Girder extension effect on earthquake resilience of ship unloader crane: A numerical study

THE 4TH BIOMEDICAL ENGINEERING’S RECENT PROGRESS IN BIOMATERIALS, DRUGS DEVELOPMENT, HEALTH, AND MEDICAL DEVICES: Proceedings of the International Symposium of Biomedical Engineering (ISBE) 2019 Pub Date : 2019-12-10 DOI:10.1063/1.5138359

Suwarno, A. Syaifudin

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Abstract

Girder of a ship unloader crane (SUC) with a rated capacity of 1250 t/h has to be extended in order to follow jetty upgrading. The girder extension is limited by the railway span of gantry crane and the capacity of belt conveyor, which are maintained. This simulation aims to determine the effect of girder extension on the vulnerability of SUC to earthquake shocks in Indonesian region. A new method is proposed to evaluate earthquake resilience of crane structure that is not anchored to the ground, based on an equivalent static load of earthquake shock. The equivalent static simulation is carried out using ANSYS Mechanical APDL R18 on the 3d-truss model of SUC, which is generated based on the general arrangement drawing. To investigate the influence of earthquake shocks on the SUC structure, three variations of girder extension is applied, i.e. 3m, 6m, and 9m. The applied load consists of the SUC operating load and the earthquake load that works on the SUC structure’s supports. The earthquake resilience of SUC after girder extension is evaluated by comparing the reaction forces that occur in the supports. The simulations indicated that the girder extension can reduce the earthquake resilience of SUC, depending on the direction of the earthquake propagation.Girder of a ship unloader crane (SUC) with a rated capacity of 1250 t/h has to be extended in order to follow jetty upgrading. The girder extension is limited by the railway span of gantry crane and the capacity of belt conveyor, which are maintained. This simulation aims to determine the effect of girder extension on the vulnerability of SUC to earthquake shocks in Indonesian region. A new method is proposed to evaluate earthquake resilience of crane structure that is not anchored to the ground, based on an equivalent static load of earthquake shock. The equivalent static simulation is carried out using ANSYS Mechanical APDL R18 on the 3d-truss model of SUC, which is generated based on the general arrangement drawing. To investigate the influence of earthquake shocks on the SUC structure, three variations of girder extension is applied, i.e. 3m, 6m, and 9m. The applied load consists of the SUC operating load and the earthquake load that works on the SUC structure’s supports. The earthquake resilience of ...

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梁伸对卸船起重机抗震性能影响的数值研究

为配合码头升级改造，额定容量为1250t /h的卸船起重机的主梁需要加长。梁的延伸受龙门起重机的轨道跨度和带式输送机的承载能力的限制，需要保持。本次模拟的目的是确定梁的延伸对印尼地区SUC的地震易损性的影响。提出了一种基于地震等效静载荷的非锚固起重机结构抗震性能评估方法。利用ANSYS Mechanical APDL R18对基于总布置图生成的SUC三维桁架模型进行等效静力仿真。为了研究地震冲击对SUC结构的影响，采用了3种不同的梁伸出量，即3m、6m和9m。应用荷载包括SUC的运行荷载和作用于SUC结构支座的地震荷载。通过对比支座的反力，评价了悬臂梁伸后的抗震性能。仿真结果表明，随地震传播方向的不同，悬臂梁的加长会降低悬臂梁的抗震性能。为配合码头升级改造，额定容量为1250t /h的卸船起重机的主梁需要加长。梁的延伸受龙门起重机的轨道跨度和带式输送机的承载能力的限制，需要保持。本次模拟的目的是确定梁的延伸对印尼地区SUC的地震易损性的影响。提出了一种基于地震等效静载荷的非锚固起重机结构抗震性能评估方法。利用ANSYS Mechanical APDL R18对基于总布置图生成的SUC三维桁架模型进行等效静力仿真。为了研究地震冲击对SUC结构的影响，采用了3种不同的梁伸出量，即3m、6m和9m。应用荷载包括SUC的运行荷载和作用于SUC结构支座的地震荷载。的抗震能力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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THE 4TH BIOMEDICAL ENGINEERING’S RECENT PROGRESS IN BIOMATERIALS, DRUGS DEVELOPMENT, HEALTH, AND MEDICAL DEVICES: Proceedings of the International Symposium of Biomedical Engineering (ISBE) 2019

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