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长安大学学报（自然科学版）[ISSN:1006-6977/CN:61-1281/TN]

Issue:

2023年1期

Page:

30-38

Research Field:

道路工程

Publishing date:

Info

Title:

Mechanical behavior and verification of horizontal through-hole hoisting of precast concrete pavement slab

Author(s):

KE Wen-hui¹;  ZHOU Ran²;  FANG Ming-jing²;  CHEN Yi-ming²;  WANG Xiao²

(1. Wuhan Municipal Construction Group Co., Ltd., Wuhan 430023, Hubei, China; 2. School of Civil Engineering and Architecture, Wuhan University of Technology, Wuhan 430070, Hubei, China)

Keywords:

road engineering;  prefabricated pavement;  precast concrete slab;  hoisting;  mechanical behavior;  numerical analysis;  test verification

PACS:

U416.216

DOI:

10.19721/j.cnki.1671-8879.2023.01.004

Abstract:

Because of the problems that the traditional embedded hanger cannot be well met by the geometric continuity and reusable of the prefabricated concrete pavement, a new type of through-hole hoisting method, namely the horizontal extended steel grid method was proposed to hoist the pavement slabs. The feasibility of this method was verified by the strain response of different reinforced concrete pavement slabs. The finite element analysis program ABAQUS and the test data were used to establish and verify the three-dimensional(3D)numerical model of the slab, respectively, and the mechanical behavior of horizontal through-hole hoisting for precast concrete slabs was analyzed. The results show that when the concrete slab with the size of 3.5 m(length)×3 m(width)×0.22 m(height)is hoisted with four-point through holes, the reinforcement ratios of hoisting direction and vertical hoisting direction decreased from 0.409% and 0.292% to 0.221% and 0.189%(ultimate reinforcement), respectively, results in about 30×10^-6 strains generated at the bottom and top of the slab under the action of self-weight load and normal hosting speed. The pavement slab concrete during the whole hoisting process is in the elastic deformation stage without cracking. The slab’s inner stress caused by the through-hole hoisting is positively correlated with the hoisting distance and the slab size, and the stress concentration of concrete and steel bars at the lifting point is significant. To prevent stress concentration-induced concrete cracking, the locally densified steel mesh in the stress concentration area and the thicker steel bar(such as diameter of rebar is Φ28)as the main reinforcement for hoisting are recommended to reduce the concentrated stress at the occlusion part of the steel bar and concrete. Meanwhile, the long side of the slab as the hoisting edge and lifting distance less than 4.0 m are also preferentially encouraged. Moreover, if necessary to reduce the reinforcement of the slab when adopting the through-hole hoisting method, the rebar in the vertical hoisting direction is preferentially considered first. This research provides a reference for the structural dimensions design, rebar arrangement, and lifting point layout of prefabricated pavement slabs and similar precast concrete components using the through-hole horizontal hoisting method.2 tabs, 13 figs, 22 refs.

References:

