|本期目录/Table of Contents|

[1]李 明,王浩然,赵唯坚.单向带抗剪键叠合板的力学性能及设计方法[J].建筑科学与工程学报,2019,36(06):35-45.
 LI Ming,WANG Hao-ran,ZHAO Wei-jian.Mechanical Properties and Design Method of One-way Laminated Slab with Shear Keys[J].Journal of Architecture and Civil Engineering,2019,36(06):35-45.
点击复制

单向带抗剪键叠合板的力学性能及设计方法(PDF)
分享到:

《建筑科学与工程学报》[ISSN:1673-2049/CN:61-1442/TU]

卷:
36卷
期数:
2019年06期
页码:
35-45
栏目:
出版日期:
2019-11-25

文章信息/Info

Title:
Mechanical Properties and Design Method of One-way Laminated Slab with Shear Keys
文章编号:
1673-2049(2019)06-0035-11
作者:
李 明,王浩然,赵唯坚
(沈阳建筑大学 土木工程学院,辽宁 沈阳 110168)
Author(s):
LI Ming, WANG Hao-ran, ZHAO Wei-jian
(School of Civil Engineering, Shenyang Jianzhu University, Shenyang 110168, Liaoning, China)
关键词:
叠合板 抗剪键 静载试验 力学性能 抗弯承载力 屈服位移 简化计算式
Keywords:
laminated slab shear key static load test mechanical property bending capacity yield displacement simplified calculation equation
分类号:
TU375.2
DOI:
-
文献标志码:
A
摘要:
针对现有钢筋桁架叠合板钢筋用量多、成本偏高的不足,提出了一种新型带混凝土抗剪键的叠合板,并通过对1块现浇板和6块叠合板的静力加载试验,分析了有无抗剪键、抗剪键沿横向个数和抗剪键结构形式对叠合板力学性能的影响。采用有限元软件ABAQUS模拟了试验中部分试件的受力过程,验证了有限元模拟方法的可行性。结果表明:与无抗剪键叠合板相比,设置一定数量抗剪键的叠合板和现浇板力学性能相近; 抗剪键个数越多,叠合板的极限承载力与现浇板越接近,其破坏特征也与现浇板基本相同; 不同结构形式的抗剪键均能保证预制底板与现浇层间的有效连接; 预制底板与现浇层的接触面间采用绑定接触时有限元模拟结果与试验结果更加接近; 考虑到结构设计的可靠性,在有限元模拟过程中,当叠合板的预制底板与现浇层间设置为摩擦接触时,改变抗剪键沿横向个数、抗剪键沿纵向个数和抗剪键截面面积,叠合板的屈服荷载和屈服位移均发生变化,但当三者增加到一定程度时,变化趋势不再明显; 改变现浇层混凝土强度等级、抗剪键混凝土强度等级和接触面摩擦因数,叠合板的屈服荷载和屈服位移基本未发生变化; 建立了带抗剪键叠合板的抗弯承载力和屈服位移简化计算式。
Abstract:
In view of the shortcomings of large amount of reinforcement and high cost for existing laminated slabs of reinforced truss, a new type of laminated slab with concrete shear keys was proposed. The effects of shear keys, number of shear keys along the transverse direction and structural forms of shear keys on the mechanical properties of laminated slabs were analyzed through static loading tests on one cast-in-place slab and six laminated slabs. In addition, the finite element software ABAQUS was used to simulate the stress process of some specimens in the test, which verified the feasibility of the finite element simulation method. Finally, the simplified calculation equations for the bending capacity and the yield displacement of the laminated slab with shear keys were established. The results show that the mechanical properties of the laminated slab with a certain number of shear keys are similar to those of the cast-in-place slab compared with the laminated slab without shear keys. The more the shear keys in number are put, the closer the ultimate bearing capacity of the laminated slab is to that of the cast-in-place slab, and it has almost the same failure characteristics as the cast-in-place slab. The shear keys of different structural forms can ensure effective connection between the prefabricated base plate and the cast-in-place layer. When the tie contact is used between the prefabricated base plate and the cast-in-place layer, the finite element simulation results are closer to the test results. When the friction contact is used between the prefabricated base plate and the cast-in-place layer in the finite element simulation process considering the reliability of structural design, the change of the number of shear keys along the transverse direction and the longitudinal direction and the section area of shear keys enables the change of both the yielding load and the yielding displacement of the laminated slab. However, when the three increase to a certain extent, the change trend is no longer obvious. When the strength grade of cast-in-place layer concrete, the strength grade of shear key concrete and the friction coefficient of surface are changed, the yielding load of the laminated slab and the displacement are basically unchanged.

