Intelligent closed-loop control of concrete moisture levels

被引：0

作者：

Fan Q. ^{[1
,2
]}

Duan Y. ^{[3
,4
]}

Wang Y. ^{[3
]}

Wang X. ^{[1
]}

Yang S. ^{[3
]}

Kang X. ^{[1
]}

机构：

[1] China Three Gorges Corporation, Beijing

[2] China Huaneng Group Co., Ltd., Beijing

[3] School of Water Resources and Hydropower Engineering, Wuhan University, Wuhan

[4] School of Urban Construction, Wuchang University of Technology, Wuhan

来源：

Qinghua Daxue Xuebao/Journal of Tsinghua University | 2021年 / 61卷 / 07期

关键词：

Concrete; Crack prevention; Intelligent control system; Moisture conservation;

D O I：

10.16511/j.cnki.qhdxxb.2020.26.038

中图分类号：

学科分类号：

摘要：

The concrete moisture content must be maintained after curing. The cement particles in concrete cannot fully hydrate and transform to a stable crystalline form if the concrete is not well hydrated. In addition, moisture loss may result in shrinkage, deformation and cracks, which will affect the structure durability. Concrete specifications and experience have shown that the concrete surface humidity should be no less than 95% during curing. Humidity diffusion theory was used to develop a mathematical model for the concrete moisture conservation with the third type of boundary condition at the surface. Information technology and mechanical control theory were then used to develop an intelligent control method for the concrete moisture conservation. An intelligent control system was then developed to automatically collect the temperature, humidity and wind speed near the concrete surface and to then calculate the concrete surface humidity. The intelligent control system provides real-time feedback warnings and intelligently controls a spray tube which reduces labor costs and ensures the concrete quality. The intelligent control equipment can be flexibly adapted to various large, complex engineering projects. © 2021, Tsinghua University Press. All right reserved.

引用

页码：671 / 680

页数：9

共 45 条

[1] HUANG Y, QI K, ZHANG J., Characteristics of moisture development of early concrete, Journal of Tsinghua University (Science and Technology), 47, 3, pp. 309-312, (2007)
[2] HUANG D H, LIU G T., Experimental study on isothermal moisture transfer process of concrete, Journal of Hydraulic Engineering, 33, 6, pp. 96-101, (2002)
[3] MA Y X, CHEN X G., Study on moisture field and shrinkage stress of hydraulic concrete, Journal of Hydroelectricity, 3, pp. 38-42, (2008)
[4] DONG X G., The influence of curing condition on the strength and durability of concrete, Jiangxi Building Materials, 3, pp. 52-53, (2014)
[5] LIANG J W, LIU Y Z, ZHANG G X, Et al., Nonlinear finite element analysis of moisture and shrinkage stress in hydraulic thin-wall concrete structures, Water Conservancy and Hydropower Technology, 8, pp. 38-41, (2007)
[6] HUANG Y Y, LIU Y, GAO J, Et al., Experimental study on internal relative humidity of early age hydraulic concrete in real environment, Journal of Basic Science and Engineering, 27, 4, pp. 744-752, (2019)
[7] HE Z, FANG G Z., Research on concrete curing method, Low Carbon World, 174, 36, pp. 207-208, (2017)
[8] JIANG S L, LI C H., The influence of curing environment on the growth of strength of long-age hydraulic concrete, Water Power, 42, 4, pp. 113-116, (2016)
[9] ZHU W M, CHEN L., Effects of different curing methods on the performance of mass fly ash concrete, Fly Ash Comprehensive Utilization, 3, pp. 20-24, (2015)
[10] REN J Z, WANG X P., Choice of curing method for hydraulic concrete, Water Conservancy Planning and Design, 5, pp. 111-113, (2015)

← 1 2 3 4 5 →