创新深水卸油系统

J. B. Araujo, A. C. Fernandes, J. S. Sales, Ana Clara Thurler, A. Vilela
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引用次数: 3

摘要

随着fpso(浮式、生产、储存和卸载)装置的使用,海上石油生产面临着增加油井数量、处理和储存能力以及最终的石油卸载和运输的挑战。随着一些油田自然活动的发展,扩展系泊fpso的数量和动态定位穿梭油轮的使用增加了,然而,这些都是生产能力和运输成本增加的瓶颈。显然,有必要采用大型油轮和常规油轮的替代方案,目前正在测试和建议几种技术的尝试和使用。本文对一种新型深水装油码头(OLT)进行了初步的数值分析和成本分析。根据现场数据、海洋研究和广泛的实践经验,OLT应该可以将fpso直接卸载到包括vlcc在内的传统穿梭油轮上。OLT概念允许将石油从FPSO转移到停泊在CALM浮标上的传统油轮上,通过由系留水下浮标支撑的水下卸油管线(OOLs)。传统的油轮将通过浮动的软管串接收石油。这种OLT概念的基础是水下浮标的应用,以支持oll,从而同时解除FPSO和CALM浮标运动的耦合。因此,CALM浮标下的OOLs载荷和疲劳强度也有所降低。本文对巴西近海盐下区域的OLT具体概念进行了评估,并给出了通过柔性卸载线分别连接到FPSO和CALM浮标的水下浮筒的数值分析结果。结果确定了技术上可行的解决方案,可以补充实验室和现场测试。此外,该解决方案的成本影响已经进行了评估,初步数据表明,一个系统的最终测试、建造和安装所需的投资仅为目前需要船对船石油转移的油轮提升成本的一小部分。使用这种创新解决方案所评估的经济效益包括:完全避免了船对船的成本;将每吨运输成本降低50%(50%),消除卸载瓶颈,从而更好地利用FPSO存储和工厂处理能力,并最终减少油轮卸载作业的数量,通过降低风险暴露,极大地提高了作业安全。
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Innovative Oil Offloading System for Deep Water
Offshore oil production with the employment of FPSOs (Floating, Production, Storage and Offloading) unit faces the challenge of increasing well volumes, processing and storage capacity and ultimately oil offloading and transportation. Following the natural activity development in some oil fields, the number of spread-moored FPSOs and the employment of Dynamic Positioning Shuttle Tankers increased, however represent altogether a bottleneck for the production capacity and considerable transportation cost increment. The need to implement alternatives for the use of larger and conventional tankers is evident, and several attempts and use of technology are being tested and proposed. The work presents preliminary numerical and cost analysis of an innovative Oil Loading Terminal (OLT) for deep water. Based on field data, metocean studies and extensive practical experience, the OLT should allow direct offloading from the FPSOs onto conventional shuttle tankers including VLCCs. The OLT concept allows the transfer of oil from an FPSO to a conventional tanker moored in CALM Buoy through submerged oil offloading lines (OOLs) supported by a tethered submerged buoy. The conventional tanker will receive the oil through a floating hose string. The cornerstone of this OLT concept is the subsurface buoy application to support the OLLs and consequently de-coupling the FPSO and CALM Buoy motions simultaneously. As a result, the OOLs loads and fatigue efforts under the CALM Buoy also decrease. The paper evaluates an OLT specific conception for the Brazilian offshore pre-salt area and results related to the numerical analysis carried out are presented considering one submerged buoy connected to a FPSO and CALM Buoy via flexible offloading lines respectively. The results appoint to a technically feasible solution that can be complementarily laboratory and field tested. Further, the solution cost impact has been assessed and initial figures demonstrate that the final testing, construction and installation of one system will need investment that cost a fraction of tanker lifting costs currently requiring Ship-to-Ship oil transfers. The economies assessed with the use of this innovative solution include total avoidance of Ship-to-Ship costs; cuts transportation cost per ton in up to 50% (fifty percent), eliminates offloading bottlenecks allowing better use of FPSO storage and plant processing capacity, and ultimately decreases the number of tanker offloading operations with considerable benefit to operational safety by reducing risk exposure.
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