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Abstract

The objective of this study is to discuss the use of gangue-based concrete (GBC) and the necessity of ensuring its mechanical properties meet technical and regulatory standards. This study examines GBC with varying coal gangue powder (CGP) replacement rates (0%, 10%, 20%, and 30%) and distinct water-to-cement ratios (0.35, 0.40, and 0.45). Acoustic emission tests, scanning electron microscopy tests, and axial compression tests were used in the experiments. The mechanical properties of GBC were examined by stress-strain curves, and the variation of parameters concerning content and hydrogel ratio was assessed in relation to the microstructure. Ultimately, based on the acoustic emission (AE) energy of the GBC damage process, combined with the crack compression effect, a GBC load damage model was established. The research results demonstrate that the damage evolution model developed in this study accurately represents the damage progression of GBC under varying dosages and hydrogel ratios. The structural model aligns with this paper and further experimental findings.

Keywords

coal gangue powder axial compression SEM acoustic emission energy damage evolution damage constitutive model crack compression effect

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References

Guan

Chen

Zhu

, et al. Effect of microwave activated coal gangue on properties of cement-based materials. Material Guide 2023; 37(04): 95–101.

Liang

Zhu

. Mercury emission from spontaneously ignited coal gangue hill in wuda coalfield, Inner Mongolia, China. Fuel 2016; 182(oct.15): 525–530.

Liu

Guan

. Multitechnique investigation of concrete with coal gangue. Constr Build Mater 2021; 301(PT.1): 124114.

Xiao

Qiu

Pan

, et al. Research on the evaluation method of damage degree of coal gangue concrete under freezing-thawing. Mater Rev 2018; 264: 120720.

Wang

Amp

. Research on the freeze-thaw damage law of coal gangue concrete. Fly Ash Comprehensive Utilization 2019; 94: 110039.

Yan

. Experimental study on mechanical properties and frost resistance of modified coal gangue aggregate concrete. Xi’an Univ. Archit. Technol 2017; 98: 111207.

Luo

Peng

Liu

, et al. Mechanical properties and damage evolution of concrete under cyclic pore water pressure. J Yangtze River Sci Res Inst 2018; 82: 108196.

Land

. Continuous damage model for load-response estimation of concrete. Cement Concr Res 1980; 10(3): 395–402.

Lubliner

Oliver

Oller

, et al. A plastic-damage model for concrete. Int J Solid Struct 1989; 25(3): 299–326.

10.

Dougill

. On stable progressively fracturing solids. Z Angew Math Phys 1976; 27: 423–437.

11.

success

Jie

. Study on stochastic damage constitutive model of concrete considering strain rate effect. Journal of Mechanics 2022; 54(12): 3456–3467.

12.

Jin-Fei

Yang

Yu-Shou

, et al. Deterioration characteristics and damage constitutive model of concrete under thermo-mechanical coupling. Bulletin of the Chinese Ceramic Society 2018.

13.

Jishi

Qiang

Yuchun

, et al. Studying the dynamic damage failure of concrete based on acoustic emission. Constr Build Mater 2017; 149: 9–16.

14.

Fan

, et al. Acoustic emission properties of concrete on dynamic tensile test. Constr Build Mater 2016; 114(jul.1): 66–75.

15.

Yan

Jia

, et al. Study on the relevant parameters of concrete static axial tensile acoustic emission test. Vibration and impact 2011; 30(5): 9.

16.

Jiang

Tong

, et al. Rate effect on mechanical properties of hydraulic concrete flexural-tensile specimens under low loading rates using acoustic emission technique. Ultrasonics 2012; 52(7): 890–904.

17.

Niv

, et al. Damage constitutive model of coal gangue concrete under freeze-thaw cycles. Constr Build Mater; 264.

18.

Chen

Tao

Ren

, et al. Research on dependence between parameters in complete stress-strain constitutive curve of concrete based on copula theory. China Civ Eng J 2020; 53: 52–63.

19.

Chi

Huang

, et al. Finite element modeling of steel-polypropylene hybrid fiber reinforced concrete using modified concrete damaged plasticity. Eng Struct 2017; 148: 23–35.

20.

Tang

. Evolution and propagation of material defects and kaisereffect function. J Seismol Res 1990; 13(2): 203–213.

21.

Wang

, et al. Experimental study on damage evolution law of layered composite rock based on acoustic emission. Sci Technol Eng 2022; 22(19): 8431–8438.

22.

Tan

, et al. Acoustic emission characteristics and damage model of cement mortar under uniaxial compression. Constr Build Mater 2019; 213(JUL.20): 377–385.

23.

Lemaitre

. How to use damage mechanics. Nucl Eng Des 1984; 80(2): 233–245.

24.

Cheng

Wang

, et al. The study on the whole stress-strain curves of coral fly ash-slag alkali-activated concrete under uniaxial compression. Materials 2020; 13(19): 4291.

25.

Huang

Liu

Goda

. Applicability of smooth particle hydrodynamics method to large sliding deformation of saturated slopes under earthquake action. Chin J Geotech Eng 2023; 45(2): 336–344.

Study on acoustic emission characteristics and damage model of gangue concrete under axial compression

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