EXPERIMENTAL RESENRCH ON CRYOGENIC TEMPERATURE TENSILE STRENGTH OF CONCRETE UNDER COUPLING ACTION OF KEY INFLUENCING FACTORS

SHI Xudong; CUI Yidan; QIAN Lei

doi:10.13204/j.gyjzG19110708

Volume 50 Issue 8

Oct. 2020

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SHI Xudong, CUI Yidan, QIAN Lei. EXPERIMENTAL RESENRCH ON CRYOGENIC TEMPERATURE TENSILE STRENGTH OF CONCRETE UNDER COUPLING ACTION OF KEY INFLUENCING FACTORS[J]. INDUSTRIAL CONSTRUCTION, 2020, 50(8): 85-91. doi: 10.13204/j.gyjzG19110708

Citation:

SHI Xudong, CUI Yidan, QIAN Lei. EXPERIMENTAL RESENRCH ON CRYOGENIC TEMPERATURE TENSILE STRENGTH OF CONCRETE UNDER COUPLING ACTION OF KEY INFLUENCING FACTORS[J]. INDUSTRIAL CONSTRUCTION, 2020, 50(8): 85-91. doi: 10.13204/j.gyjzG19110708

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EXPERIMENTAL RESENRCH ON CRYOGENIC TEMPERATURE TENSILE STRENGTH OF CONCRETE UNDER COUPLING ACTION OF KEY INFLUENCING FACTORS

doi: 10.13204/j.gyjzG19110708

Department of Civil Engineering, Tsinghua University, Beijing 100084, China

Received Date: 2019-11-07

Abstract

Abstract

The effects of three key factors, including cryogenic temperature, concrete water content and strength grade, on concrete tensile strength were discussed through the splitting tensile experiment under cryogenic temperatures from -40 ℃ to -180 ℃ for the concrete with different water contents (2.0% to 5.5%) and strength grades (C30, C40 and C50), and the corresponding coupling action relationship was also fitted out. From the test results it was shown that the higher the strength grade and water content of concrete, and the lower the cryogenic temperature, the more flat the failure surface and the more obvious the splitting phenomenon of coarse aggregates located in the failure surface. The tensile strength of concrete increased with the increase of water content, and decreased with the decrease in cryogenic temperature at same other conditions, and then tended to be stable. However, the influence of concrete strength grade on its cryogenic temperature tensile strength was relatively small, and the higher the water content, the smaller the increase in splitting tensile strength for the concrete with higher strength grades. These test results and the expressions of concrete splitting tensile strength at cryogenic temperature, including three key factors of cryogenic temperature, water content and strength grade, could be used as references for the improvement of relevant theories and the design and safety evaluation of ultralow temperature concrete structures.
- concrete,
- cryogenic temperature,
- water content,
- strength grade,
- tensile strength

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References

贾承造,张永峰,赵霞. 中国天然气工业发展前景与挑战[J]. 天然气工业,2014,34(2):8-18.

MIURA T. The Properties of Concrete at Very Low Temperatures[J]. Materials and Structures, 1989, 22(4):243-254.

时旭东,田佳伦,钱磊,等. 经历常温降温及再回温的混凝土受力性能试验研究[J]. 工业建筑,2019,49(7):119-123

,128.

LEE G C, SHIH T S, CHANG K C. Mechanical Properties of Concrete at Low Temperature[J]. Journal of Cold Regions Engineering, 1988, 2(1):13-24.

KOGBARA R B, IYENGAR S R, GRASLEY Z C, et al. A Review of Concrete Properties at Cryogenic Temperatures:Towards Direct LNG Containment[J]. Construction & Building Materials, 2013, 47(10):760-770.

MARSHALL A L. Cryogenic Concrete[J]. Cryogenics, 1982,22(11):555-565.

YAMANA S, KASAMI H, OKUNO T. Properties of Concrete at Very Low Temperatures[J]. ACI Special Publication, 1978:55-56.

时旭东,居易,马驰,等. 混凝土低温受拉强度试验研究[J]. 建筑结构,2016,46(13):86-89.

王传星,谢剑,李会杰. 低温环境下混凝土性能的试验研究[J]. 工程力学,2011,28(增刊2):182-186.

时旭东,居易,郑建华,等.混凝土低温受压强度试验研究[J].建筑结构,2014,44(5):29-33.

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