Effect of Lightweight Aggregate with Water-Holding Capacity on Strength and Autogenous Shrinkage of Ultra-High Performance Concrete

Authors

FANG Chi, Da Hao Municipal Construction Co ., Ltd., Shantou ，Guangdong 515041 , ChinaFollow
YANG Weihao, Da Hao Municipal Construction Co ., Ltd., Shantou ，Guangdong 515041 , China
REN Kang, Da Hao Municipal Construction Co ., Ltd., Shantou ，Guangdong 515041 , China
ZHANG Jinghang, School of Civil and Environmental Engineering , Changsha University of Science & Technology , Changsha , Hunan 410114 , China
LYU Yigang, School of Civil and Environmental Engineering , Changsha University of Science & Technology , Changsha , Hunan 410114 , China
HUANG Dunwen, School of Civil and Environmental Engineering , Changsha University of Science & Technology , Changsha , Hunan 410114 , China
PENG Hui, School of Civil and Environmental Engineering , Changsha University of Science & Technology , Changsha , Hunan 410114 , ChinaFollow

Corresponding Author

彭晖，男，博士，教授.E-mail：huipeng@csust.edu.cn

Abstract

In response to the significant autog enous shrinkage issue of ultra-high performance concrete (UHPC ) under normal temperature curing,the influence of lightweight aggregates with water-holding capacity mixed with coarse aggregates on the compressive strength and autogenous shrinkage performance of UHPC was investigated.The mixing proportions of the two types of aggregates were optimized using the response surface method (RSM ).The results show that adequate amounts of basalt and volcanic rocks with water-holding capacity effectively reduce the shrinkage of UHPC.The rigid basalt restrains the shrinkage of the matrix,while volcanic rocks with water-holding capacity release moisture slowly,alleviating the autogenous drying effect and thus reducing shrinkage.However,an excessive amount of basalt and volcanic rocks leads to a decrease in the compressive strength of UHPC.This is because the coarse aggregates increase the transition zone between the matrix and coarse aggregates,resulting in fiber clustering,and the low strength of volcanic rocks makes it difficult to compensate for the degradation effect brought about by the transition zone.

Publication Date

4-10-2025

DOI

10.14048/j.issn.1671-2579.2025.02.007

First Page

65

Last Page

72

Submission Date

April 2025

Recommended Citation

Chi, FANG; Weihao, YANG; Kang, REN; Jinghang, ZHANG; Yigang, LYU; Dunwen, HUANG; and Hui, PENG (2025) "Effect of Lightweight Aggregate with Water-Holding Capacity on Strength and Autogenous Shrinkage of Ultra-High Performance Concrete," Journal of China & Foreign Highway: Vol. 45: Iss. 2, Article 7.
DOI: 10.14048/j.issn.1671-2579.2025.02.007
Available at: https://zwgl1980.csust.edu.cn/journal/vol45/iss2/7

