«Previous Article|Table of Contents|Next Article»

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

Issue:

2023年03期

Page:

83-91

Research Field:

建筑结构

Publishing date:

Info

Title:

Design and stability study of UHPC-CA fabricated dry masonry retaining wall

Author(s):

WANG Qing¹; 2;  REN Xiaobin¹; 2;  WANG Huafeng¹; 2;  ZHOU Wanqing¹; 2

(1. Hubei Key Laboratory of Disaster Prevention and Mitigation, China Three Gorges University, Yichang 443002, Hubei, China; 2. College of Civil Engineering & Architecture, China Three Gorges University, Yichang 443002, Hubei, China)

Keywords:

dry masonry retaining wall;  ecological block;  model test;  stability;  finite element simulation;  UHPC-CA

PACS:

TU375.6

DOI:

10.19815/j.jace.2021.11015

Abstract:

A new type of fabricated hollow block was designed, and the block was made of ultra-high performance concrete mixed with coarse aggregate(UHPC-CA). The strength and durability of the dry masonry wall were improved compared with the traditional cast-in-situ retaining wall. The blocks were connected by trapezoidal tenon and groove, and the size and angle of tenon and groove were determined based on the friction self-locking principle. The stability of the new block dry masonry retaining wall was studied by means of model test, finite element simulation and theoretical analysis. The results show that the tenon and groove of the designed block are connected reliably, and no local damage caused by falling off between tenon and groove occurs. The integrity of retaining wall is good, and the anti overturning safety and stability of the new block dry masonry retaining wall can reach the same effect as the integral cast-in-situ retaining wall. The new retaining wall can be stacked in many ways, which is suitable for embankment, shoulder and other protection works of standard truck driving roads at all levels. The double row retaining wall can ensure that the trapezoidal tenon will not be damaged by shear. In addition, green plants can be planted in the filling hole of the block, which has great ecological benefits.

References:

