为实现低风速型风电机组高柔塔筒抗疲劳设计,以某140 m柔塔机组为研究对象,采用欧盟标准EN 1991-1-4推荐的有效相关长度法和频谱模型法,开展涡激振动疲劳损伤评估。基于有限元法建模获取结构固有模态属性;由疲劳应力-寿命(S-N)曲线、风速瑞利分布和Miner法则推导塔筒疲劳应力范围和损伤规则;对比分析柔塔与刚塔两类机型临界风速分布和焊缝疲劳损伤分布。结果表明:柔塔更易激发二阶涡激振动,二阶涡激载荷显著增大,其损伤对不同风场条件(年平均风速、风切变)极为敏感;在6.5 m/s设计风速下,45%~85%塔筒高度处疲劳损伤均超过IEC 61400-6塔架与基础设计要求20年损伤限值0.1,存在疲劳破坏风险,须考虑加阻措施或优化结构设计。
Abstract
In order to reach the anti-fatigue design of high-soft tower of low wind speed wind turbine, taking a 140 m soft tower as the research object, the vortex induced vibration fatigue damage assessment uses the effective correlation length method and spectrum model method recommended by EU standard EN1991-1-4. Acquire inherent modal attributes of the structure by modeling based on finite element method; Derive the fatigue stress range and damage rule of tower from S-N curve, Rayleigh distribution of wind speed and Miner rule; The critical wind speed distribution and weld fatigue damage distribution of soft tower and rigid tower are compared and analyzed. The results show that the soft tower is easier to excite the second-order vortex induced vibration, the second-order vortex induced load increases significantly, and its damage is extremely sensitive to different wind field conditions (annual average wind speed and wind shear); Under the design wind speed of 6.5 m/s, the fatigue damage at 45%-85% of the tower height exceeds the 20-year damage limit of IEC 61400-6 requirement for tower and foundation design by 0.1. There is a risk of fatigue damage, so it is necessary to consider the resistance adding measures or optimize the structural design.
关键词
风电机组 /
塔筒 /
疲劳损伤 /
涡激振动 /
临界风速 /
焊缝
Key words
wind turbines /
towers /
fatigue damage /
vortex induced vibration /
critical wind speed /
weld
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参考文献
[1] 李鹏, 符鹏程, 杨洪源, 等. 柔塔二阶涡激振动阻尼值分析[J]. 风能, 2019(7): 74-77.
LI P, FU P C, YANG H Y, et al.Analysis of damping value of second-order vortex induced vibration of soft tower[J]. Wind energy, 2019(7): 74-77.
[2] 龙凯, 贾娇. 大型水平轴风力机塔筒涡激振动焊缝疲劳分析[J]. 太阳能学报, 2015, 36(10): 2455-2459.
LONG K, JIA J.Analysis of fatigue damage of tower of large scale horizontal axis wind turbine by wind-induced transverse vibration[J]. Acta energiae solaris sinica, 2015, 36(10): 2455-2459.
[3] 盛景, 桑松, 曹爱霞, 等. SPAR型浮式风力机涡激特性研究及系缆疲劳评估[J]. 太阳能学报, 2019, 40(10): 2979-2985.
SHENG J, SANG S, CAO A X, et al.Vortex induced characteristics of SPAR type floating wind turbine and fatigue assessment of mooring system[J]. Acta energiae solaris sinica, 2019, 40(10): 2979-2985.
[4] CARLSON D W, MODARRES-SADEGHI Y.Vortex-induced vibration of spar platforms for floating offshore wind turbines[J]. Wind energy, 2018, 21(11): 1169-1176.
[5] MESKELL C, PELLEGRINO A.Vortex shedding lock-in due to pitching oscillation of a wind turbine blade section at high angles of attack[J]. International journal of aerospace engineering, 2019(5): 1-12.
[6] PELLEGRINO A, MESKELL C.Vortex shedding lock-in due to stream-wise oscillation of a 2-D wind turbine blade section at high angles of attack[C]//American Society of Mechanical Engineers Pressure Vessels & Piping Conference, Anaheim, CA, USA, 2014.
[7] IEC 61400-1—2019, Wind energy generation systems Part 1: design requirements[S].
[8] EN1991-1-4—2004, Eurocode 1: actions on structures-Part 1-4: general actions wind actions[S].
[9] LIVANOS D.Investigation of vortex induced vibrations on wind turbine towers[D]. Delft: Delft University of Technology, 2018.
[10] FRANCESCA L, HANS-JÜRGEN N, RÜDIGER H. Aerodynamic damping model in vortex-induced vibrations for wind engineering applications[J]. Journal of wind engineering and industrial aerodynamics, 2018, 174: 281-295.
[11] IEC 61400-6—2020,Wind energy generation systems-Part 6: tower and foundation design requirements[S].
[12] EN1993-1-6—2004, Eurocode 3:design of steel structures,Part 1-6: general rules: supplementary rules for shell structures[S].
[13] EN1993-1-9—2005, Eurocode 3: design of steel structures—Part 1-9: fatigue[S].
基金
国家重点研发计划(SQ2020YFB150108); 华能集团总部科技项目“基础能源科技研究专项”(HNKJ20-H88)
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