Reference

[1]DE LARRARD F,SEDRAN T.Optimization of ultra-high-performance concrete by the use of a packing model [J].Cement and Concrete Research,1994,24(6):997-1009.
[2]覃维祖,曹峰.一种超高性能混凝土:活性粉末混凝土 [J].工业建筑,1999,29(4):16-18.QIN Weizu,CAO Feng.A new ultra-high performance concrete:Reactive powder concrete [J].Industrial Construction,1999,29(4):16-18.
[3]袁明,贺文杰,颜东煌,等.超高性能混凝土配合比优化研究[J].中外公路,2019,39(6):169-173.YUAN Ming,HE Wenjie,YAN Donghuang,et al.Investigation on optimizing mixing ratio of ultra-high performance concrete [J].Journal of China & Foreign Highway,2019,39(6):169-173.
[4]SHAO X D,YI D T,HUANG Z Y,et al.Basic performance of the composite deck system composed of orthotropic steel deck and ultrathin RPC layer [J].Journal of Bridge Engineering,2013,18(5):417-428.
[5]XUE C C,YU M,XU H M,et al.Experimental study on thermal performance of ultra-high performance concrete with coarse aggregates at high temperature [J].Construction and Building Materials,2022,314:125585.
[6]LU K W,XU Q Z,DU L P,et al.Fatigue performance of prefabricated coarse aggregate ultrahigh-performance concrete deck subjected to negative bending moment [J].Engineering Structures,2023,274:115098.[7]LIU Z,ALSOMIRI M,LI M,et al.Experimental investigation on the flexural behavior of coarse aggregate reactive powder concrete (CA-RPC ) bridge deck [J].Engineering Structures,2022,271:114951.
[8]AHMED S,AL-DAWOOD Z,ABED F,et al.Impact of using different materials,curing regimes,and mixing procedures on compressive strength of reactive powder concrete:A review [J].Journal of Building Engineering,2021,44:103238.
[9]YAZICI H,YARDIMCI M Y,AYDIN S,et al.Mechanical properties of reactive powder concrete containing mineral admixtures under different curing regimes [J].Construction and Building Materials,2009,23(3):1223 -1231.
[10]周腾,裴炳志,黄政宇,等.钢纤维掺量对 UHPC轴拉性能的影响 [J].中外公路,2022,42(5):120-124.ZHOU Teng,PEI Bingzhi,HUANG Zhengyu,et al.Effect of steel fiber content on tensile properties of UHPC [J].Journal of China & Foreign Highway,2022,42(5):120-124.
[11]SHI C J,WU Z M,XIAO J F,et al.A review on ultra high performance concrete:Part Ⅰ:Raw materials and mixture design [J].Construction and Building Materials,2015,101:741-751.
[12]WANG D H,SHI C J,WU Z M,et al.A review on ultra high performance concrete:Part Ⅱ:Hydration,microstructure and properties [J].Construction and Building Materials,2015,96:368-377.
[13]WANG J Q,LIU J P,WANG Z,et al.Cost-effective UHPC for accelerated bridge construction:Material properties,structural elements,and structural applications [J].Journal of Bridge Engineering,2021,26(2):04020117.
[14]陈宝春,李聪,黄伟,等.超高性能混凝土收缩综述 [J].交通运输工程学报,2018,18(1):13-28.CHEN Baochun,LI Cong,HUANG Wei,et al.Review of ultra-high performance concrete shrinkage [J].Journal of Traffic and Transportation Engineering,2018,18(1):13-28.
[15]李兵,杨腾宇,方昌乐,等.蒸养条件下超高性能混凝土收缩试验研究 [J].中外公路,2024,44(6):90-97.LI Bing,YANG Tengyu,FANG Changle,et al.Experimental investigation on shrinkage effect of ultra- high performance concrete under steam curing [J].Journal of China & Foreign Highway,2024,44(6):90-97.
[16]赵辛玮,肖汝诚,孙斌,等.常温养护型超高性能混凝土组合 桥 面 板 收 缩 性 能 研 究 [J].中 外 公 路,2020,40(3):100-108.ZHAO Xinwei,XIAO Rucheng,SUN Bin,et al.Study on shrinkage performance of composite bridge deck with ultra-high performance concrete cured in normal temperature [J].Journal of China & Foreign Highway,2020,40(3):100-108.
