地铁上盖层间隔震建筑设计研究

THE DESIGN OF INTER-STORY ISOLATED BUILDINGS BUILT ON TOP OF METRO DEPOTS

  • 摘要: 层间隔震技术是提升地铁上盖结构抗震性能的有效措施。为识别影响该类结构关键设计指标的控制因素,从而指导该类结构的精细设计,依托一大底盘-双塔楼地铁上盖层间隔震工程案例,考虑了3种塔楼方案和4种隔震层方案,设计了12个分析案例。基于精细模型分析了塔楼、隔震层和大底盘相对刚度比和隔震层屈重比对9个关键设计指标的影响规律,包括塔楼和大底盘的中震减震系数、大震最大层间位移角和楼面绝对加速度,以及隔震层的大震位移、极大面压和极小面压,识别了影响各设计指标的关键影响因素。结果表明:对于塔楼,减震系数和楼面最大绝对加速度的控制因素是隔震层刚度和屈重比,减小两者可以取得更好的控制效果,增大塔楼刚度也会存在一定的控制效果,但相对有限;增大塔楼刚度和减小隔震层刚度及屈重比可以一定程度控制塔楼最大层间位移角,当两者达到一定程度后控制效果均趋于稳定。对于大底盘,塔楼和隔震层对其设计指标影响相对较小。对于隔震层,隔震层刚度及屈重比是大震隔震层位移的主要控制因素,其减小会显著增大该位移;塔楼刚度是极大面压的控制性因素,刚度的增大会带来重力的增大,从而带来极大面压的增大;增大塔楼刚度和减小隔震层刚度均可显著控制支座中的拉应力,其中塔楼刚度的增大效果更为突出。该研究的相关成果可为地铁上盖层间隔震建筑的抗震性能控制和设计提供参考。

     

    Abstract: Inter-story isolation is an effective method to improve the seismic performance of buildings built on top of metro depots (i.e., large chassis). To identify the factors controlling the critical design indexes and guide the detailed design, 12 study cases were designed based on a real engineering project, which includes two inter-story isolated towers built on top of a metro depot. Among these cases, three schemes and four schemes were considered for the tower and isolation system, respectively. Based on a refined model, the influence of the stiffness ratio between the tower, the isolation system and the large chassis and the yield ratio of the isolation system on nine critical design indexes were analyzed. The design indexes include the horizontal seismic absorbing coefficient (β) under the design basis earthquake, maximum inter-story drift ratio (θmax) and maximum absolute floor acceleration (amax) under the maximum considered earthquake of towers and chassis, maximum displacement of isolation system (Dmax), maximum and minimum compressive stresses of the isolator under the maximum considered earthquake. Subsequently, the factors controlling each index were identified. For the tower, the stiffness and yield ratio of the isolation system are the controlling factors for the β and amax. The decrease of these two factors can achieve a good control effect, while the increase of the stiffness of the tower can control β and amax to a certain extent. The increase of the stiffness of the tower and the decease of the stiffness and the yield ratio can control θmax to a certain extent, but such a control effect tends to stabilize when these two factors reach a certain extent. For the chassis, the schemes of the tower and isolation system has little impact on the design indexes. For the isolation system, the controlling factors for Dmax are the stiffness and yield ratio of the isolation system. The decrease of these factors leads to a significant increase of Dmax. The stiffness of the tower is the controlling factor for the maximum compressive stress of the isolators because the gravity increases with the stiffness. The increase of the stiffness of the tower and the decrease of the stiffness of the isolation system can significantly control the tensile stress of the isolators, and the control effect caused by the increase of the stiffness of two is more significant. The results provide a reference for the seismic performance control and design of inter-story isolated buildings built on top of metro depots.

     

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