Sealing Advancements for Rotating Control Devices

Aaron Richie, Lannie Laroy Dietle
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Abstract

Some of the most critical elements of a rotating control device (RCD) are the rotary seals that prevent a pressurized abrasive drilling fluid from destroying the rolling element bearings. The rotary seals prevent the drilling fluid from damaging the bearings by sealing the annular gap between the rotating mandrel and the stationary bearing housing. The combination of pressure causing seal material to bulge into the annular gap and the relative runout between the mandrel and housing can cause extrusion damage of the seal. The relative rotation and runout between the seal and mandrel in an abrasive environment leads to abrasive wear of the seal. Finally, the relatively high surface speed and contact pressure between the seal and mandrel leads to adhesive wear of the seal. When the drilling fluid pressure below the RCD is low there are several suitable rotary seal designs that can provide acceptable RCD life at most rotary drilling speeds. To meet higher speed and pressure conditions for the 100 hour minimum duration, established in API 16RCD, many RCD designs employ a sealing approach that splits the sealing tasks across two seals. One seal excludes the abrasive drilling fluid at low differential pressure and another seal, capable of operating at high differential pressure, retains a clean lubricant that is at nearly the same pressure as the drilling fluid. This sealing system generally requires an external lubricant pressurization system to provide the necessary fluid and pressure environment for the seals. Some drilling sites that operate at these conditions cannot accommodate these large, complex, expensive lubricant systems due to space or access constraints, or economic considerations. This paper describes an innovative sealing system that enables an RCD to operate at 1,500 psi and 100 RPM for 200 hours without requiring an external lubricant pressurization system. This claim is based on extensive laboratory testing of three new technologies included in this sealing system. Key results and summaries from the test program are included in this paper. The three key technologies are: A hydrodynamic spring-loaded lip seal that can be used to exclude abrasive drilling fluid at low-differential pressure or retain a clean lubricant at high differential pressure. A direct-compression hydrodynamic seal that can retain a clean lubricant at high differential pressure. A self-actuating miniature valve that replaces the lubricant supply function of an external lubricant pressurization system.
旋转控制装置的密封进展
旋转控制装置(RCD)的一些最关键的元件是旋转密封,它可以防止加压研磨性钻井液破坏滚动元件轴承。旋转密封通过密封旋转心轴和固定轴承外壳之间的环形间隙来防止钻井液损坏轴承。压力导致密封材料向环空间隙内膨胀,芯轴与外壳之间的相对跳动,这两种压力的结合会导致密封的挤压损坏。在磨料环境中,密封与心轴之间的相对旋转和跳动会导致密封的磨料磨损。最后,相对较高的表面速度和密封与心轴之间的接触压力导致密封的粘着磨损。当钻井液压力低于RCD时,有几种合适的旋转密封设计可以在大多数旋转钻井速度下提供可接受的RCD寿命。为了满足API 16RCD中规定的最低持续时间为100小时的更高速度和压力条件,许多RCD设计采用了将密封任务拆分为两个密封的密封方法。一种密封排除了低压差下的磨蚀性钻井液,另一种密封能够在高压差下工作,保留了与钻井液压力几乎相同的清洁润滑剂。这种密封系统一般需要一个外部润滑加压系统,为密封件提供必要的流体和压力环境。由于空间或通道限制或经济考虑,在这些条件下作业的一些钻井场地无法容纳这些大型、复杂、昂贵的润滑剂系统。本文介绍了一种创新的密封系统,该系统可以使RCD在1,500 psi和100 RPM的压力下工作200小时,而无需外部润滑剂加压系统。这种说法是基于广泛的实验室测试三种新技术包括在这个密封系统。本文包括测试程序的主要结果和总结。三个关键技术是:流体动力弹簧负载唇密封,可用于在低压差下排除磨蚀性钻井液,或在高压差下保持清洁润滑剂。一种直接压缩流体动力密封,可以在高压差下保持清洁的润滑剂。一种自动微型阀门,取代了外部润滑加压系统的润滑供应功能。
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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