threads own complete streamlines. We found that the owner approach is most suitable. The slight advantage that the distributed approach has in terms of load balancing is not enough to compensate for the additional overheads. Moreover, the owner approach allows straightforward re-use of existing sequential codes, which is not the case for the distributed approach in case of implicit or adaptive implicit solution strategies. The tracing and mapping stages in streamline simulation have low parallel efficiency. However, in real-field models, the computational burden of the streamline solves is significantly heavier than that of the tracing and mapping stages, and therefore, the impact of these stages is limited. We tested the parallelization on three shared memory systems: a 24 dualcore processor Sun SPARC server; an eight-way Sun Opteron server, representative of the state-of-the-art shared memory systems in use in the industry; and the very recently released Sun Niagara II multicore machine that has eight floating point compute units on the chip. We test a single-phase flow problem on three heterogeneous reservoirs with varying well placements (this system gives the worst case scenario as the tracing and mapping costs are not negligible compared to the transport costs). For the SPARC and Opteron system, we find parallel efficiencies ranging between 60 and 75 for the tracer flow problems. The sublinear speedup is mostly due to communication overheads in the tracing and mapping stages. In applications with more complex physics, the relati...

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Section: The General Streamline Simulation Processmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Parallel implementations of streamline simulators

2008

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“…Second, the improved mappings discussed in the previous section reduce smoothing and mass balance errors so that more frequent pressure updates are acceptable if needed. Ingebrigtsen et al (1999) and Crane et al (2000) suggested updating the pressure along streamlines during a global time step to better honor the strong coupling between the pressure and transport equations. For gas injection problems, a similar approach may help to account for volume change at gas fronts.…”

Section: An Adaptive Streamline Frameworkmentioning

confidence: 99%

Industrial Compositional Streamline Simulation for Efficient and Accurate Prediction of Gas Injection and WAG Processes

Gerritsen¹

2008

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Executive SummaryGas-injection processes are widely and increasingly used for enhanced oil recovery (EOR). In the United States, for example, EOR production by gas injection accounts for approximately 45% of total EOR production and has tripled since 1986. The understanding of the multiphase, multicomponent flow taking place in any displacement process is essential for successful design of gas-injection projects. Due to complex reservoir geometry, reservoir fluid properties and phase behavior, the design of accurate and efficient numerical simulations for the multiphase, multicomponent flow governing these processes is nontrivial. In this work, we developed, implemented and tested a streamline based solver for gas injection processes that is computationally very attractive: as compared to traditional Eulerian solvers in use by industry it computes solutions with a computational speed orders of magnitude higher and a comparable accuracy provided that cross-flow effects do not dominate. We contributed to the development of compositional streamline solvers in three significant ways: improvement of the overall framework allowing improved streamline coverage and partial streamline tracing, amongst others; parallelization of the streamline code, which significantly improves wall clock time; and development of new compositional solvers that can be implemented along streamlines as well as in existing Eulerian codes used by industry.We designed several novel ideas in the streamline framework. First, we developed an adaptive streamline coverage algorithm. Adding streamlines locally can reduce computational costs by concentrating computational efforts where needed, and reduce mapping errors. Adapting streamline coverage effectively controls mass balance errors that mostly result from the mapping from streamlines to pressure grid. We also introduced the concept of partial streamlines: streamlines that do not necessarily start and/or end at wells. This allows more efficient coverage and avoids the redundant work generally done in the near-well regions. We improved the accuracy of the streamline simulator with a higher order mapping from pressure grid to streamlines that significantly reduces smoothing errors, and a Kriging algorithm is used to map from the streamlines to the background grid. The higher accuracy of the Kriging mapping means that it is not essential for grid blocks to be crossed by one or more streamlines. The higher accuracy comes at the price of increased computational costs, but allows coarser coverage and so does not generally increase the overall costs of the computations. To reduce errors associated with fixing the pressure field between pressure updates, we developed a higher order global time-stepping method that allows the use of larger global time steps. Third-order ENO schemes are suggested to propagate components along streamlines. Both in the two-phase and three-phase experiments these ENO schemes outperform other (higher order) upwind schemes. Application of the third order ENO scheme leads to ii...

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“…Gas displacement processes are one of the critical areas in SL simulation, as the compressibility remains a significant issue. Crane et al [26] used 1D fully implicit solutions of FD simulation to solve for pressure and fluid compositions together along each streamline, and account for the changes of the phase behavior that depend on the changes in pressure. It was tested and compared against FD compositional simulator using the SPE 9 Model.…”

Section: Introductionmentioning

confidence: 99%

Application of Streamline Simulation for Gas Displacement Processes

Nagib

2014

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Performance evaluation of miscible and near-miscible gas injection processes is available through conventional finite difference (FD) compositional simulation. Streamline methods have also been developed in which fluid is transported along the streamlines instead of using the finite difference grid. In streamline-based simulation, a 3D flow problem is decoupled into a set of 1D problems solved along streamlines. This reduces simulation time relative to FD simulation, and suppresses the numerical dispersion errors that are present in FD simulations. Larger time steps and higher spatial resolution can be achieved in these simulations. Thus, streamline-based reservoir simulation can be orders of magnitude faster than the conventional finite difference methods. Streamline methods are traditionally only applied to incompressible flow processes. In this paper, the method is adopted and assessed for application to compressible flow processes. A detailed comparison is given between the results of conventional FD simulation and the streamline approach for gas displacement processes. Finally, some guidelines are given on how the streamline method can potentially be used to good effect for gas displacement processes.

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A Fully Compositional Streamline Simulator

Cited by 58 publications

References 48 publications

Parallel implementations of streamline simulators

Parallel implementations of streamline simulators

Industrial Compositional Streamline Simulation for Efficient and Accurate Prediction of Gas Injection and WAG Processes

Application of Streamline Simulation for Gas Displacement Processes

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