水合物试采工程中水下井口组合的横向承载特性

IF 4.6 3区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY
China Geology Pub Date : 2023-07-01 DOI:10.31035/cg2022057
Jing Zeng , Wen-wei Xie , Bei-bei Kou , Jing-an Lu , Xing-chen Li , De-jun Cai , Hao-xian Shi , Ke-wei Zhang , Hua-qing Liu , Jin Li , Bo Li
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引用次数: 0

摘要

导管和吸力锚是深水钻井或海洋工程领域提供承载力的关键设备,具有作业效率高、施工周期短的优点。为了在深水浅层水合物油藏中打水平井,在第二轮水合物试采项目中,采用抽锚井口装置承担主要垂直承载力,以减少导管下入深度,提高启动点位置。然而,深水吸锚井口装置在立管移动荷载作用下的变形规律尚不清楚,有必要了解其侧向承载特性,以指导其结构方案的设计。基于三维实体有限元方法,建立了吸锚井口装置的实体有限元模型。在该模型中,海底土壤被分为七层,模拟了井口组件与土壤之间的接触,并将垂直载荷和弯矩施加到井口节点,以模拟在深水中工作时立管的运动。讨论了常规井口装置和吸锚式井口装置在井口载荷影响下的侧向承载稳定性。分析结果表明,弯矩是影响井口管柱横向变形的主要因素;增大导体外径的抗弯性能优于增大导体壁厚的抗弯特性;对于海底井口,吸锚明显提高了侧向承载力,减少了侧向变形。吸锚井口组件的导线仍需降低到最大扰动深度以下的一定深度,以确保侧向轴承的稳定性。因此,开发了一种吸锚井口组合导线最小下入深度的方法。现场实施表明,与第一轮水合物试采项目相比,导线下入深度增加了9.42m,试采过程中不存在井口倾覆的风险。本文提出的确定最小导水深度的方法是可行的,在后续水合物勘探开发中仍将发挥重要作用。©2023中国地质编辑部。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Lateral bearing characteristics of subsea wellhead assembly in the hydrate trial production engineering

Conductor and suction anchor are the key equipment providing bearing capacity in the field of deep-water drilling or offshore engineering, which have the advantages of high operation efficiency and short construction period. In order to drill a horizontal well in the shallow hydrate reservoir in the deep water, the suction anchor wellhead assembly is employed to undertake the main vertical bearing capacity in the second round of hydrate trial production project, so as to reduce the conductor running depth and heighten the kick-off point position. However, the deformation law of the deep-water suction anchor wellhead assembly under the moving load of the riser is not clear, and it is necessary to understand the lateral bearing characteristics to guide the design of its structural scheme. Based on 3D solid finite element method, the solid finite element model of the suction anchor wellhead assembly is established. In the model, the seabed soil is divided into seven layers, the contact between the wellhead assembly and the soil is simulated, and the vertical load and bending moment are applied to the wellhead node to simulate the riser movement when working in the deep water. The lateral bearing stability of conventional wellhead assembly and suction anchor wellhead assembly under the influence of wellhead load is discussed. The analysis results show that the bending moment is the main factor affecting the lateral deformation of the wellhead string; the anti-bending performance from increasing the outer conductor diameter is better than that from increasing the conductor wall thickness; for the subsea wellhead, the suction anchor obviously improves the lateral bearing capacity and reduces the lateral deformation. The conduct of the suction anchor wellhead assembly still needs to be lowered to a certain depth that below the maximum disturbed depth to ensure the lateral bearing stability, Thus, a method for the minimum conductor running depth for the suction anchor wellhead assembly is developed. The field implementations show that compared with the first round of hydrate trial production project, the conductor running depth is increased by 9.42 m, and there is no risk of wellhead overturning during the trial production. The method for determining the minimum conductor running depth in this paper is feasible and will still play an important role in the subsequent hydrate exploration and development.

©2023 China Geology Editorial Office.

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来源期刊
China Geology
China Geology GEOLOGY-
CiteScore
7.80
自引率
11.10%
发文量
275
审稿时长
16 weeks
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