Integrated Modelling Workflow for Life Cycle Development of a Large Scale Coal Seam Gas Field

Vikram Sharma, J. Davies, Benjamin Vella, Jesscia Jiang, I. Sugiarto, S. Mazumder
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引用次数: 1

Abstract

Development of coal seam gas fields is conceptually simple but complexity arises with: the stochastic nature of coal reservoirscontinually changing work scopethe large number of wells required to meet gas contracts. In the current environment, the cost of developing thousands of wells and hundreds of kilometres of associated gathering is a key driver to the success or failure of CSG projects. Continuous reduction in cost/funding with limited resources drives companies to derive an integrated approach to the field development. Subsurface models now form an integral part of production forecasting and decision making. Companies have benefited from the computation technological advances in the recent past, whereby it is possible to run large-scale models in a reasonable timeframe. Several tools and approaches are available today to integrate complex 3D reservoir models with surface networks to generate an integrated production forecast. In this paper we focus on using advanced geospatial applications with integrated system models to derive a development concept which is optimal, realistic and capable of adapting to changes in work scope as the development progresses. Gathering routes and associated material take off (MTO) points are generated in geographic information system (GIS) tools, using constraints and criteria such as: access and approvalssub-surface data (scope of recovery maps, net coal and permeability)maximum use of existing infrastructure (Roads, Tracks, etc.)environmental constraints (overland flow, vegetation, etc.)well spacing. Seamless integration of GIS tools and sub-surface modeling tools is what makes this workflow unique. GIS tools acts as a key integrator, forcing different disciplines and departments to work together in a common platform. It also functions as a common database used across an entire organisation. GIS toolbox gives a significant head-start to the project by first defining what is achievable. It is then finessed with the best value sub-surface outcome and a final forecast is derived in a significantly shorter time scale. With the approach presented in this paper, the forecasting cycle, involving full economic run, is substantially reduced– from several months to just weeks, if not days. The final outcome is an achievable well sequence which is derived along a realistic gathering route. With this, the MTO and the production forecasts are aligned and the associated costs can be easily traced to source. This workflow is automated and can be easily repeated if scope or project premise changes. Last but not least, this approach can be applied to any onshore unconventional or conventional plays.
大型煤层气田生命周期开发集成建模工作流
煤层气田的开发在概念上是简单的,但随着煤储层的随机性、工作范围的不断变化以及满足天然气合同所需的大量井的数量增加,其复杂性也随之产生。在目前的环境下,开发数千口井和数百公里的相关收集的成本是CSG项目成败的关键驱动因素。在有限的资源下,不断降低成本和资金,促使公司开发出一种综合的油田开发方法。目前,地下模型已成为生产预测和决策的重要组成部分。公司已经从最近的计算技术进步中受益,因此有可能在合理的时间范围内运行大规模模型。目前,有几种工具和方法可以将复杂的3D油藏模型与地面网络相结合,从而生成综合的产量预测。本文着重利用先进的地理空间应用和集成系统模型,推导出一种最优的、现实的、能够适应开发工作范围变化的开发理念。在地理信息系统(GIS)工具中生成收集路线和相关材料起降点(MTO),使用约束条件和标准,例如:访问和批准地下数据(恢复地图范围、净煤和渗透率)现有基础设施(道路、轨道等)的最大利用环境约束条件(地上流、植被等)井间距。GIS工具和地下建模工具的无缝集成使该工作流独一无二。GIS工具作为一个关键的集成商,迫使不同的学科和部门在一个共同的平台上协同工作。它还可以作为跨整个组织使用的公共数据库。GIS工具箱通过首先定义可实现的内容,为项目提供了一个重要的开端。然后利用最佳地下结果值对其进行处理,并在明显较短的时间尺度内得出最终预测结果。采用本文提出的方法,包括经济全面运行在内的预测周期大大缩短——从几个月缩短到几周,甚至几天。最终的结果是一个可实现的井序列,它是沿着一个现实的聚集路线推导出来的。这样,MTO和产量预测就能保持一致,相关成本可以很容易地追溯到源头。这个工作流程是自动化的,如果范围或项目前提发生变化,可以很容易地重复。最后但并非最不重要的是,这种方法可以应用于任何陆上非常规或常规油气藏。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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