Global Performance Analysis for Deepwater Flexible Riser

Abstract

Abstract:

Ocean flexible pipe is of great importance in ocean oil resource exploitation. Due to its outstanding capability of erosion resistance, terrain adaptability, long continuous length and convenient installation, flexible pipe is gradually replacing traditional steel pipe. Flexible riser has been widely used among foreign countries to connect the floating structures to underwater production system of deepwater oil/gas field. However, there is no design and manufacturing technology in China for deepwater flexible pipe. Here we focus on the introduction of analysis method on the global performance of flexible pipe in-place condition. Taking riser parameters, environmental conditions, parameters of the floating production, storage and offloading system, and the riser shape as input parameters, static analysis, dynamic analysis, regular wave analysis and irregular wave analysis can be performed using certain software. Based on the analysis results, one can easily judge whether the designed riser can meet the application requirements.

Key words: marine oil and gas pipeline, flexible riser, composite flexible pipe, floating production, storage and offloading, mooring analysis, global analysis

CLC Number:

TE832

Cheng-lin LU, Lan LI, Ping-na SONG, Jing CAO, Yong SHA, Wei-wei ZHOU. Global Performance Analysis for Deepwater Flexible Riser[J]. Ocean Engineering Equipment and Technology, 2015, 2(2): 88-92.

Figures/Tables 10

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References 9

[1]	American Petroleum Institute.API SPEC 17J. Specification for unbonded flexible pipe[S]. 2008.
[2]	American Petroleum Institute.API RP 17B. Recommended practice for flexible pipe[S]. 2008.
[3]	International Organization for Standardization. ISO 13628-2. Petroleum and natural gas industries--design and operation of subsea production systems. Part 2: unbonded flexible pipe systems for subsea and marine application[S]. 2006.
[4]	Det Norske Veritas.DNV-OS-F201. Dynamic risers[S]. 2001.
[5]	Det Norske Veritas.DNV-OS-E301. Position mooring[S]. 2008.
[6]	Det Norske Veritas.DNV-RP-C205. Environmental conditions and environmental loads[S]. 2007.
[7]	Det Norske Veritas.DNV-OS-F101. Submarine pipeline systems[S]. 2012.
[8]	Det Norske Veritas.DNV-RP-C103. Column stabilized units[S]. 2005.
[9]	American Petroleum Institute.API RP 2SK. Recommended practice for design and analysis of station-keeping systems for floating structures[S]. 2005.

序号	名称	功能
1	骨架层	支撑内压密封层,防止内压密封层压溃
2	内压密封层(内衬层)	形成输送流体的密封层
3	抗压铠装层	承受内压及外压
4,6,8	耐磨层	固定金属层,防止金属与金属接触磨损
5,7	抗拉铠装层	承受轴向拉力
9	中间包覆层	限制抗拉层钢丝变形,减少磨损,双重保护
10	保温层	防止热量流失
11	外包覆层	抗机械损坏,防止海水进入

参数	取值
内径/mm	203.2
外径/mm	418.2
单重/(kg·m^-1)	218
弯曲刚度/(kN·m²)	472
轴向刚度/(MN)	660
扭转刚度/(kN·m²·rad^-1)	7390
存储弯曲半径/m	2.74
操作弯曲半径/m	4.0
允许操作最大曲率/m^-1	0.25
允许最大拉力/kN	2300
允许最大压缩/kN	100

偏移方向	图示
Near offset (Near) 船的偏移作用方向与立管平面平行,朝向海床连接处.偏移作用与来流方向同向.船头与来流存在一个和工况相关的夹角α
Far offset (Far) 船的偏移作用方向与立管平面平行,朝向远离海床链接处的方向.偏移作用与来流方向同向.船头与来流存在一个和工况相关的夹角α
Cross offset (Cross) 船的偏移作用在与立管平面垂直的方向上.偏移作用与来流方向同向.船头与来流存在一个和工况相关的夹角α.正负号用来区别两个等效的交叉偏移
Quartering near offset (Qnear) 船的偏移作用与立管平面成45°角,朝向海床连接处.船头与来流存在一个和工况相关的夹角α.正负号用来区别两个等效的偏移
Quartering far offset (Qfar) 船的偏移作用与立管平面成45°角,朝向远离海床连接处方向.船头与来流存在一个和工况相关的夹角α.正负号用来区别两个等效的偏移

极端荷载工况	环境方向	偏移方向
EX-01-Re/Ir	共线	Far
EX-02-Re/Ir		Near
EX-03-Re/Ir		Cross
EX-04-Re/Ir		Qfar
EX-05-Re/Ir		Qnear
EX-06-Re/Ir	交叉	Far
EX-07-Re/Ir		Near
EX-08-Re/Ir		Cross
EX-09-Re/Ir		Qfar
EX-10-Re/Ir		Qnear

极端荷载工况	环境方向	偏移方向	有效拉力/kN		最大曲率/m^-1
极端荷载工况	环境方向	偏移方向	最大	最小	最大曲率/m^-1
EX-01-Re	共线	Far	1002.3	-32.3	0.245
EX-02-Re		Near	741.7	-2.9	0.105
EX-03-Re		Cross	986.5	-31.5	0.223
EX-04-Re		Qfar	958.1	-28.2	0.226
EX-05-Re		Qnear	723.8	-3.1	0.121
EX-06-Re	交叉	Far	978.3	-37.0	0.222
EX-07-Re		Near	790.4	-22.5	0.132
EX-08-Re		Cross	748.9	-18.4	0.189
EX-09-Re		Qfar	774.1	-19.3	0.195
EX-10-Re		Qnear	789.0	-15.9	0.116