Experimental Study on Materials and Mechanical Properties of Steel Tube-Confined Coral Concrete Reinforcement Mechanism

Jing Huang; Wen Xuan Shan; Yi Gao

doi:10.4028/p-jkfwni

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Experimental Study on Materials and Mechanical Properties of Steel Tube-Confined Coral Concrete Reinforcement Mechanism
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HomeMaterials Science ForumMaterials Science Forum Vol. 1079Experimental Study on Materials and Mechanical...

Experimental Study on Materials and Mechanical Properties of Steel Tube-Confined Coral Concrete Reinforcement Mechanism

Abstract:

Filling steel tubes with coral concrete to form concrete filled steel tube composite structures for compression members can compensate for its low aggregate strength. In order to demonstrate the reinforcement mechanism of coral concrete hoop under steel tube restraint and to propose the strength theory under the hoop effect, it is necessary to obtain the theoretical analysis based on the theory of triaxial compressive bearing theory of normal concrete. Therefore, starting from the failure mechanism of coral concrete under triaxial compression, the hoop reinforcement mechanism of coral concrete under different lateral pressure conditions is studied analytically. By the axial compression bearing capacity comparative test between normal concrete and coral concrete under steel tube restraint, comparative relationship between lateral pressure and circumferential strain is calculated and the conditions for taking values are acquired, which lays the foundation for the calculation theory of the compressive bearing capacity of it.

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Periodical:

Materials Science Forum (Volume 1079)

Pages:

199-205

DOI:

https://doi.org/10.4028/p-jkfwni

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Online since:

December 2022

Authors:

Jing Huang, Wen Xuan Shan*, Yi Gao

Keywords:

Experimental Study, Hoop Reinforcement, Lateral Pressure Coefficient, Steel Tube-Confined Coral Concrete

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References

[1] Zhao H., Gao Y., Li H. Y. Research of the compressive testes and bearing capacities of coral concrete filled square steel tube short columns. China Concrete and Cement Products, 2019(3): 43-47.

Google Scholar

[2] Gao Y., Li H. Y., Zhao H. Experimental research on axial compression behavior of CFRP coral concrete filled square steel tube short columns. Concrete, 2019(11):54-57．Doi：10.3969/j.issn.1002-3550.2019.11.012.

Google Scholar

[3] Y. Gao, Y. Lu. Study on raw materials and structural performance of coral concrete composite structure. Domenico Lombardo, Ke Wang. Advances in Materials Science and Engineering: Proceedings of the 7th annual international workshop on materials science and engineering, (iwmse 2021). CRC Press/Balkema, 2022: 177-185. https://doi.org/10.1201/9781003225850-27.

DOI: 10.1201/9781003225850-27

Google Scholar

[4] GB/T 50081-2019. Standard for test method of mechanical properties on ordinary concrete [S].

Google Scholar

[5] Gao Y., Wei Z. B. Sun Xiao. Experimental research on basic mechanical properties of coral aggregate concrete. Journal of Naval University of Engineering, 2017, 29(1): 64-68. Doi：10. 7495/j. issn. 1009 - 3486. 2017. 01. 013.

Google Scholar

[6] Yan Y. X., Li B., Ton g Y. Z., Li X. M., Liu J. J. Analysis of axial compressive bearing capacity for RPC filled steel stub columns based on the limit equilibrium theory. Building Structure, 2020, 50(5): 135-139.

Google Scholar

[7] Pan B. Z., Wei Z. B. Experimental study on effects to coral sand concrete compressive strength of raw materials. Engineering Mechanics, 2015, 32(s1): 221-224.

Google Scholar

[8] Gao Y. Huang Jing. Experimental study on axial compression properties of coral concrete filled steel tubular short column. Journal of Logistical Engineering University, 2017, 33(3): 9-10. Doi：10. 3969/j. issn. 1672 - 7843. 2017. 03. 002.

Google Scholar

[9] Zhong S. T. Unified theory of concrete filled steel tubular: Research and Application. Bei Jing: Tsinghua University Press, 2006:78.

Google Scholar