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1.
恢复力—摩擦基底隔震结构的地震可靠性分析 总被引:1,自引:0,他引:1
本文建立了恢复力-摩擦基底隔震结构在地震作用下的运动微分方程。地震地面运动被模拟成随机过程。利用等效线性化方法,获得了这种基底隔震结构在地震作用下的均方位移和均方速度反应。根据最大位侈反应的概率分布函数,求得了这种基底隔震结构和与它相应的基底固定结构在给定地震作用下的破坏概率。计算结果表明,这种基底隔震结构在地震作用下有较高的可靠性。 相似文献
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基础隔震单层偏心结构扭转地震反应分析 总被引:1,自引:0,他引:1
采用微分型滞回恢复力模型模拟隔震支座的恢复力特性,对基础隔震单层偏心结构的扭转地震反应进行分析,研究隔震系统偏心距和上部结构偏心距对结构扭转反应的影响。结果表明,采用隔震技术可以显著降低隔震结构的扭转地震反应。 相似文献
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对于近断层处高烈度区高层剪力墙结构,传统设计难以解决墙体太厚、配筋太大等难题。为研究在考虑近断层影响下高烈度区剪力墙住宅采用隔震设计的技术可行性,采用隔震设计对某剪力墙结构工程进行全面分析。对比分析常规剪力墙结构方案及增设橡胶隔震支座的隔震方案,分析结果表明,隔震方案较常规方案前3阶结构自振周期延长约3倍,从而有效减小了上部结构的地震作用;在设防烈度地震作用下,结构水平向减震系数为0.281,上部结构所受水平地震作用和抗震措施可按降低一度进行设计;罕遇地震作用下隔震支座性能稳定,上部结构基本处于弹性工作状态。研究结论可为隔震支座设计和进一步研究提供参考。 相似文献
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近年来,越来越多的高层建筑采用了基础隔震技术,但研究表明,高层隔震建筑在超烈度地震作用下仍可能发生破坏或倒塌,因此开展高层建筑隔震前后的地震风险对比分析显得尤为重要,可直观显示该类建筑在将来可能发生地震作用下的表现。在进行隔震结构地震风险分析时,上部结构、隔震支座、地震动的不确定性对易损性分析结果有重要影响,因此本文以高层RC框架剪力墙结构为研究对象,在综合考虑隔震支座、上部结构和地震动参数随机性的基础上,定义上部结构层间位移角及隔震层位移2个参数为结构损伤的评价指标,对隔震前后结构的地震易损性进行了对比分析,进而开展地震风险评价。结果表明:隔震技术极大地减小了结构的地震脆弱性,提高了结构的抗震安全性,但其在超烈度大震作用下也具有倒塌的风险;相比于非隔震结构,隔震结构的风险损失值可降低6倍。 相似文献
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隔震技术作为当前最有效的结构减震控制技术之一,在世界各国高烈度地区广泛建造。随着隔震技术的大范围推广,建造工况更为复杂的隔震工程随之不断涌现。系统深入研究复杂地震激励下隔震结构地震响应,是隔震工程长期安全服役的重要保障,也是隔震技术能够不断完善和推广的坚实基础。本文从复杂地震激励涵盖的多维地震、近场和近断层地震、行波效应以及土与结构相互作用四个主要方面入手,依据国内外相关文献开展综述,探讨了复杂地震激励下隔震结构研究存在的问题,并对此进行展望。 相似文献
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《华南地震》2018,(4)
基础隔震结构在罕遇地震作用下可以大幅降低上部结构的地震响应,达到保护结构的目的;但在超过罕遇地震的强震作用下,隔震层位移可能超过预留的隔震沟宽度,隔震结构与周边挡土墙碰撞。建立考虑上部结构非线性的隔震结构模型,设防烈度为8度,进行了超过罕遇地震的强震下地震响应分析,结果表明,隔震结构与挡土墙碰撞减小了隔震层位移,但导致上部结构加速度、位移及层剪力明显放大,放大程度随碰撞刚度及地震动强度的增大而增大,随隔震沟宽度的增大而减小;碰撞刚度增大到一定程度后,层间位移的增大对碰撞刚度的增大不再敏感,加速度及上部结构基底剪力系数则未表现出这一趋势;碰撞还导致支座最大面压的增大及最小面压的减小。 相似文献
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高层隔震结构的等效简化模型研究 总被引:11,自引:1,他引:11
Kelly和周锡元等曾对规则型隔震结构上部单自由度模型进行过讨论,给出了必要的计算公式。对各种中低层规则型隔震建筑,应用此公式可获得满意的结果。近来隔震技术逐渐被应用到高层建筑中。对于高层隔震体系,上部结构的高阶振型效应不能忽略,此时应用单自由度模型将产生较大误差。为此,本文采用上部结构周期和总基底剪力相等的准则,推导了等效模型的结构参数公式,并通过数值模拟分析给出了等效模型简化确定方法。通过对原结构和等效模型结构的地震反应分析,证明了这种等效方法是简便有效的。 相似文献
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砂垫层具有取材方便、造价低、施工简便的特点,为了更好地在农居工程建设中推广应用地基砂垫层隔震技术,通过制作农村房屋结构模型,进行地基砂垫层隔震体系与无隔震体系的大型振动台试验,研究了地基砂垫层隔震体系的隔震性能。基于结构加速度反应、结构位移反应和结构应变反应三个方面,对比分析无隔震试验和地基砂垫层隔震试验的结果,研究地基砂垫层隔震体系的隔震性能。结果表明:地基砂垫层隔震体系能够有效地减小上部结构的地震加速度反应、层间位移反应和应变反应,具有良好的隔震效果;输入地震动的量级是影响地基砂垫层隔震体系隔震效果的一个重要因素。 相似文献
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本文提出一种评估同一地区不同类型结构的抗震投入产出效益的新指标,即结构价值损失比率。利用"5·12"汶川地震后对甘肃陇南的学校、住宅、办公、医院和生命线工程等9类建筑物的调查统计结果,研究了震害等级、经济损失与结构抗震初始投入之间的关系,建立了结构价值损失比率与结构初始投入之间的关系和高烈度区危房率与地震地面运动峰值之间的关系。对比分析了土-木组合、砖-木组合、砖砌体结构、非隔震框架结构和基础隔震结构等不同类型结构的抗震性能,并与实际鉴定的震害等级相比较。利用结构价值损失比率,初步说明了采用隔震新技术结构的减灾效益。 相似文献
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Optimal energy‐based seismic design of non‐conventional Tuned Mass Damper (TMD) implemented via inter‐story isolation 
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下载免费PDF全文 Inter‐story isolation, an effective strategy for mitigating the seismic risk of both new and existing buildings, has gained more and more interest in recent years as alternative to base isolation, whenever the latter results to be impractical, technically difficult or uneconomic. As suggested by the name, the technique consists in inserting flexible isolators at floor levels other than the base along the height of a multi‐story building, thus realizing a non‐conventional Tuned Mass Damper (TMD). Consistent