Design Perspectives for Selection of Subsea Gas Lift Technology for Deep Water Fields

Ligia Tornisiello, S. Taxy, Rick Curto
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Abstract

Riser base gas lift is conventionally used in deep water fields to minimize backpressure on wells, smooth start-up transients, and mitigate slugging in the flowline-riser system which can cause disruption in the topside facilities. The effectiveness of riser base gas lift depends on several factors, such as the reservoir performance, the fluid properties, the field architecture, and the topography. There are several technical solutions available to deliver the lift gas to the riser base. Such technical solutions differ in terms of lift-gas supply method (distributed vs point-to-point), riser specifications, and overall system complexity. The selection of technical solution has the potential for minimizing infrastructure. Available solutions include bundled risers and concentric riser configurations that allow gas lift functions to be integrated with the main production conduit. The evaluation of riser base gas lift effectiveness and the selection of the most appropriate technical solution is typically performed early in the field development cycle. This paper presents a review of the available subsea gas lift technical solutions and discusses an evaluation process, including criteria for the selection of the most appropriate solution. The presented case study assumes a deep water Gulf of Mexico field, in which the main subsea system consists of two wet insulated piggable flowline loops. Key decision drivers were flow assurance requirements, complexity, operability, impact on field layout, interfaces, installation, and schedule are discussed. This holistic approach aids the selection of the most appropriate riser base gas lift system in the early field development cycle.
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深水油田海底气举技术选择的设计展望
立管底部气举通常用于深水油田,以最大限度地减少井的背压,平稳启动,并减轻流-立管系统中的段塞,这可能会导致上层设施的中断。立管底部气举的有效性取决于几个因素,如储层性能、流体性质、油田结构和地形。有几种技术方案可以将举升气体输送到立管基座。这些技术解决方案在举升供气方式(分布式与点对点)、立管规格和整体系统复杂性方面存在差异。技术解决方案的选择有可能使基础设施最小化。现有的解决方案包括捆绑式立管和同心立管配置,可以将气举功能与主生产管道集成在一起。立管底部气举效率的评估和最合适的技术方案的选择通常在油田开发周期的早期进行。本文回顾了现有的海底气举技术解决方案,并讨论了评估过程,包括选择最合适解决方案的标准。本案例假设墨西哥湾的一个深水油田,该油田的主要海底系统由两个湿绝缘可清管流线环路组成。关键决策驱动因素包括流量保证要求、复杂性、可操作性、对现场布局、接口、安装和进度的影响。这种整体方法有助于在油田早期开发周期中选择最合适的立管基座气举系统。
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