TLD的减振原理及其在JZ20－2MUQ平台减冰振中的应用研究

ＴＬＤ在基底运动下内部液体对基底结构的作用可由分析液体运动或直接通过试验测定得到，将所得的ＴＬＤ对基底结构作用与基底运动的关系直接应用到结构动力平衡方程中，求得结构系统在安装ＴＬＤ后在外力作用下的响应。根据这一思路，建立了ＴＬＤ减振作用的分析步骤和表达式。运用该方法对ＪＺ２０－２ＭＵＱ平台利用ＴＬＤ减冰振进行了试验和分析研究。首先测定在ＪＺ２Ｏ－２ＭＵＱ平台减冰振中采用的原型ＴＬＤ的基底剪力关于基底位移的传递函数和阻尼系数，将测量值代入在安装ＴＬＤ后的结构响应关于外力传递函数表达式中求得其值，由安装ＴＬＤ所带来的结构响应传递函数值变化推算减振效果。此外，通过ＪＺ２Ｏ－２ＭＵＱ平台利用ＴＬＤ减振的室内模拟和现场试验验证该方法预报结果是可靠的。     

基于SESAM的半潜式平台水动力响应分析

根据三维势流理论,应用SESAM软件对国内某海域半潜式平台的水动力性能进行了研究。分析了目标平台在频域下的附加质量系数、阻尼系数,以及运动响应幅值(RAO)等一系列水动力参数,并研究了粘性阻尼对半潜式平台RAO的影响。结果表明,粘性阻尼对半潜式平台运动响应幅值有很大的影响,研究水动力性能时不能忽略。     

Truss Spar平台垂荡响应频域分析

利用已有水动力试验和数值模拟结果及Morison方程,简化估计了Truss Spar平台垂荡方向水动力贡献,快速有效地预报了平台极端海况下的垂荡响应.在频域内分别采用数值迭代计算和粘滞阻尼线性化方法得到了平台在不同数量垂荡板配置下的垂荡响应幅值算子.在墨西哥湾、西非和中国南海等3种不同地区极端海况以及墨西哥湾工作状态海况下计算了平台的响应极值,分析发现平台波频垂荡响应对入射波浪周期非常敏感.采用JONSWAP波能谱得到了Truss Spar平台垂荡响应谱.通过比较和参数分析,验证了平台在设计上的合理性与实际海况下良好的垂荡运动性能.     

海洋平台结构地震响应不确定性因素分析

本文将海洋平台结构的刚度、质量、阻尼以及动水阳力系数C_m,C_d模拟为随机变量,利用随机有限元法,分析了这些参数的变异性引起的海洋平台结构地震响应变异性问题。结果表明,海洋平台结构地震响应的变异性与输入结构参数本身的变异性具有同一量级,动水阻力参数变异性对平台反应的影响比结构参数变异性平台反应的影响稍小。     

随机波浪下Truss Spar平台垂荡运动时域分析

研究Truss Spar平台在随机波浪下的垂荡运动特性。采用ITTC双参数谱,考虑绕射作用,数值计算了平台所受的随机波浪力。利用已有的水动力试验和数值模拟结果及Morison方程,估计了Truss Spar平台垂荡方向的附加质量和粘滞阻尼大小。考虑非线性阻尼和瞬时波面的影响,运用Runge-Kutta数值迭代算法,比较了不同随机波浪参数对平台运动响应的影响,特别是波浪特征周期接近垂荡固有周期时。结果表明,当波浪特征周期接近平台垂荡固有周期时,平台产生大幅垂荡运动,频域的运动分析结果比时域结果偏小。     

海洋对热带气旋响应的研究

建立一个二层非线性原始方程海洋模式，用以研究海洋对静止和以不同移速移动的热带气旋的响应。数值试验结果表明，海洋对静止ＴＣ的响应，具有不对移性；在ＴＣ中心处，抽吸使混合层变浅，在ＴＣ最大风速半径处，大风夹卷明显使ＭＬ加深和海表温下降；海洋对移动ＴＣ的响应，具有右偏性，且随移速加快而加剧。ＭＬ深度和ＳＳＴ的变化对ＴＣ移速十分敏感，而海流则不同。     

大直径浮式结构涡激振动的数值模拟

通过数值模拟的方法研究Spar平台两自由度涡激运动,建立考虑流固耦合时Spar平台涡激运动时域数值模型,采用Matlab软件编程计算了Spar平台在不同流速下的两自由度涡激运动响应,并比较了Spar平台涡激运动时非线性阻尼对于结构的影响。通过对数值模型模拟结果的比较发现,非线性阻尼能降低Spar平台两向涡激运动响应的计算结果,尤其是当平台发生共振时,这个影响更为显著。     