[17]SUN Y,YU R,SHUI Z H,et al.Understanding the porous aggregates carrier effect on reducing autogenous shrinkage of ultra-high performance concrete (UHPC ) based on response surface method [J].Construction and Building Materials,2019,222:130-141.
[18]YANG L,SHI C J,WU Z M.Mitigation techniques for autogenous shrinkage of ultra-high-performance concrete：A review [J].Composites Part B:Engineering,2019,178:107456.
[19]LIU K Z,LONG Y,CHEN L Y,et al.Mechanisms of autogenous shrinkage for ultra-high performance concrete (UHPC ) prepared with pre-wet porous fine aggregate (PFA )[J].Journal of Building Engineering,2022,54:104622.
[20]LIU J H,SHI C J,FARZADNIA N,et al.Effects of pretreated fine lightweight aggregate on shrinkage and pore structure of ultra-high strength concrete [J].Construction and Building Materials,2019,204:276-287.
[21]LIU K Z,YU R,SHUI Z H,et al.Influence of external water introduced by coral sand on autogenous shrinkage and microstructure development of ultra-high strength concrete (UHSC )[J].Construction and Building Materials,2020,252:119111.
[22]JUSTS J,WYRZYKOWSKI M,BAJARE D,et al.Internal curing by superabsorbent polymers in ultra-high performance concrete [J].Cement and Concrete Research,2015,76:82-90.
[23]LI S K,MO L W,DENG M,et al.Mitigation on the autogenous shrinkage of ultra-high performance concrete via using MgO expansive agent [J].Construction and Building Materials,2021,312:125422.
[24]CAO F Z,MIAO M,YAN P Y.Hydration characteristics and expansive mechanism of MgO expansive agents [J].Construction and Building Materials,2018,183:234-242.
[25]刘路明,方志,黄政宇,等.膨胀剂与内养剂对超高性能混凝土性能的影响 [J].硅酸盐学报,2020,48(11):1706 -1715.LIU Luming,FANG Zhi,HUANG Zhengyu,et al.Effects of expansive agent and super-absorbent polymer on performance of ultra-high performance concrete [J].Journal of the Chinese Ceramic Society,2020,48(11):1706 -1715.
[26]龚建清,罗鸿魁,张阳,等.减缩剂和 HCSA膨胀剂对UHPC力学性能和收缩性能的影响 [J].材料导报,2021,35(8):8042 -8048,8063.GONG Jianqing,LUO Hongkui,ZHANG Yang,et al.Effect of shrinkage reducing agent and HCSA expansion agent on mechanical properties and shrinkage properties of UHPC [J].Materials Reports,2021,35(8):8042 -8048,8063.
[27]黄维蓉,杨玉柱,崔通,等.含粗骨料超高性能混凝土收缩变形性能的研究 [J].混凝土,2021 (8):99-103.HUANG Weirong,YANG Yuzhu,CUI Tong,et al.Study on the workability and mechanical properties of ultra-high performance concrete containing coarse aggregate [J].Concrete,2021 (8):99-103.
[28]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.
[29]黄维蓉,杨玉柱,刘延杰,等.含粗骨料超高性能混凝土的力学性能 [J].硅酸盐学报,2020,48(11):1747 -1755.HUANG Weirong,YANG Yuzhu,LIU Yanjie,et al.Mechanical properties of ultra-high performance concrete containing coarse aggregate [J].Journal of the Chinese Ceramic Society,2020,48(11):1747 -1755.
[30]中国建筑科学研究院，宿迁华夏建设 （集团）工程有限公司.普通混凝土拌合物性能试验方法标准：GB/T 50080—2016 [S].北京：中国建筑工业出版社，2017.China Academy of Building Research,Suqian Huaxia Construction Group.Standard for test method of performance on ordinary fresh concrete：GB/T 50080—2016 [S].Beijing:China Architecture & Building Press,2017.
[31]清华大学.活性粉末混凝土:GB/T 31387—2015 [S].北京:中国标准出版社,2015.Tsinghua University.Reactive powder concrete:GB/T 31387—2015 [S].Beijing:Standards Press of China,2015.
[32]梁金国,马宝富.纤维素纤维对水泥砂浆湿度调控及性能影响研究 [J].中外公路,2024,44(3):46-52.LIANG Jinguo,MA Baofu.Effect of cellulose fiber on humidity control and properties of cement mortar [J].Journal of China & Foreign Highway,2024,44(3):46-52.