|Table of Contents|

Influence of Surface Cracks on Humidity Response of Concrete Under Constant Climatic Environment(PDF)

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

Issue:
2021年03期
Page:
99-106
Research Field:
Publishing date:

Info

Title:
Influence of Surface Cracks on Humidity Response of Concrete Under Constant Climatic Environment
Author(s):
JIANG Jian-hua QIU Jia-qi FU Yong-quan LIN Ming-yi HU Fei-fei
(College of Civil and Transportation Engineering, Hohai University, Nanjing 210024, Jiangsu, China)
Keywords:
concrete humidity response water-cement ratio fly ash crack width crack depth
PACS:
TU528
DOI:
10.19815/j.jace.2020.09027
Abstract:
In order to study the humidity response relationship between the internal micro-environment and the external environment of cracked concrete, the internal humidity response tests of concrete under different crack conditions were carried out by artificially simulating the constant climatic environment, and the effects of different water cement ratios and fly ash contents were also considered. Finally, a formula for calculating the equivalent moisture diffusion coefficient of concrete considering the effect of surface crack was proposed, and the prediction model of internal humidity response of concrete with surface crack under the constant climatic environment was established, then the feasibility of the model was verified. The results show that the internal humidity response rate of cracked concrete is higher than that of non-cracked concrete. Under the crack conditions, the humidity response rate of concrete does not change significantly with the increase of crack width, but increases linearly with the increase of crack depth. The humidity response rate of cracked concrete increases with the increase of the water-cement ratio, and the humidity response rate of concrete without fly ash is the fastest, followed by the concrete with the fly ash content of 30% and 15%. Moreover, there are differences in the significance of the effect of cracks on the internal humidity response of concrete with different water-cement ratios and fly ash contents.

References:

[1] ANDRADE C,SARRIA J,ALONSO C.Relative Humidity in the Interior of Concrete Exposed to Natural and Artificial Weathering[J].Cement & Concrete Research,1999,29(8):1249-1259.
[2]韩学强,詹树林,徐 强,等.干湿循环作用对混凝土抗氯离子渗透侵蚀性能的影响[J].复合材料学报,2020,37(1):198-204.
HAN Xue-qiang,ZHAN Shu-lin,XU Qiang,et al.Effect of Dry-wet Cycling on Resistance of Concrete to Chloride Ion Permeation Erosion[J].Acta Materiae Compositae Sinica,2020,37(1):198-204.
[3]方小婉,娄宗科,高亚磊,等.硫酸盐侵蚀下混凝土抗冻耐久性研究进展[J].混凝土,2019(12):6-10,17.
FANG Xiao-wan,LOU Zong-ke,GAO Ya-lei,et al.Research Progress on Frost Resistance Durability of Concrete Under Sulfate Attack[J].Concrete,2019(12):6-10,17.
[4]毛继泽,齐 辉,鲇田耕一.轻骨料含水率对混凝土吸水性及抗冻性的影响[J].建筑材料学报,2009,12(4):473-477.
MAO Ji-ze,QI Hui,AYUTA Ko-ichi.Effects of Water Content in Lightweight Aggregate on Water-absorbing Property and Freeze-thaw Resistance of Concrete[J].Journal of Building Materials,2009,12(4):473-477.
[5]AHLSTROM J,TIDBLAD J,SEDERHOLM B,et al.Influence of Chloride and Moisture Content on Steel Rebar Corrosion in Concrete[J].Materials and Corrosion,2016,67(10):1049-1058.
[6]SIMCIC T,PEJOVNIK S,SCHUTTER G D,et al.Chloride Ion Penetration into Fly Ash Modified Concrete During Wetting-drying Cycles[J].Construction and Building Materials,2015,93:1216-1223.
[7]马文彬,李 果.自然气候条件下混凝土内部温湿度响应规律研究[J].混凝土与水泥制品,2007(2):18-21.
MA Wen-bin,LI Guo.Research on the Response Law of Temperature and Humidity in Concrete Under Natural Climate Conditions[J].China Concrete and Cement Products,2007(2):18-21.
[8]RYU D W,KO J W,NOGUCHI T.Effects of Simulated Environmental Conditions on the Internal Relative Humidity and Relative Moisture Content Distribution of Exposed Concrete[J].Cement & Concrete Composites,2011,33:142-153.
[9]LIU P,SONG L,YU Z.Quantitative Moisture Model of Interior Concrete in Structures Exposed to Natural Weather[J].Construction and Building Materials,2016,102:76-83.
[10]MIN H,ZHANG W,GU X.Effects of Load Damage on Moisture Transport and Relative Humidity Response in Concrete[J].Construction and Building Materials,2018,169:59-68.
[11]刘 鹏,余志武,宋 力.自然环境中混凝土内湿度响应规律[J].中国矿业大学学报,2013,42(3):388-393.
LIU Peng,YU Zhi-wu,SONG Li.The Humidity Response Law in Concrete in the Natural Environment[J].Journal of China University of Mining & Technology,2013,42(3):388-393.
[12]JIANG J,YUAN Y.Quantitative Models of Climate Load and Its Effect in Concrete Structure[J].Construction and Building Materials,2012,29:102-107.
[13]张国辉,李宗利,张林飞,等.干燥条件对混凝土强度影响试验研究[J].建筑材料学报,2015,18(5):840-846.
ZHANG Guo-hui,LI Zong-li,ZHANG Lin-fei,et al.Experimental Study on Concrete Strength for Different Drying Conditions[J].Journal of Building Materials,2015,18(5):840-846.
[14]鲁彩凤,袁迎曙,蒋建华.粉煤灰混凝土孔隙结构对气体扩散能力的影响[J].中国矿业大学学报,2011,40(4):523-529.
LU Cai-feng,YUAN Ying-shu,JIANG Jian-hua.Effect of Pore Structure on Gas Diffusion in Fly Ash Concrete[J].Journal of China University of Mining & Technology,2011,40(4):523-529.
[15]王建贵,杨匡宋.空气中水蒸气的扩散系数及平均自由程的测定[J].物理实验,1986(6):284-285.
WANG Jian-gui,YANG Kuang-song.Measurement of Diffusion Coefficient and Mean Free Path of Water Vapor in Air[J].Physics Experimentation,1986(6):284-285.
[16]蒋建华,袁迎曙,王嵩林,等.人工气候环境下混凝土内相对湿度响应预测[J].中南大学学报:自然科学版,2013,44(12):5091-5099.
JIANG Jian-hua,YUAN Ying-shu,WANG Song-lin,et al.Prediction of Response of Relative Humidity in Concrete Under Artificial Climate Environment[J].Journal of Central South University:Science and Technology,2013,44(12):5091-5099.
[17]GERARD B,MARCHAND J.Influence of Cracking on the Diffusion Properties of Cement-based Materials:Part Ⅰ:Influence of Continuous Cracks on the Steady-state Regime[J].Cement and Concrete Research,2000,30(1):37-43.
[18]田锦州,徐乃忠,李凤明.误差函数erf(x)近似计算及其在开采沉陷预计中的应用[J].采矿与岩层控制工程学报,2009,14(2):33-35.
TIAN Jin-zhou,XU Nai-zhong,LI Feng-ming.Proximate Calculation of Error Function erf(x)and Its Application in Mining Subsidence Prediction[J].Journal of Mining and Strata Control Engineering,2009,14(2):33-35.

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Last Update: 2021-05-20