考虑随机波浪载荷的导管架平台结构优化设计

研究海洋平台适应恶劣海况的设计理论，应用ANSYS软件对位于渤海湾的CII导管架海洋平台进行动力分析，得到CII平台基本动力学参数和在随机波浪载荷作用下的动力响应。CII平台是以管件为主的空间框架结构，将管件外径作为固定约束，以其壁厚作为设计变量，考虑刚度、强度和稳定性等约束条件，以结构的总重量为优化目标，对平台进行构件尺寸的优化设计，计算结果表明目标函数值比原设计减小4．33％，经济效益明显。此研究方法对近海导管架海洋平台的结构设计具有实际参考价值。     

新模块化单桩缓冲系泊浮式集成结构系统研究

为配合我国南海重要岛礁陆域拓展及海洋资源开发,提出了一种基于新型单桩缓冲系泊与波浪能装置(WEC)集成的具有潮汐自适应特性的模块化浮体结构系统。基于三维势流理论,综合考虑浮体模块与单桩缓冲结构的相对运动及相关波浪能装置的机械耦合机理,重点研究了新型单模块浮式结构系统在典型海况下的动力响应特征,获得了单桩缓冲系泊系统的初步优化设计参数,并对极端海况进行安全校核,提出了优化自存策略。数值结果表明,此带有波浪能装置的新型单桩缓冲系泊系统,不仅可以有效地降低浮体模块的运动响应幅值并改善平台舒适度,还可以获得可观的发电量,而且在极端海况下,可以通过调整阻尼装置系统来稳定浮体模块的运动。     

转角阻尼器对海洋平台-摇摆墙体系抗振分析

在海洋平台摇摆墙体系基础上,提出在海洋平台和摇摆墙之间刚性连接杆的铰接点处安装粘弹性转角阻尼器的减振措施,对海洋平台进行进一步减振控制。对粘弹性转角位移阻尼器的刚度和阻尼参数进行了优化分析,可知阻尼器的阻尼与刚度在结构减振中起到了十分重要的作用,且存在特定范围内的优化值。以JZ20-2北高点井口平台为例,利用ANSYS进行地震荷载作用和实测挤压冰荷载下的仿真分析,研究了粘弹性转角阻尼器在海洋平台和摇摆墙之间刚性连接杆铰接点处的不同安装方式,对比分析减振效果。结果表明,在该体系刚性连接杆的铰接点处安装粘弹性转角阻尼器能显著降低结构的振动反应,连接杆右侧安装粘弹性转角阻尼器的方式为减振效果最佳方式。     

Vibration Control of Multi-Tuned Mass Dampers for An Offshore Oil Platform

The purpose of this study is to investigate the effectiveness of multi-tuned mass dampers (MTMD) on mitigating vi-bration of an offshore oil platform subjected to ocean wave loading. An optimal design method is used to determine the optimal damper parameters under ocean wave loading. The force on the structure is determined by use of the linearized Morison equation. Investigation on the deck motion with and vvithout MTMD on the structure is made under design condi-tions. The results show that MTMD with the optimized parameters suppress the response of each structural mode. The sensitivity of optimum values of MTMD to characteristic wave parameters is also analyzed. it is indicated that a single TMD on the deck of a platform can have the best performance, and the small the damping value of TMD, the betler the vibration control.     

Torsional Response of the Offshore Platform with TMD

It is pointed out in this paper that the offshore platform could be controlled by means of the Tuned Mass Damper (TMD) if there is torsional vibration in the system. The effectiveness of the location of TMD is quantified with the help of the response ratio between the peak responses of the system in the presence and in the absence of TMD. In addition, the parameters of frequency and damping ratio of TMD are optimized.     

Energy Anaiysis for TMD-Structure Systems Subjected to Impact Loading

This paper investigates the characteristics of reduction of the lateral vibration by use of a Tuned Mass Damper (TMD) for offshore jacket platforms under impact loading. Unlike traditional analysis, the present analysis focuses on the energy concept of TMD/structure systems. In this study, a time domain is taken. The platform is modeled as a simplified single-degree-of-freedom (SDOF) system by extraction of the first vibration mode of the structure and the excited force is assumed to be impact loading. The energy dissipation and energy transmission of the structure-TMD system are studied. Finally, an optimized TMD design for the modeled platform is demonstrated based on a new type of cost function - maxi-mum dissipated energy by TMD. Results indicate that TMD control is effective in reducing the Standard deviation of the deck motion but less effective in reducing the maximum response under impact loading.     

Dynamic Response Behaviors of Upright Breakwaters Under Breaking Wave Impact

- The dynamic response behaviors of upright breakwaters under broken wave impact are analysed based on the mass-damper-spring dynamic system model. The effects of the mass, damping, stiffness, natural period, and impulse duration (or oscillation period) on the translation, rotation, sliding force, overturning moment, and corresponding dynamic amplifying factors are studied. It is concluded that the ampli-ying factors only depend on the ratio of the system natural period to impulse duration (or oscillation period) under a certain damping ratio. Moreover, the equivalent static approach to breakwater design is also discussed.     

