Abstract
Oil and gas field development optimization, which involves the determination of the optimal number of wells, their drilling sequence and locations while satisfying operational and economic constraints, represents a challenging computational problem. In this work, we present a deep-reinforcement-learning-based artificial intelligence agent that could provide optimized development plans given a basic description of the reservoir and rock/fluid properties with minimal computational cost. This artificial intelligence agent, comprising of a convolutional neural network, provides a mapping from a given state of the reservoir model, constraints, and economic condition to the optimal decision (drill/do not drill and well location) to be taken in the next stage of the defined sequential field development planning process. The state of the reservoir model is defined using parameters that appear in the governing equations of the two-phase flow (such as well index, transmissibility, fluid mobility, and accumulation, etc.,). A feedback loop training process referred to as deep reinforcement learning is used to train an artificial intelligence agent with such a capability. The training entails millions of flow simulations with varying reservoir model descriptions (structural, rock and fluid properties), operational constraints (maximum liquid production, drilling duration, and water-cut limit), and economic conditions. The parameters that define the reservoir model, operational constraints, and economic conditions are randomly sampled from a defined range of applicability. Several algorithmic treatments are introduced to enhance the training of the artificial intelligence agent. After appropriate training, the artificial intelligence agent provides an optimized field development plan instantly for new scenarios within the defined range of applicability. This approach has advantages over traditional optimization algorithms (e.g., particle swarm optimization, genetic algorithm) that are generally used to find a solution for a specific field development scenario and typically not generalizable to different scenarios. The performance of the artificial intelligence agents for two- and three-dimensional subsurface flow are compared to well-pattern agents. Optimization results using the new procedure are shown to significantly outperform those from the well pattern agents.
Highlights
Field development decisions such as the number of wells to drill, their location and drilling sequence need to be made optimally to maximize the value realized from a petroleum asset
The number of drilling stages for each specific field development scenario depends on the total production period and drilling duration sampled from Table 1
We developed an AI agent for constrained field development optimization for two- and three-dimensional subsurface two-phase flow models
Summary
Field development decisions such as the number of wells to drill, their location and drilling sequence need to be made optimally to maximize the value realized from a petroleum asset. Optimization algorithms such as evolutionary strategies are, in recent times, widely applied to the field development optimization problem [1,2]. The large number of computationally expensive flow simulations needs to be run for each field under consideration This suggests the field development optimization problem will benefit from strategies that would allow for the generalization of the optimization process to several petroleum fields
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