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Acoustic emissions evaluation of the dynamic splitting tensile properties of steel fiber reinforced concrete under freeze–thaw cycling

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Abstract

This study empirically investigated the influence of freeze–thaw cycling on the dynamic splitting tensile properties of steel fiber reinforced concrete (SFRC). Brazilian disc splitting tests were conducted using four loading rates (0.002, 0.02, 0.2, and 2 mm/s) on specimens with four steel fiber contents (0%, 0.6%, 1.2%, and 1.8%) subjected to 0 and 50 freeze–thaw cycles. The dynamic splitting tensile damage characteristics were evaluated using acoustic emission (AE) parameter analysis and Fourier transform spectral analysis. The results quantified using the freeze–thaw damage factor defined in this paper indicate that the degree of damage to SFRC caused by freeze–thaw cycling was aggravated with increasing loading rate but mitigated by increasing fiber content. The percentage of low-frequency AE signals produced by the SFRC specimens during loading decreased with increasing loading rate, whereas that of high-frequency AE signals increased. Freeze–thaw action had little effect on the crack types observed during the early and middle stages of the loading process; however, the primary crack type observed during the later stage of loading changed from shear to tensile after the SFRC specimens were subjected to freeze–thaw cycling. Notably, the results of this study indicate that the freeze–thaw damage to SFRC reduces AE signal activity at low frequencies.

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References

  1. Wang Y, Bai Y, Xi Y P. Analytical solutions of moisture-chloride ion coupled transport in unsaturated concrete. Journal of the American Ceramic Society, 2021, 104(11): 5883–5897

    Article  Google Scholar 

  2. Liu X, Yan Z, Wang D J, Zhao Y, Niu D T, Wang Y. Corrosion cracking behavior of reinforced concrete under freeze–thaw cycles. Journal of Building Engineering, 2023, 64: 105610

    Article  Google Scholar 

  3. Wang Y Z, Yang W C, Ge Y, Liu P H, Zhang A. Analysis of freeze–thaw damage and pore structure deterioration of mortar by low-field NMR. Construction & Building Materials, 2022, 319: 126097

    Article  Google Scholar 

  4. Li L F, Xi Y P, Railsback R. Evaluation of Different Types of Waterproofing Membranes (Asphaltic and Non-Asphaltic) as Cost Effective Bridge Deck Barriers in Reducing Corrosive Chloride Effects. Colorado: Department of Transportation, 2018

    Google Scholar 

  5. Guo G. Preparation and mechanical properties of steel fiber reinforced concrete. Journal of Functional Materials, 2020, 51(11): 1001–9731

    Google Scholar 

  6. Jiang L, Niu D, Bai M. Experiment study on the frost resistance of steel fiber reinforced concrete. Advanced Materials Research, 2012, 368–373: 357–360

    Google Scholar 

  7. Wang C, Wu K. Study on the mechanical properties of carbon fiber and steel fiber concrete. Journal of Building Materials, 2003, 6(3): 253–256 (in Chinese)

    Google Scholar 

  8. Yong Y, Ren Q W. Experimental study on mechanical performance of steel fibre reinforced concrete. Journal of Hohai University (Natural Sciences), 2006, 34: 92–94 (in Chinese)

    Google Scholar 

  9. Wang R J, Hu Z Y, Li Y, Wang K, Zhang H. Review on the deterioration and approaches to enhance the durability of concrete in the freeze–thaw environment. Construction & Building Materials, 2022, 321: 126371

    Article  Google Scholar 

  10. Nili M, Azarioon A, Danesh A, Deihimi A. Experimental study and modeling of fiber volume effects on frost resistance of fiber reinforced concrete. International Journal of Civil Engineering, 2018, 16(3): 263–272

    Article  Google Scholar 

  11. Dong F, Wang H, Yu J, Liu K, Guo Z, Duan X, Qiong X. Effect of freeze-thaw cycling on mechanical properties of polyethylene fiber and steel fiber reinforced concrete. Construction & Building Materials, 2021, 295: 123427

    Article  Google Scholar 

  12. Qiu J, Pan D, Gu S, Guan X, Zheng J, Zhang C. Study on frost resistance and damage model of steel fiber reinforced coal gangue concrete. Journal of Glaciology and Geocryology, 2018, 40: 563–569

    Google Scholar 

  13. Zhou T, Xiong X, Li Y. Influence of freeze–thaw cycles on dynamic performance of steel fiber reinforced concrete. Journal of Water Resources and Water Engineering, 2021, 32(3): 167–172+178 (in Chinese)

    Google Scholar 

  14. Su H Z, Tong J J, Hu J, Wen Z P. Experimental study on AE behavior of hydraulic concrete under compression. Meccanica, 2013, 48(2): 427–439

    Article  Google Scholar 

  15. Sagar R V, Prasad B K R. AE energy release during the fracture of HSC beams. Magazine of Concrete Research, 2009, 61(6): 419–435

    Article  Google Scholar 

  16. Sagar R V, Prasad B K R, Kumar S S. An experimental study on cracking evolution in concrete and cement mortar by the b-value analysis of acoustic emission technique. Cement and Concrete Research, 2012, 42(8): 1094–1104

    Article  Google Scholar 

  17. Yue J, Xia Y, Fang H. Experimental study on fracture mechanism and tension damage constitutive relationship of steel fiber reinforced concrete Technology. China Civil Engineering Journal, 2021, 54: 93–106

    Google Scholar 

  18. Zhang H, Jin C, Wang L, Pan L, Liu X, Ji S. Research on dynamic splitting damage characteristics and constitutive model of basalt fiber reinforced concrete based on acoustic emission. Construction & Building Materials, 2022, 319: 126018

