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

Issue:

2020年01期

Page:

33-40

Research Field:

Publishing date:

Info

Title:

Mechanical Properties Test of New Type of Laminated Slab

Author(s):

WU Fang-bo¹;  QIN Hao¹;  WEN Jun¹;  LI Bo¹;  ZHOU Xu-hong¹; 2

(1. College of Civil Engineering, Hunan University, Changsha 410082, Hunan, China; 2. School of Civil Engineering, Chongqing University, Chongqing 400045, China)

Keywords:

laminated slab;  mechanical property;  four-point loading;  deflection;  bearing capacity

PACS:

TU311

DOI:

10.19815/j.jace.2019.02026

Abstract:

In order to analyze the performance of laminated slab in service, such as deflection, stress-strain curve of steel bars, the static loading test of a cast-in-place slab and a new type of laminated slab was carried out. In the test, the large reaction frame, a hydraulic jack and a two-stage distribution beam were used as loading tools for four-point loading on the composite simply supported slab with detachable truss and the cast-in-place simply supported slab to simulate the stress state of the slab under uniform load, and the test data were compared. The results show that the deflection of the laminated slab meets the requirements of the use stage, and the ductility is good. At the end of the final loading, the cracks of the laminated slab is similar to the cast-in-place two-way slab. The cracks at the bottom of the slab first appear below the four loading points, and with the subsequent loading from four loading points to four corners of the laminated slab. The appearance of cracks indicates that the tensile properties of steel bars are fully utilized when the laminated slab are damaged. After the last stage of loading, the concrete on the top of the laminated slab is not crushed, this indicates that the laminated slab still has the capacity of continuous bearing. The bonding performance between the embedded parts and concrete is good, and the concrete around the embedded parts is not damaged in a large area. Several vertical cracks are found on the side of the component, and no transverse cracks are found on the laminated surface, which shows that the surface scratching can meet the shear requirements of the laminated surface.

References:

[1] 曾垂军,吴方伯,刘锡军,等.新型叠合结构体系的设计与施工[J].建筑科学,2006,22(4):67-71.
ZENG Chui-jin,WU Fang-bo,LIU Xi-jun,et al.Design and Construction of a New Type Composite Structure System[J].Building Science,2006,22(4):67-71.
[2]田国安.冷轧带肋钢筋混凝土叠合板试验研究[J].建筑结构,2000,30(1):35-37,29.
TIAN Guo-an.Experiment Research of Composite Floor with Cold-rolled Ribbed Steel Bars[J].Building Structure,2000,30(1):35-37,29.
[3]聂建国,陈必磊,陈 戈,等.钢筋混凝土叠合板的试验研究[J].工业建筑,2003,33(12):43-46,33.
NIE Jian-guo,CHEN Bi-lei,CHEN Ge,et al.Experimental Study on Shear Behavior of R.C.Laminated Slabs[J].Industrial Construction,2003,33(12):43-46,33.
[4]THANOON W A,YARDIN Y,JAAFAR M S,et al.Structural Behaviour of Ferrocement-brick Composite Floor Slab Panel[J].Construction and Building Materials,2010,24(11):2224-2230.
[5]EL-DARDIRY E,JI T.Modelling of the Dynamic Behaviour of Profiled Composite Floors[J].Engineering Structures,2006,28(4):567-579.
[6]REX C O,EASTERLING W S.Behavior and Modeling of Reinforced Composite Slab in Tension[J].Journal of Structural Engineering,2000,126(7):764-771.
[7]JEONG Y J.Simplified Model to Predict Partial-interactive Structural Performance of Steel-concrete Composite Slabs[J].Journal of Constructional Steel Research,2008,64(2):238-246.
[8]IZZUDDIN B A,TAO X Y,ELGHAZOULI A Y.Realistic Modeling of Composite and Reinforced Concrete Floor Slabs Under Extreme Loading.I:Analytical Method[J].Journal of Structural Engineering,2004,130(12):1972-1984.
[9]ELGHAZOULI A Y,IZZUDDIN B A.Realistic Modeling of Composite and Reinforced Concrete Floor Slabs Under Extreme Loading.II:Verification and Application[J].Journal of Structural Engineering,2004,130(12):1985-1996.
[10]刘汉朝,蒋青青.倒“T”形叠合简支板的试验研究[J].中南大学学报:自然科学版,2004,35(1):147-150.
LIU Han-chao,JANG Qing-qing.Experiment of Inverted “T” Simply Supported Composite Slab[J].Journal of Central South University:Natural Science,2004,35(1):147-150.
[11]李 杰,黄鹏飞,陈以一,等.无支撑钢筋桁架混凝土叠合板受力性能试验研究[J].结构工程师,2013,29(4):132-139.
LI Jie,HUANG Peng-fei,CHEN Yi-yi,et al.Experimental Research on Mechanical Properties of Self-sustaining Steel Bar Truss and Concrete Superposed Slab[J].Structural Engineers,2013,29(4):132-139.
[12]周鲲鹏.PK预应力双向叠合楼板的试验研究与应用[D].长沙:湖南大学,2006.
ZHOU Kun-peng.Experimental Study and Application of PK Prestressed Composite Two-way Slab[D].Changsha:Hunan University,2006.
[13]张微伟.PK预应力叠合楼板的试验研究与理论分析[D].长沙:湖南大学,2007.
ZHANG Wei-wei.Experimental Study and Theoretical Analysis of PK Prestressed Composite Slab[D].Changsha:Hunan University,2007.
[14]黄海林.预制带肋底板混凝土叠合楼板受力性能及设计方法[D].长沙:湖南大学,2013.
HUANG Hai-lin.Structural Behavior and Design Method of Concrete Composite Slab with Precast Prestressed Concrete Ribbed Panel[D].Changsha:Hunan University,2013.
[15]王元清,袁 霞,张延年,等.钢筋桁架混凝土双向叠合楼板承载性能分析[J].沈阳建筑大学学报:自然科学版,2014,30(3):385-391.
WANG Yuan-qing,YUAN Xia,Zhang Yan-nian,et al.Analysis of Loading Capacity of Steel Bar Truss and Concrete Superimposed Two-way Slab[J].Journal of Shenyang Jianzhu University:Natural Science,2014,30(3):385-391.
[16]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.
[17]丁克伟,陈 东,刘云林,等.一种新型拼缝结构的叠合板受力机理及试验研究[J].土木工程学报,2015,48(10):64-69.
DING Ke-wei,CHEN Dong,LIU Yun-lin,et al.Theoretical and Experimental Study on Mechanical Behavior of Laminated Slabs with New Type Joints[J].China Civil Engineering Journal,2015,48(10):64-69.
[18]左 瑞.免拆模混凝土梁的试验研究与分析[D].长沙:湖南大学,2017.
ZUO Rui.Experimental Study and Analysis on Free Demoulding Concrete Beams[D].Changsha:Hunan University,2017.
[19]吴方伯,左 瑞,文 俊,等.免拆模混凝土梁受弯性能试验[J].建筑科学与工程学报,2018,35(2):8-15.
WU Fang-bo,ZUO Rui,WEN Jun,et al.Experimental on Bending Performance of Concrete Beam Without Demoulding[J].Journal of Architecture and Civil Engineering,2018,35(2):8-15.
[20]GB/T 50152—2012,混凝土结构试验方法标准[S].
GB/T 50152—2012,Standard for Test Methods of Concrete Structures[S].

Memo

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Common functions

Last Update: 2020-01-13