参考文献/References:

[1] 曹诗定,王 伟.装配式建筑优点、技术难点剖析与监管重点探索[J].工程质量,2015,33(11):24-27.
CAO Shi-ding,WANG Wei.Advantages and Technical Difficulties and Emphases of Supervision of Assembly Building Projects[J].Construction Quality,2015,33(11):24-27.
[2]COOK J P.Composite Structure Methods[M].New York:McGraw-Hill Book Company Inc,1976.
[3]DAVID C S,AMIN E.Partially Composite Sandwich Panel Deflections[J].Journal of Structural Engineering,1995,121(4):778-783.
[4]BOZZO L M,TORRES L.A Proposed Semi-prefabricated Prestressed Composite Steel-Concete Slab[J].Structures and Buildings,2004,157(5):309-317.
[5]REDZUAN A W,SAMUEL E.Determination of Composite Slab Strength Using a New Elemental Test Method[J].Journal of Structural Engineering,2007,133(9):1268-1277.
[6]LUDOVICO M D,PROTA A,MANFREDI G,et al.FRP Strengthening of Full-scale PC Girders[J].Journal of Composites for Construction,2010,14(5):510-520.
[7]朱茂存,刘宗仁,陈忠汉.预应力混凝土夹芯叠合板的性能分析[J].混凝土与水泥制品,2001(5):47-49.
ZHU Mao-cun,LIU Zong-ren,CHEN Zhong-han.Performance Analysis on the Prestressed Concrete Sandwich Laminated Slab[J].China Concrete and Cement Products,2001(5):47-49.
[8]李耀庄,蒋青青,黄赛超,等.混凝土倒T形叠合连续板的试验研究[J].中南大学学报:自然科学版,2003,34(6):695-698.
LI Yao-zhuang,JIANG Qing-qing,HUANG Sai-chao,et al.Experimental Study on the RC Invertible T Slab-continuous Composite Slab[J].Journal of Central South University:Science and Technology,2003,34(6):695-698.
[9]郭乐工,郭乐宁,杨艳春.预应力混凝土叠合板与薄板抗弯承载力相关关系分析[J].哈尔滨工业大学学报,2005,37(10):1440-1441.
GUO Le-gong,GUO Le-ning,YANG Yan-chun.Correlation Model of Bending Bearing Capacity Between Prestressed Slab and Laminated Slabs[J].Journal of Harbin Institute of Technology,2005,37(10):1440-1441.
[10]周绪红,张微伟,吴方伯,等.预应力混凝土四边简支双向叠合板的设计方法[J].建筑科学与工程学报,2006,23(4):54-57,94.
ZHOU Xu-hong,ZHANG Wei-wei,WU Fang-bo,et al.Design Method of Prestressed Concrete Simply Supported on Four Sides of Two Way Composite Slab[J].Journal of Architecture and Civil Engineering,2006,23(4):54-57,94.
[11]岳建伟,彭燕伟,魏 锟.带肋预应力叠合板在钢结构中的应用[J].建筑技术,2010,41(12):1090-1093.
YUE Jian-wei,PENG Yan-wei,WEI Kun.Application of Precast Composite Slab with Trough in Steel Structure[J].Architecture Technology,2010,41(12):1090-1093.
[12]朱永明,高 歌,肖建庄.再生混凝土叠合板受弯力学性能试验[J].混凝土与水泥制品,2012(6):49-52.
ZHU Yong-ming,GAO Ge,XIAO Jian-zhuang.Bending Mechanical Properties Test of Recycled Concrete composite Slab[J].China Concrete and Cement Products,2012(6):49-52.
[13]陈 东,沈小璞.带桁架钢筋的混凝土双向自支承叠合板受力机理研究[J].建筑结构,2015,45(15):93-96.
CHEN Dong,SHEN Xiao-pu.Study on Loading Mechanism of Bidirectional Self-supporting Concrete Composite Plates with Truss Rebar[J].Building Structure,2015,45(15):93-96.
[14]吴方伯,付 伟,文 俊,等.新型叠合板拼缝构造静载试验[J].建筑科学与工程学报,2018,35(4):1-10.
WU Fang-bo,FU Wei,WEN Jun,et al.Static Load Experiment of New Type of Laminated Plate Joint Structure[J].Journal of Architecture and Civil Engineering,2018,35(4):1-10.
[15]刘立新,于 春,栾文彬,等.预制混凝土叠合板的无筋叠合面抗剪性能试验研究[J].建筑施工,2013,35(1):80-82.
LIU Li-xin,YU Chun,LUAN Wen-bin,et al.Test Study on Shear-resisting Performance of Precast Concrete Composite Slab with Unreinforced Composite Surface[J].Building Construction,2013,35(1):80-82.
[16]JGJ 1—2014,装配式混凝土结构技术规程[S].
JGJ 1—2014,Technical Specification for Precast Concrete Structures[S].
[17]汤 磊,郭正兴,丁桂平.新型钢筋桁架混凝土叠合双向板刚度和挠度计算方法研究[J].建筑结构,2013,43(19):30-32.
TANG Lei,GUO Zheng-xing,DING Gui-ping.Research on Calculation Method of Stiffness and Deflection of the New Steel Bar Truss Concrete Superimposed Two-way Slab[J].Building Structure,2013,43(19):30-32.
[18]商忠韬,凤俊敏,顾 艳,等.新型预制预应力钢筋桁架翼缘加劲肋叠合双向板试验研究[J].施工技术,2015,4(21):60-63,67.
SHANG Zhong-tao,FENG Jun-min,GU Yan,et al.Experimental Analysis on the Prestressed Two-way Composite Slab with Steel Truss Flange Ribbed Panels[J].Construction Technology,2015,4(21):60-63,67.
[19]王立国.带抗剪键叠合板的力学性能及影响因素研究[D].沈阳:沈阳建筑大学,2015.
WANG Li-guo.Study on Mechanical Behavior of Laminated Slab with Shear Connectors[D].Shenyang:Shenyang Jianzhu University,2015.
[20]GB/T 50152—2012,混凝土结构试验方法标准[S].
GB/T 50152—2012,Standard for Test Method of Concrete Structures[S].
[21]蒋昭奕.叠合面粘结程度对混凝土叠合板承载性能影响研究[D].杭州:浙江工业大学,2017.
JIANG Zhao-yi.Study on the Influence of the Bonding Degree of the Overlapped Surface on the Bearing Performance of the Concrete Laminated Plate[D].Hangzhou:Zhejiang University of Technology,2017.
[22]陈富强,田 唯,刘占国,等.匹配浇筑混凝土接触面摩擦系数试验研究[J].中国港湾建设,2014(12):34-38.
CHEN Fu-qiang,TIAN Wei,LIU Zhan-guo,et al.Experimental Study on Friction Coefficient of Concrete with Matching Pouring Surface[J].China Harbour Engineering,2014(12):34-38.

