木面板预应力悬索桥性能预测

IF 0.6 4区 工程技术 Q4 ENGINEERING, CIVIL Baltic Journal of Road and Bridge Engineering Pub Date : 2017-12-27 DOI:10.3846/BJRBE.2017.29
V. Goremikins, D. Serdjuks, K. Buka-Vaivade, L. Pakrastins, N. Vatin
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引用次数: 17

摘要

缆索特拉斯的使用允许开发对主梁刚度要求降低的桥梁,其中通过稳定缆索的预应力来确保桥梁的整体刚度。预应力悬挂桁架在没有大刚度梁的情况下提供所需刚度的优势,以及交叉层压木材在两个方向上表现的能力,在分析的结构中得到了结合。在考虑的悬索桥结构中,仅考虑跨度主索、稳定索和竖向吊杆中心点重合(含义不清,难以平移)的预应力索特拉斯作为主要承载系统。两个数值模型评估了交叉层合板对预应力索特拉斯性能的影响。为了验证数值模型,开发了两个跨度等于2m的结构物理模型。第一个物理模型是针对这种情况开发的,当甲板的面板在没有间隙的情况下放置,并且在压缩时沿纵向表现,在弯曲时沿横向表现。第二个物理模型是针对甲板面板放置有间隙且仅在横向方向上弯曲的情况而开发的。得到了在对称和不对称荷载作用下,索特拉斯的最大竖向位移和水平支撑反作用力与竖向荷载强度的关系。说明了通过考虑预应力索桁架和交叉层压木板的组合工作,将特拉斯索材料消耗减少17%的可能性。
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Prediction of Behaviour of Prestressed Suspension Bridge with Timber Deck Panels
Cable truss usage allows developing bridges with reduced requirements for girder stiffness, where overall bridge rigidity is ensured by prestressing of the stabilization cable. The advantages of prestressed suspension trusses to provide required stiffness without massive stiffness girders and the ability of cross-laminated timber to behave in both directions are combined in the analysed structure. Prestressed cable truss with coincident (unclear meaning, difficult to translate) in the centre point of the span main and stabilization cables and vertical suspenders only was considered as the main load carrying system in the considered structure of suspension bridge. Two numerical models evaluated influence of cross-laminated timber deck on the behaviour of prestressed cable truss. Two physical models of the structure with the span equal to 2 m were developed for verification of the numerical models. The first physical model was developed for the case, when panels of the deck are placed without clearances and behaving in the longitudinal direction in compression so as in the transversal direction in bending. The second physical model was developed for the case when panels of the deck are placed with clearances and are behaving in the transverse direction in bending only. The dependences of maximum vertical displacements and horizontal support reaction of the cable truss on the intensity of vertical load in cases of symmetric and unsymmetrical loading were obtained for both physical models. Possibility to decrease the cable truss materials consumption by 17% by taking into account combined work of prestressed cable trusses and cross-laminated timber panels was stated.
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来源期刊
Baltic Journal of Road and Bridge Engineering
Baltic Journal of Road and Bridge Engineering 工程技术-工程:土木
CiteScore
2.10
自引率
9.10%
发文量
25
审稿时长
>12 weeks
期刊介绍: THE JOURNAL IS DESIGNED FOR PUBLISHING PAPERS CONCERNING THE FOLLOWING AREAS OF RESEARCH: road and bridge research and design, road construction materials and technologies, bridge construction materials and technologies, road and bridge repair, road and bridge maintenance, traffic safety, road and bridge information technologies, environmental issues, road climatology, low-volume roads, normative documentation, quality management and assurance, road infrastructure and its assessment, asset management, road and bridge construction financing, specialist pre-service and in-service training;
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