with this, an optimal design methodology is developed in the present paper with the objective of achieving the global protection of both the structural portions separated by the inter‐story isolation system, that is, the lower portion (below the isolation system) and the isolated upper portion (above the isolation system). The optimization procedure is formulated on the basis of an energy performance criterion that consists in maximizing the ratio between the energy dissipated in the isolation system and the input energy globally transferred to the entire structure. Numerical simulations, performed under natural accelerograms with different frequency content and considering increasing isolation levels along the height of a reference frame structure, are used to investigate the seismic performance of the optimized inter‐story isolation systems. Copyright © 2015 John Wiley & Sons, Ltd. 相似文献
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应用叠层橡胶支座进行基础隔震是目前国内外大力推广的一门建筑抗震新技术。但由于对采用隔震技术后建筑物的工程造价是否会增加缺乏具体的经济技术指标,使得建筑开发商对其推广应用一直持保守态度。选择了位于VIII度区的两个典型工程实例(一例为乙类建筑,另一例为丙类建筑),简要分析了同一建筑物采取不同设计方案(不隔震但抗震设防、隔震使实际设防水平提高、隔震后与未隔震建筑保持相同设防水平等三种不同设计方案)对工程造价的影响及差异。分析数据表明,在同等设防烈度下,基础隔震技术的合理应用可以使被隔震建筑的工程造价与同条件只采用抗震设防的建筑工程造价适当降低。 相似文献
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针对目前隔震体系尚不能减小竖向地震反应的缺陷,提出并研制了采用碟形弹簧的竖向半主动隔震装置。竖向半主动隔震装置是由碟形弹簧和外套油缸组成的,且由电磁阀控制油缸内油体与外接蓄油箱内油体间的油路,可实现竖向半主动隔震控制,提出了竖向隔震控制的半主动策略,结合水平隔震支座可实现三维隔震。通过振动台地震模拟实验,验证了三维隔震体系的效能,该研究对高烈度地区隔震技术的改善具有应用参考价值。 相似文献
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This paper proposes an online test technique that employs mixed control of displacement and force. Two types of mixed control, ‘displacement–force combined control’ and ‘displacement–force switching control’ are proposed. In displacement–force combined control, one jack is operated by displacement‐control, and another is operated by force‐control. Validity of the combined control technique is demonstrated by a series of online tests applied to a base‐isolated structure subjected to horizontal and vertical ground motions simultaneously. The substructuring technique is employed in the tests, and the base‐isolation layer is tested, with the rest of the structure modeled in the computer. Displacement‐control and force‐control were adopted for simulating the horizontal and vertical response, respectively. Both displacement‐ and force‐control were implemented successfully despite interference between the two jacks. Earthquake responses of the base‐isolated structure involving the effects of varying axial forces on the horizontal hysteretic behavior of the base‐isolation layer were simulated. In the displacement–force switching control, the jack was operated by displacement‐control when the test specimen was flexible but switched to force‐control once the specimen became stiff. Validity of the switching control technique was also checked by a series of online tests applied to the base‐isolated structure subjected to vertical ground motions. Switching between displacement‐control and force‐control was achieved when the axial force applied to the base‐isolation layer changed from tension to compression or from compression to tension. Both the displacement‐ and force‐control were successful even with many rounds of switching. The test revealed that large accelerations occurred on the floor immediately above the base‐isolation layer at the instants when the axial force of the base‐isolation layer changed from tension to compression. Copyright © 2005 John Wiley & Sons, Ltd. 相似文献