[1] BONIC Z,DAVIDOVIC N,PROLOVIC V,et al.Experimental testing of retaining walls of precast elements[J].Applied Mechanics and Materials,2015,725-726:168-175.
[2]章宏生,沈振中,徐力群,等.新型装配扶壁式挡土墙结构特性有限元分析[J].南水北调与水利科技,2017,15(3):145-150,189.
ZHANG Hongsheng,SHEN Zhenzhong,XU Liqun,et al.Finite element analysis of the structural characteristics of new assembly buttressed retaining wall[J].South-to-North Water Transfers and Water Science & Technology,2017,15(3):145-150,189.
[3]刘 泽,何 矾,黄天棋,等.装配悬臂式挡土墙节点承载特性试验研究[J].公路交通科技,2020,37(9):25-33.
LIU Ze,HE Fan,HUANG Tianqi,et al.Experimental study on joint bearing characteristics of prefabricated cantilever retaining wall[J].Journal of Highway and Transportation Research and Development,2020,37(9):25-33.
[4]BUI T T,BOST M,LIMAM A,et al.Modular precast concrete facing for soil-nailed retaining walls:laboratory study and in situ validation[J].Innovative Infrastructure Solutions,2020,5(1):1.
[5]刘曙光,方 琦,钟桂辉,等.新型装配式悬臂混凝土挡土墙承载性能试验[J].同济大学学报(自然科学版),2020,48(7):937-944,952.
LIU Shuguang,FANG Qi,ZHONG Guihui,et al.Experimental investigation on bearing capacity of novel precast cantilever concrete retaining wall[J].Journal of Tongji University(Natural Science),2020,48(7):937-944,952.
[6]蒋梅东.装配式挡土墙结构设计与试验研究[D].湘潭:湖南科技大学,2017.
JIANG Meidong.Structural design and experimental study of assembled retaining wall[D].Xiangtan:Hunan University of Science and Technology,2017.
[7]陈桂奇,王保田,王永安,等.自锁式景观砌块加筋挡土结构的设计与应用[J].水利水电科技进展,2007,27(3):57-59.
CHEN Guiqi,WANG Baotian,WANG Yongan,et al.Principle and application of self-locked scenic granitiform reinforced concrete block retaining wall[J].Advances in Science and Technology of Water Resources,2007,27(3):57-59.
[8]LING H I,YANG S T,LESHCHINSKY D,et al.Finite-element simulations of full-scale modular-block reinforced soil retaining walls under earthquake loading[J].Journal of Engineering Mechanics,2010,136(5):653-661.
[9]LATHA G M,SANTHANAKUMAR P.Seismic response of reduced-scale modular block and rigid faced reinforced walls through shaking table tests[J].Geotextiles and Geomembranes,2015,43(4):307-316.
[10]韩晓云.路堤边坡绿化装配式挡土墙的稳定性分析[D].成都:西南交通大学,2019.
HAN Xiaoyun.Afforesting prefabricated retaining wall on embankment slope stability analysis[D].Chengdu:Southwest Jiaotong University,2019.
[11]YU Y,BATHURST R J,ALLEN T M.Numerical modeling of the SR-18 geogrid reinforced modular block retaining walls[J].Journal of Geotechnical and Geoenvironmental Engineering,2016,142(5):04016 003.
[12]李 聪,陈宝春,韦建刚.粗集料UHPC收缩与力学性能[J].交通运输工程学报,2019,19(5):11-20.
LI Cong,CHEN Baochun,WEI Jiangang.Shrinkage and mechanical properties of UHPC with coarse aggregate[J].Journal of Traffic and Transportation Engineering,2019,19(5):11-20.
[13]李力剑,徐礼华,池 寅,等.含粗骨料超高性能混凝土单轴受压疲劳性能[J].建筑材料学报,2022,25(4):381-388.
LI Lijian,XU Lihua,CHI Yin,et al.Fatigue performance of ultra-high performance concrete containing coarse aggregate under uniaxial cyclic compression[J].Journal of Building Materials, 2022,25(4):381-388.
[14]杨凤玲,嵇银行,刘 伟,等.含粗骨料超高性能混凝土的试验研究[J].混凝土,2018(12):110-113.
YANG Fengling,JI Yinhang,LIU Wei,et al.Experimental study on ultra-high-performance concrete with coarse aggregate[J].Concrete,2018(12):110-113.
[15]活性粉末混凝土:GB/T 31387—2015[S].北京:中国标准出版社,2015.
Reactive powder concrete:GB/T 31387—2015[S].Beijing:Standards Press of China,2015.
[16]BARR B.Compact shear test specimens for FRC materials[J].Composites,1987,18(1):54-60.
[17]沈蒲生.混凝土结构设计原理[M].3版.北京:高等教育出版社,2007.
SHEN Pusheng.Design principle of concrete structure[M].3rd ed.Beijing:Higher Education Press,2007.
[18]姚 燕,李功洲,高春勇,等.大于C80混凝土轴心抗压强度设计值取值的探讨[J].煤炭工程,2015,47(1):110-111,114.
YAO Yan,LI Gongzhou,GAO Chunyong,et al.Discussion on design value selection of axial compressive strength of over C80 concrete[J].Coal Engineering,2015,47(1):110-111,114.
[19]段淑敏,孔艳平.摩擦中的自锁现象[J].力学与实践,2004,26(5):81-83.
DUAN Shumin,KONG Yanping.Self-locking phenomenon in friction[J].Mechanics and Engineering,2004,26(5):81-83.
[20]应宏伟,郑贝贝.砂土中刚性挡墙不同主动变位模式任意位移土压力计算[J].工程力学,2012,29(11):243-249.
YING Hongwei,ZHENG Beibei.Earth pressures on rigid retaining walls in sandy soil with different active movement modes under arbitrary deformation[J].Engineering Mechanics,2012,29(11):243-249.
[21]尉希成.支挡结构设计手册[M].北京:中国建筑工业出版社,1995.
YU Xicheng.Handbook of retaining structure design[M].Beijing:China Architecture & Building Press,1995.
[22]建筑边坡工程技术规范:GB 50330—2013[S].北京:中国建筑工业出版社,2014.
Technical code for building slope engineering:GB 50330—2013[S].Beijing:China Architecture & Building Press,2014.
[23]建筑地基基础设计规范:GB 50007—2011[S].北京:中国计划出版社,2012.
Code for design of building foundation:GB 50007—2011[S].Beijing:China Planning Press,2012.
[24]马 巍,王大雁.冻土力学[M].北京:科学出版社,2014.
MA Wei,WANG Dayan.Mechanics of frozen ground[M].Beijing:Science Press,2014.
[25]HAMOUSH.Freezing and thawing durability of very high strength concrete[J].American Journal of Engineering and Applied Sciences,2011,4(1):42-51.

Memo

Memo:

-

Common functions

Last Update: 2023-05-20