    Article  Google Scholar 

  19. Qiu J, Pan D, Guan X, Wang M J, Zheng J. Damage law of steel fiber reinforced coal gangue concrete based on acoustic emission technology. Bulletin of the Chinese Ceramic Societ, 2018, 37: 3338–3342

    Google Scholar 

  20. Lai Y S, Xiong Y, Cheng L F. Study of characteristics of acoustic emission during entire loading tests of concrete and its application. Journal of Building Materials, 2015, 18: 380–386 (in Chinese)

    Google Scholar 

  21. Topolar L, Kocab D, Pazdera L, Vymazal T. Analysis of acoustic emission signals recorded during freeze-thaw cycling of concrete. Materials, 2021, 14(5): 1230

    Article  Google Scholar 

  22. Afroughsabet V, Biolzi L, Ozbakkaloglu T. High-performance fiber-reinforced concrete: A review. Journal of Materials Science, 2016, 51(14): 6517–6551

    Article  Google Scholar 

  23. Mei M, Wu L, Wan C, Wu Z, Liu H, Yi Y. Mechanical properties of nano SiO2 and fiber-reinforced concrete with steel fiber and high performance polypropylene fiber. Materials Research Express, 2021, 8(10): 105001

    Article  Google Scholar 

  24. Zhang C, Sun Y, Xu J, Wang B. The effect of vibration mixing on the mechanical properties of steel fiber concrete with different mix ratios. Materials, 2021, 14(13): 3669

    Article  Google Scholar 

  25. Xu Z L. Concise Course of Elastic Mechanics. 4th ed. Beijing: Higher Education Press, 2013

    Google Scholar 

  26. Li C, Zhu J J. Study on splitting tensile failure mechanism of concrete. Shanxi Architecture, 2015, 41: 109–111 (in Chinese)

    Google Scholar 

  27. Shahidan S, Pulin R, Bunnori N M, Holford K M. Damage classification in reinforced concrete beam by acoustic emission signal analysis. Construction & Building Materials, 2013, 45: 78–86

    Article  Google Scholar 

  28. Yang J Z, Liu C W. A precise calculation of power system frequency and phasor. IEEE Transactions on Power Delivery, 2000, 15(2): 494–499

    Article  Google Scholar 

  29. Cooley J W, Tukey J W. An algorithm for the machine calculation of complex Fourier series. Mathematics of Computation, 1965, 19: 297–301

    Article  MathSciNet  Google Scholar 

  30. de Groot P J, Wijnen P A M, Janssen R B F. Real-time frequency determination of acoustic emission for different fracture mechanisms in carbon/epoxy composites. Composites Science and Technology, 1995, 55(4): 405

    Article  Google Scholar 

  31. Gutkin R, Green C J, Vangrattanachai S, Pinho S T, Robinson P, Curtis P T. On acoustic emission for failure investigation in CFRP: Pattern recognition and peak frequency analyses. Mechanical Systems and Signal Processing, 2011, 25(4): 1393–1407

    Article  Google Scholar 

  32. Ohno K, Ohtsu M. Crack classification in concrete based on acoustic emission. Construction & Building Materials, 2010, 24(12): 2339–2346

    Article  Google Scholar 

  33. Chen Z G, Jin X Y, Jin N G. Experimental study on the acoustic emission characteristics of concrete beams during damage. Cryogenic Building Technology, 2018, 40: 37–39

    Google Scholar 

  34. Gan Y X, Wu S C, Ren Y, Zhang G. Study on the evaluation index of granite splitting damage based on the rise time/amplitude of acoustic emission and average frequency value. Geotechnics, 2020, 41: 2324–2332

    Google Scholar 

  35. Li Y, Liu Y, Ding C, Li Z L, Zhang X F, Ding X P. Acoustic emission RA-AF characterization of the damage process of different seam coal. Mine Safety, 2022, 53: 37–43

    Google Scholar 

  36. Aggelis D G. Classification of cracking mode in concrete by acoustic emission parameters. Mechanics Research Communications, 2011, 38(3): 153–157

    Article  Google Scholar 

  37. Xing Y K, Huang B X, Chen D Y, Zhao X L, Li B H. Acoustic emission full-waveform multi-parameter monitoring of nonlinear fracture of fractured fractures. Journal of China Coal Society, 2021, 46: 3470–3487 (in Chinese)

    Google Scholar 

  38. Li X L, Chen S J, Liu S M, Li Z H. Acoustic emission waveform characteristics of rock mass under uniaxial loading based on HHT analysis. Journal of Central South University, 2021, 28: 1843–1856

    Article  Google Scholar 

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Acknowledgements

The authors would like to thank Southeast University and Hohai University for providing the test equipment. We would like to express our gratitude to our colleagues in the research group.

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Authors and Affiliations

  1. College of Civil and Transportation Engineering, Hohai University, Nanjing, 210098, China

    Hua Zhang, Xinyue Liu, Lingyu Bai, Shanshan Ji, Luoyu Pan & Xuechen Li

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  1. Hua Zhang
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  2. Xinyue Liu
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  3. Lingyu Bai
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  4. Shanshan Ji
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  5. Luoyu Pan
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  6. Xuechen Li
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Correspondence to Hua Zhang.

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Zhang, H., Liu, X., Bai, L. et al. Acoustic emissions evaluation of the dynamic splitting tensile properties of steel fiber reinforced concrete under freeze–thaw cycling. Front. Struct. Civ. Eng. 17, 1341–1356 (2023). https://doi.org/10.1007/s11709-023-0988-4

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  • DOI: https://doi.org/10.1007/s11709-023-0988-4

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