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Real‐time hybrid testing is a very effective technique for evaluating the dynamic responses of rate‐dependent structural systems subjected to earthquake excitation. A smart base isolation system has been proposed by others using conventional low‐damping isolators and controllable damping devices such as magnetorheological (MR) dampers to achieve specified control target performance. In this paper, real‐time hybrid tests of a smart base isolation system are conducted. The simulation is for a base‐isolated two‐degrees‐of‐freedom building model where the superstructure and the low‐damping base isolator are numerically simulated, and the MR damper is physically tested. The target displacement obtained from the step‐by‐step integration of the numerical substructure is imposed on the MR damper, which is driven by three different control algorithms in real‐time. To compensate the actuator delay and improve the accuracy of the test, an adaptive phase‐lead compensator is implemented. The accuracy of each test is investigated by using the root mean square error and the tracking indicator. Experimental results demonstrate that the hybrid testing procedure using the proposed actuator compensation techniques is effective for investigating the control performance of the MR damper in a smart base isolation system. Copyright © 2013 John Wiley & Sons, Ltd. 相似文献
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A methodology for dynamic analysis of linear structure-foundation systems with local non-linearities
An efficient computational technique is presented for the dynamic analysis of large linear structural systems with local non-linearities. The earthquake response evaluation for many practical structures belongs to this class of problems. The technique provides a rational approach to the earthquake-resistant design of structure-foundation systems with predetermined non-linearities occurring along the structure-foundation interface. Various possibilities for base isolation systems are naturally fitted within the proposed framework. In particular, we address uplifting of the structure as a natural base isolation concept. We use the dynamic substructuring technique and an efficient numerical algorithm which accommodates non-proportional damping as a consistent way to reduce significantly the computational effort, which is in sharp contrast to the vast majority of ad-hoc simplified models used for the same purpose. A numerical example which demonstrates the vibration isolation effect when the uplifting of the concrete gravity dam occurs is also presented. 相似文献
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《地震工程与结构动力学》2018,47(5):1169-1192
In seismic base isolation, most of the earthquake‐induced displacement demand is concentrated at the isolation level, thereby the base‐isolation system undergoes large displacements. In an attempt to reduce such displacement demand, this paper proposes an enhanced base‐isolation system incorporating the inerter, a 2‐terminal flywheel device whose generated force is proportional to the relative acceleration between its terminals. The inerter acts as an additional, apparent mass that can be even 200 times higher than its physical mass. When the inerter is installed in series with spring and damper elements, a lower‐mass and more effective alternative to the traditional tuned mass damper (TMD) is obtained, ie, the TMD inerter (TMDI), wherein the device inertance plays the role of the TMD mass. By attaching a TMDI to the isolation floor, it is demonstrated that