[1] HWANG B G,SHAN M,LOOI K Y.Key constraints and mitigation strategies for prefabricated prefinished volumetric construction[J].Journal of Cleaner Production,2018,183:183-193.
[2]GB 50010—2010,混凝土结构设计规范[S].
GB 50010—2010,Gode for design of concrete structures[S].
[3]孟宪宏,张斯远,谷 立.国内预埋吊件应用现状及国内外相关规范对比分析[J].施工技术,2017,46(3):38-40.
MENG Xian-hong,ZHANG Si-yuan,GU Li.Application status of domestic embedded hanging parts and comparative analysis of relevant standard between domestic and international[J].Construction Technology,2017,46(3):38-40.
[4]吴焕娟,黄清杰,蒋勤俭,等.大型预制柱吊装技术研究[J].混凝土与水泥制品,2018(12):75-80.
WU Huan-juan,HUANG Qing-jie,JIANG Qin-jian,et al.Research on lifting technology of large precast column[J].China Concrete and Cement Products,2018(12):75-80.
[5]张亚楠,尤克泉,孔兰兰,等.新型层间抱柱式悬臂吊装施工安全性探究[J].结构工程师,2019,35(5):206-211.
ZHANG Ya-nan,YOU Ke-quan,KONG Lan-lan,et al.Study on the safety of an innovative fast construction method using on-column crane facility[J].Structural Engineers,2019,35(5):206-211.
[6]周光毅,宫立宝,王佳斌,等.装配式混凝土结构停车楼吊装施工技术[J].施工技术,2016,45(4):31-34.
ZHOU Guang-yi,GONG Li-bao,WANG Jia-bin,et al.Hoisting construction technology of the precast concrete parking building[J].Construction Technology,2016,45(4):31-34.
[7]汪中林,周 仪,肖桃李,等.装配式建筑异形PC构件吊装技术分析[J].混凝土,2019(3):140-142.
WANG Zhong-lin,ZHOU Yi,XIAO Tao-li,et al.Analysis on hoisting technology of special-shaped precast concrete component with fabricated buildings[J].Concrete,2019(3):140-142.
[8]左学兵,雷翔栋.山东海阳核电站大型结构模块吊装重心计算及配平[J].施工技术,2012,41(15):29-31.
ZUO Xue-bing,LEI Xiang-dong.Calculation of the center of gravity and design of the balance scheme for the large structural modules in Haiyang Nuclear Power Station in Shandong[J].Construction Technology,2012,41(15):29-31.
[9]于喜年,杨盈彧,王建国.某核电厂混凝土底板模块化吊装设计及应用[J].核动力工程,2013,34(6):132-135.
YU Xi-nian,YANG Ying-yu,WANG Jian-guo.Design and application of concrete floor modular hoisting in nuclear power plants[J].Nuclear Power Engineering,2013,34(6):132-135.
[10]赵国辉,谢兰敏,金玲玲.超大PC构件起吊结构分析[J].建筑结构,2016,46(增2):188-190.
ZHAO Guo-hui,XIE Lan-min,JIN Ling-ling.A hoisting method analysis of large prefabricated shear wall[J].Building Structure,2016,46(S2):188-190.
[11]冯国祥,蒋勤俭,吴焕娟.大跨度预制梁吊装应力分析及预埋吊件选用方法研究[J].混凝土,2018(10):127-131.
FENG Guo-xiang,JIANG Qin-jian,WU Huan-juan.Hoisting stress analysis of large-span precast beam and study on selection method of embedded hanger[J].Concrete,2018(10):127-131.
[12]孟宪宏,戴承良,吕雪源,等.专用预埋吊件在大型预制看台板中的应用研究[J].施工技术,2019,48(6):45-47.
MENG Xian-hong,DAI Cheng-liang,LU Xue-yuan,et al.Application research of dedicated pre-buried lifting member for prefabricated platform boards[J].Construction Technology,2019,48(6):45-47.
[13]尹锦明,姜 毅,韩光义.装配式水泥混凝土路面板块吊装应力分析[J].施工技术,2015,44(增1):393-396.
YIN Jin-ming,JIANG Yi,HAN Guang-yi.Stress analysis of fabricated cement concrete pavement slab in the process of lifting[J].Construction Technology,2015,44(S1):393-396.
[14]叶浩文,周 冲.装配式建筑的设计-加工-装配一体化技术[J].施工技术,2017,46(9):17-19.
YE Hao-wen,ZHOU Chong.Design,processing and assembly integration technology of precast buildings[J].Construction Technology,2017,46(9):17-19.
[15]郑艺杰,张 晋,尹万云,等.装配整体式剪力墙结构构件吊装分析[J].施工技术,2015,44(增1):572-576.
ZHENG Yi-jie,ZHANG Jin,YIN Wan-yun,et al.Lifting analysis of prefabricated shear wall structural components[J].Construction Technology,2015,44(S1):572-576.
[16]姚一辰,韩普各.钢筋桁架混凝土叠合板底板吊装受力性能分析[J].混凝土与水泥制品,2020(9):62-67.
YAO Yi-chen,HAN Pu-ge.Analysis of mechanical performance of reinforced concrete composite slabs with steel-bar truss[J].China Concrete and Cement Products,2020(9):62-67.
[17]SYED AMEEN,SONPAROTE RANJAN-S.Construction of pretensioned precast concrete pavement[J].Iranian Journal of Science and Technology,Transactions of Civil Engineering,2020,44(S1):507-514.
[18]ASHTIANI R S,JACKSON C J,SAEED A,et al.Precast concrete panels for conyingency rigid airfield pavement damage repairs[R].Panama City:Applied Research Associates,2010.
[19]FANG M J,ZHOU R,KE W H,et al.Precast system and assembly connection of cement concrete slabs for road pavement:A review[J].Journal of Traffic and Transportation Engineering(English Edition),2022,9(2):208-222.
[20]陈伟光,李 浩,郭志鑫,等.大尺寸预制板吊点最优布设方式的探讨[J].施工技术,2018,47(增1):1649-1652.
CHEN Wei-guang,LI Hao,GUO Zhi-xin,et al.Discussion on optimal lifting points of large-size prefabricated slab[J].Construction Technology,2018,47(S1):1649-1652.
[21]方自虎,周海俊,赖少颖,等.ABAQUS混凝土应力-应变关系选择[J].建筑结构,2013,43(增2):559-562.
FANG Zi-hu,ZHOU Hai-jun,LAI Shao-ying,et al.Choose of ABAQUS concrete stress-strain curve[J].Building Structure,2013,43(S2):559-562.
[22]曾 宇,胡良明.ABAQUS混凝土塑性损伤本构模型参数计算转换及校验[J].水电能源科学,2019,37(6):106-109.
ZENG Yu,HU Liang-ming.Calculation transformation and calibration of ABAQUS concrete plastic damage constitutive model[J].Water Resources and Power,2019,37(6):106-109.

Memo

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Common functions

Last Update: 2023-01-30