相似文献/References:

[1]吴方伯,付 伟,文 俊,等.新型叠合板拼缝构造静载试验[J].建筑科学与工程学报,2018,35(04):1.
 WU Fang-bo,FU Wei,WEN Jun,et al.Static Load Experiment of New Type of Laminated Plate Joint Structure[J].Journal of Architecture and Civil Engineering,2018,35(06):1.
[2]谷 倩,雷晓天,黄 超,等.页岩陶粒轻质混凝土双向叠合楼板[J].建筑科学与工程学报,2018,35(06):102.
 GU Qian,LEI Xiao-tian,HUANG Chao,et al.Mechanical Performance Test and Deflection Calculation Analysis of Shale Ceramsite Lightweight Concrete Two-way Composite Floor Slab[J].Journal of Architecture and Civil Engineering,2018,35(06):102.
[3]吴方伯,秦 浩,文 俊,等.新型叠合板力学性能试验[J].建筑科学与工程学报,2020,37(01):33.[doi:10.19815/j.jace.2019.02026]
 WU Fang-bo,QIN Hao,WEN Jun,et al.Mechanical Properties Test of New Type of Laminated Slab[J].Journal of Architecture and Civil Engineering,2020,37(06):33.[doi:10.19815/j.jace.2019.02026]

备注/Memo

备注/Memo:
收稿日期:2018-12-21
基金项目:国家自然科学基金项目(51278312); “十三五”国家重点研发计划项目(2016YFC0701402)
作者简介:李 明(1979-),男,辽宁沈阳人,副教授,工学博士,博士后,E-mail:297531635@qq.com。
更新日期/Last Update: 2019-11-26