Abstract
According to the roadmap toward clean energy, natural gas has been pronounced as the perfect transition fuel. Unlike usual dry gas reservoirs, gas condensates yield liquid which remains trapped in reservoir pores due to high capillarity, leading to the loss of an economically valuable product. To compensate, the gas produced on the surface is stripped from its heavy components and reinjected back to the reservoir as dry gas thus causing revaporization of the trapped condensate. To optimize this gas recycling process compositional reservoir simulation is utilized, which, however, takes very long to complete due to the complexity of the governing differential equations implicated. The calculations determining the prevailing k-values at every grid block and at each time step account for a great part of total CPU time. In this work machine learning (ML) is employed to accelerate thermodynamic calculations by providing the prevailing k-values in a tiny fraction of the time required by conventional methods. Regression tools such as artificial neural networks (ANNs) are trained against k-values that have been obtained beforehand by running sample simulations on small domains. Subsequently, the trained regression tools are embedded in the simulators acting thus as proxy models. The prediction error achieved is shown to be negligible for the needs of a real-world gas condensate reservoir simulation. The CPU time gain is at least one order of magnitude, thus rendering the proposed approach as yet another successful step toward the implementation of ML in the clean energy field.
Highlights
Despite the surprisingly fast development of renewable energy sources to fully replace traditional fossil fuels, as of today renewables account for a significant but still limited percentage of global energy demands [1]
We propose the use of machine learning (ML) to build regression tools directly providing the prevailing k-values, achieving the solution of the flash problem at a fraction of the time needed by conventional iterative methods, and greatly accelerating the simulation process
To cross-check the trained models performance, each one of the sample simulation models was forced to reproduce the datasets used by the other models which were alien to it
Summary
Despite the surprisingly fast development of renewable energy sources to fully replace traditional fossil fuels, as of today renewables account for a significant but still limited percentage of global energy demands [1]. CO2 emissions by at least half and can be transported and stored as liquefied natural gas (LNG) or compressed natural gas (CNG). It can successfully deal with both seasonal and short-term demand fluctuations [3]. When gas condenses to liquid in the reservoir pores, it stays trapped there due to surface tension forces. The richer and more valuable hydrocarbon components are trapped, and liquid accumulation blocks the gas flow and weakens the well’s productivity [8,9] by forming condensate banks [10–13]. More than 50% of well productivity was lost in the Arun field in Indonesia [14–18] due to condensate banking
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