Studies of TLP dynamic response under wind, waves and current

Investigated is the coupled response of a tension leg platform (TLP) for random waves. Inferred are the mass matrix, coupling stiffness matrix, damping matrix in the vibration differential equation and external load of TLP in moving coordinating system. Infinitesimal method is applied to divide columns and pontoons into small parts. Time domain motion equation is solved by Runge-Kutta integration scheme. Jonswap spectrum is simulated in the random wave, current is simulated by linear interpolation, and NPD spectrum is applied as wind spectrum. The Monte Carlo method is used to simulate random waves and fluctuated wind. Coupling dynamic response, change of tendon tension and riser tension in different sea conditions are analyzed by power spectral density (PSD). The influence of approach angle on dynamic response of TLP and tendon tension is compared.     

圆筒形FPSO尺度规划和运动性能研究

首先介绍全球海域圆筒形装置的工程应用案例,对比圆筒形FPSO相对常规船形的优势,然后以原油储量、工艺模块甲板面积、耐波性、稳性、系泊系统、排水量等控制参数为目标,研究圆筒形FPSO主尺度选取依据,分舱原则。重点研究圆筒形装置的阻尼板结构,此为抑制运动响应的关键结构,通过模型试验方法分析对比了水平阻尼板、不同角度锥形阻尼板的特性。最后研究圆筒形装置运动性能分析方法,介绍二阶响应数值预报方法,研究垂荡和横摇运动的耦合效应,分析波频和低频运动响应,通过模型试验进行了验证,从而指导圆筒形装置设计。     

考虑桩土作用独桩海洋平台横向振动特性研究

采用动Winkler弹性地基梁模型模拟桩土问动力相互作用，并考虑了流体与桩问相互作用，通过组合成层土中、水中桩单元的刚度阵，推得了独桩海洋平台连续系统横向振动的动刚度阵及在波浪力作用下平台甲板处的频率响应函数，进而求得了在确定性波浪力及随机波浪力作用下桩身任意点的位移响应。最后，通过算例研究和分析了在随机波浪力作用下成层土参数、甲板上重量及冲刷淘深等因素对平台振动响应的影响。     

三锚系大型浮标运动响应特性数值研究

以三锚系浮标系统为研究对象,基于AQWA与OrcaFlex软件开展了三锚系大型浮标系统运动响应特性数值模拟研究。对直径10 m的浮标结构在波浪荷载下的水动力特性进行研究,校核了浮标的初稳性和大倾角稳性特征,计算分析了浮标的附加质量、辐射阻尼、运动响应幅值算子RAO等水动力参数,阐明了不同风、浪、流工况下三锚系浮标与辅助浮筒的运动响应特性,揭示了浮标三锚链导缆孔处锚泊张力随入射角度、波高和周期等的变化规律。研究结果表明：该浮标稳性和随波性能较好。与无浮筒三锚系浮标相比,带辅助浮筒的三锚系浮标系统的运动响应和锚泊张力减小,随着波高和周期增大,三锚系浮标系泊锚链的极端张力值逐渐增大,尤其是在极端海况下,迎浪向锚链极端张力急剧增大。     

The Optimal Design of TMD for Offshore Structures

This paper presents the optimal design procedure of Tuned Mass Damper(TMD)for re-ducing vibration of an actual steel jacket offshore platform excited by random wave loading.In this study,a frequency domain is taken.The force on the structure is determined by use of the linearized Morisonequation for an input Power Spectral Density(PSD)of wave elevation.The sensitivity of optimum valuesof TMD to characteristic parameters of random wave spectrum is analyzed.An optimized TMD designfor the modeled platform is given based on design conditions and the findings of the study.     

Wave Radiation by A Submerged Ring Plate in Water of Finite Depth

A plate submerged at a certain depth underneath the sea surface has been proposed as a structure type for different purposes, including motion response reduction, wave control, and wave energy harvesting. In the present study, the three-dimensional wave radiation problem is investigated in the context of the linear potential theory for a submerged ring plate in isolation or attached to a floating column as an appendage. In the latter case, the ring plate is attached at a certain distance above the column bottom. The structure is assumed to undergo a heave motion. An analytical model is developed to solve the wave radiation problem via the eigenfunction expansion method in association with the region-matching technique. With the velocity potential being available, the hydrodynamic coefficients, such as added mass and radiation damping, are obtained through the direct pressure integration. An alternative solution of radiation damping has also been developed in this study, in which the radiation damping is related to the Kochin function in the wave radiation problem. After validating the present model, numerical analysis is performed in detail to assess the influence of various plate parameters, such as the plate size and submergence depth. It is noted that the additional added mass due to the attached ring plate is larger than that when the plate is in isolation. Meanwhile, the radiation damping of the column for the heave motion can vanish at a specific wave frequency by attaching a ring plate, corresponding to a condition that there exist no progressive waves in the exterior region.