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

Issue:

2020年03期

Page:

1-9

Research Field:

Publishing date:

Info

Title:

Analysis of Dynamic Response of Progressive Collapse for RC Frame Substructure

Author(s):

YI Wei-jian;  HUANG Yi-mou

(College of Civil Engineering, Hunan University, Changsha 410082, Hunan, China)

Keywords:

progressive collapse;  rapid removal of middle column;  failure time;  load on beam;  dynamic increase factor

PACS:

TU973.2

DOI:

10.19815/j.jace.2019.05028

Abstract:

Numerical simulation analyses for dynamic test and static test of reinforced concrete beam-column substructures were conducted using Explicit and Standard modules of ABAQUS finite element software, respectively, and the correctness of the model was verified. Then, based on the original dynamic test, further calculations were carried out to analyze the influence of failure time of middle column and load on beam on the dynamic response of the residual structure. In order to obtain the displacement of middle column under different static loads, the dynamic test specimen was also loaded with static load, so the dynamic increase factor could be obtained, which equaled to the ratio of dynamic displacement to static displacement, then the effect of failure time and load value on the dynamic increase factor was discussed. The results show that when the failure time gets shorter, the maximum vertical displacement and amplitude of middle column will get larger; the dynamic increase factor decreases with increase of failure time. The maximum displacement of middle column increases as the load on beam increases, when the load exceeds a certain value, the displacement will continue to divergence with time, this critical load can be called dynamic ultimate bearing capacity of the residual structure, according to analysis, the ultimate bearing capacity of the residual structure increases with the increase of failure time of middle column; the load on beam has little influence on dynamic increase factor.

References:

[1] SASANI M,BAZAN M,SAGIROGLU S.Experimental and Analytical Progressive Collapse Evaluation of Actual Reinforced Concrete Structure[J].ACI Structural Journal,2007,104(6):731-739.
[2]何庆锋.钢筋混凝土框架结构抗倒塌性能试验研究[D].长沙:湖南大学,2009.
HE Qing-feng.Research on Progressive Collapse Behavior of RC Frame Structures[D].Changsha:Hunan University,2009.
[3]TIAN Y,SU Y.Dynamic Response of Reinforced Concrete Beams Following Instantaneous Removal of a Bearing Column[J].International Journal of Concrete Structures and Materials,2011,5(1):19-28.
[4]KAI Q,LI B.Dynamic Performance of RC Beam-column Substructures Under the Scenario of the Loss of a Corner Column-experimental Results[J].Engineering Structures,2012,42:154-167.
[5]BALDRIDGE S M,HUMAY F K.Preventing Progressive Collapse in Concrete Buildings[J].Concrete International,2003,25(11):73-79.
[6]SASANI M,KROPELNICKI J.Progressive Collapse Analysis of an RC Structure[J].The Structural Design of Tall and Special Buildings,2008,17(4):757-771.
[7]高 超,宗周红,伍 俊.爆炸荷载下钢筋混凝土框架结构倒塌破坏试验研究[J].土木工程学报,2013,46(7):9-20.
GAO Chao,ZONG Zhou-hong,WU Jun.Experimental Study on Progressive Collapse Failure of RC Frame Structures Under Blast Loading[J].China Civil Engineering Journal,2013,46(7):9-20.
[8]周 媛,李付勇,王社良.钢筋混凝土框架抗连续倒塌的仿真分析[J].建筑科学与工程学报,2016,33(5):64-69.
ZHOU Yuan,LI Fu-yong,WANG She-liang.Simulation Analysis of Progressive Collapse of Reinforced Concrete Frames[J].Journal of Architecture and Civil Engineering,2016,33(5):64-69.
[9]STEVENS D,CROWDER B,SUNSHINE D,et al.DoD Research and Criteria for the Design of Buildings to Resist Progressive Collapse[J].Journal of Structural Engineering,2011,137(9):870-880.
[10]RUTH P,MARCHAND K A,WILLIAMSON E B.Static Equivalency in Progressive Collapse Alternate Path Analysis:Reducing Conservatism While Retaining Structural Integrity[J].Journal of Performance of Constructed Facilities,2006,20(4):349-364.
[11]AMIRI S,SAFFARI H,MASHHADI J.Assessment of Dynamic Increase Factor for Progressive Collapse Analysis of RC Structures[J].Engineering Failure Analysis,2018,84:300-310.
[12]杜永峰,包 超,李 慧,等.竖向不规则RC框架结构连续倒塌动力放大系数研究[J].四川大学学报:工程科学版,2015,47(2):43-49.
DU Yong-feng,BAO Chao,LI Hui,et al.Dynamic Increase Factor of Vertically Irregular RC Frame Structure in Progressive Collapse[J].Journal of Sichuan University:Engineering Science Edition,2015,47(2):43-49.
[13]GSA 2013,Alternate Path Analysis & Design Guidelines for Progressive Collapse Resistance[S].
[14]QIAN K,LI B,MA J X.Load-carrying Mechanism to Resist Progressive Collapse of RC Buildings[J].Journal of Structural Engineering,2015,141(2):04014107.
[15]SU Y P,TIAN Y,SONG X S.Progressive Collapse Resistance of Axially-restrained Frame Beams[J].ACI Structural Journal,2009,106(5):600-607.
[16]ABAQUS Inc.ABAQUS Analysis User's Manual V6.10[M].Palo Alto:ABAQUS Inc,2010.
[17]OTHMAN H,MARZOUK H.Finite-element Analysis of Reinforced Concrete Plates Subjected to Repeated Impact Loads[J].Journal of Structural Engineering,2017,143(9):04017120.
[18]GB 50010—2010,混凝土结构设计规范[S].
GB 50010—2010,Code for Design of Concrete Structures[S].
[19]田连波,侯建国.ABAQUS中混凝土塑性损伤因子的合理取值研究[J].湖北大学学报:自然科学版,2015,37(4):340-345,358.
TIAN Lian-bo,HOU Jian-guo.Reasonable Plastic Damaged Factor of Concrete Damaged Plastic Model of ABAQUS[J].Journal of Hubei University:Natural Science,2015,37(4):340-345,358.
[20]CEB-FIP,FIB Model Code 1990[S].
[21]MALVAR L J,ROSS C A.A Review of Strain Rate Effects for Concrete in Tension[J].ACI Materials Journal,1998,95(6):735-739.
[22]MALVAR L J.Review of Static and Dynamic Properties of Steel Reinforcing Bars[J].ACI Materials Journal,1998,95(5):609-616.
[23]GSA 2003,Progressive Collapse Analysis and Design Guidelines for New Federal Office Buildings and Major Modernization Projects[S].
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Memo

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Common functions

Last Update: 2020-06-08