the displacement demand of base‐isolated structures can be significantly reduced. Due to the stochastic nature of earthquake ground motions, optimal parameters of the TMDI are found based on a probabilistic framework. Different optimization procedures are scrutinized. The effectiveness of the optimal TMDI parameters is assessed via time history analyses of base‐isolated multistory buildings under several earthquake excitations; a sensitivity analysis is also performed. The enhanced base‐isolation system equipped with optimal TMDI attains an excellent level of vibration reduction as compared to the conventional base‐isolation scheme, in terms not only of displacement demand of the base‐isolation system but also of response of the isolated superstructure (eg, base shear and interstory drifts); moreover, the proposed vibration control strategy does not imply excessive stroke of the TMDI. 相似文献
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The development of an efficient energy-dissipating mechanism that works in conjunction with laminated elastomeric bearings in order to reduce the lateral deformation of the isolation system has always been a goal of base isolation research. Theoretically, this deformation will be reduced to the minimum if damping augmentation of the isolation system can reach a critical value. However, augmenting the isolation damping may cause some unwanted side effects. The purpose of this paper is to study the influence of isolation damping on the seismic response of heavily damped base-isolated buildings. The base isolation system is assumed to be linearly viscoelastic and is analysed using the complex mode method. Solutions derived by using perturbation techniques for a two-degree-of-freedom system and the computer simulation for a multiple-degree-of-freedom system reveal that augmenting the isolation damping can reduce efficiently the deformation of the isolation system, but at the price of increasing the high-frequency vibration in the superstructure. When the damping ratio of the isolation system is beyond some level, increasing the isolation damping will enlarge the extreme values of the base and superstructural accelerations. It is also found that approximate solutions derived from the use of classical damping and classical modes of vibration in the seismic analysis of heavily damped base isolation systems can be substantially in error. 相似文献
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Performance of a base isolator with shape memory alloy bars 总被引:1,自引:1,他引:1
A new and innovative base isolation device is introduced in this paper based on extensive research carried out by the authors and their co-workers. A prototype of the device was built and experimentally tested on the shaking table. The new base isolation device consists of two disks, one vertical cylinder with an upper enlargement sustained by three horizontal cantilevers, and at least three inclined shape memory alloy (SMA) bars. The role of the SMA bars is to limit the relative motion between the base and the superstructure, to dissipate energy by their super-elastic constitutive law and to guarantee the re-centring of the device. To verify the expected performance, a prototype was built and tested under sinusoidal waves of displacement of increasing frequency with different amplitudes. It is shown that the main feature of the proposed base isolation device is that for cyclic loading, the super-elastic behavior of the alloy results in wide load-displacement loops, where a large amount of energy is dissipated. 相似文献