Study of Rheological-Mechanical Properties and Vibration Mechanics Bandgap of Row Pile Foundation
DOI:
https://doi.org/10.13052/ejcm2642-2085.3212Keywords:
Fluid mechanics, row pile foundation, vibration mechanics, periodic structure, multiple scattering mechanism, elastic wave bandgapAbstract
To analyze the rheological and mechanical properties as well as the vibration-mechanical forbidden zone effect of row pile foundations, this paper employs time-dependent modulus to examine the rheological mechanics of soil. Drawing from viscoelastic theory, we derive the expression of deformation modulus in the frequency domain to analyze the frequency dependence of the shear modulus of rheological soils. We construct a continuous medium dynamics model of the pile-soil periodic structure, taking into account soil rheology, and derive the dispersion equation of shear waves in the periodic structure using the multiple scattering method. The band gap characteristics and parameters that influence the law of shear waves in rheological soil-row pile foundations are studied through the analysis of arithmetic cases. The results show that under the loading condition, the zero-frequency shear modulus of soil is larger than the initial modulus value, and the real part of the shear modulus decreases monotonically with the increase of frequency and finally converges to the initial modulus value; under the unloading condition, the zero-frequency shear modulus of soil is smaller than the initial modulus value, and the real part of the shear modulus increases monotonically with the increase of frequency and finally converges to the initial modulus value; the larger the relaxation time of soil, the faster the convergence rate; the imaginary part of the shear modulus of soil The imaginary part of the soil shear modulus is positive under loading condition and negative under unloading condition, the value of the imaginary part increases and then decreases with increasing frequency and finally converges to 0. The imaginary part reaches the peak at the critical frequency, the larger the relaxation time the smaller the critical frequency, and the peak of the imaginary part is independent of the relaxation time. This study analyzed the dispersion curve of shear waves in a pile-soil periodic structure and found that increasing low-frequency shear wave velocity in rheological soil pile foundation shifts the band gap position to a higher frequency band, resulting in a smaller band gap width than in linear elastic soil. The relaxation time of soil affects the frequency position and width of the band gap, with larger relaxation times resulting in higher frequency positions and smaller widths. Additionally, soil rheology widens the forbidden vibration band gap of the pile periodic structure when the filling rate of the pile foundation is larger.
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Yang Zongcai, Zhang Junyun, Zhou Depei. Study on the rapid weathering characteristics of red-layered mudstone slopes. Journal of Rock Mechanics and Engineering, 2006, 25(2): 275–283.
Zhang J.Y., Zhou D.P. … Rapid weathering law of red-layered mudstone slopes. Journal of Southwest Jiaotong University, 2006, 41(1): 74–79.
Pan Y, Liu Z, Zhou Cuiying. Experiments on water disintegration characteristics of red-bedded soft rock and its interface model. Geotechnics, 2017, 38(11): 3231–3239.
Wu Daoxiang, Liu Hongjie, Wang Guoqiang. Indoor experimental study on the disintegration properties of red-bedded soft rocks. Journal of Rock Mechanics and Engineering, 2010, 29.
Diao X. H., Yang S. X., C. S. B. Experimental study of water absorption and swelling characteristics of mudstone under different temperature and humidity environments. Journal of East China Jiaotong University, 2017, 34(3): 14–18.
Hu WJ, Ding Y, Xia ZY, et al. Experimental study on the lateral limit of the swelling performance of red-layered mudstone in the Chongqing area. Journal of Disaster Prevention and Mitigation Engineering, 2015, 35(5): 607–611.
Ji M, Gao Gao, Gao YN, et al. Study on the time effect of water swelling of ash mudstone. Journal of China University of Mining and Technology, 2010, 39(4): 511–515.
Liu X.L., Wang S.J., Wang E.C., et al. Swelling intrinsic relations of swelling rocks containing time effects. Journal of Water Resources, 2006, 37(2): 195–199.
Wei YX, Zhang SZ, Gan Y, et al. Experimental study on basic properties and swelling and softening of red-bedded mudstone in Sichuan Basin. Engineering Investigation, 2010: 61–68.
Zhong ZB, Li AH, Deng RG, et al. Experimental study on the time-dependent expansion-deformation characteristics of red-bedded mudstone in central Sichuan. Journal of Rock Mechanics and Engineering, 2019, 38(1): 76–86.
Chen Wenwu, Yuan Pengbo, Liu Xiaowei. Experimental study on creep characteristics of red-bedded soft rocks under graded loading conditions. Journal of Rock Mechanics and Engineering, 2009, 28(Suppl. 1): 3076–3081.
Ju Nengpan, Huang Haifeng, Zheng Da, et al. Creep properties of red-bedded mudstone considering water content and improved Burgers model. Geotechnics, 2016, 37: 67–74.
Liu S. W., Chen W. W., Zhang F. Y., et al. Experimental study on rheological properties of Neoproterozoic red-bedded soft rocks. Chinese Desert, 2012, 32(5): 1268–1274.
Wang Yanchao. Study on creep mechanical properties of Badong Formation mudstone and temporal properties of slope deformation and support. Wuhan: China University of Geosciences, 2018.
Yan Yunming, Li Hengle, Guo Shili. Experimental study of triaxial creep mechanical properties of purple-red mudstone. Journal of Changjiang Academy of Sciences, 2017, 34(6): 88–92.
Yang Shu-Bi, Xu Jin, Dong Xiao-Bi. Study on the rheological characteristics of sandy-mudstone interbedded slopes in the red-bedded area. Geological Hazards and Environmental Protection, 1996, 7(2): 12–24.
Jian W, Wang Z, Yin K. Mechanism of the Anlesi landslide in the Three Gorges Reservoir, China. Engineering Geology, 2009, 108(1–2): 86–95.
Wang Zhimeng. Research on red-layered mudstone’s adaptability and engineering technology and its improved soil filling for high-speed railroad roadbed [Doctoral dissertation]. Chengdu: Southwest Jiaotong University, 2009.
Wei Y. X. Experimental study on the technology of using red-layered mudstone to fill the roadbed of high-speed railroad. Journal of Railway Engineering, 2009, (12): 39–43.
Yangyang Wei, et al. Bionic Mechanical Analysis of Dragonfly Wings: The Feasibility of Mesh Combination to Improve Structural Stiffness. European Journal of Computational Mechanics, 2022, 31(4): 459–504.
Yang, Xianjian. Geodynamic problems in industrial environmental vibration. Journal of Geotechnical Engineering, 1992, 114(2): 82–88.
Woods R D, Barnet N E, Sangesser R. A new tool for soil dynamics. Journal of Geotechnical Engineering Division, ASCE, 1974, 100(11): 1234–1247.
Liao S, Sangrey D A. Use of piles as isolation barriers. Journal of Geotechnical Engineering Division, ASCE, 1978, 104(9): 1139–1152.
Aviles J, Sanchez-Sesma F J. Piles as barriers for elastic waves. Journal of Geotechnical Engineering, 1983, 109(9): 1134–1146.
Baroomand B, Kaynia A M. Vibration isolation by an array of piles//Soil Dynamics and Earthquake Engineering. southampton: Computational Mechanics Publications, 1991: 683–691.
Kattis S E, Polyzos D, Beskos D E. Vibration isolation by a row of piles using a 3-D frequency domain BEM. International Journal for Numerical Methods in Engineering, 1999, 46(5): 713–728.
Qiu Chang. Three-dimensional Analysis of Far-Field Passive Vibration Isolation for Continuous and Discontinuous Barriers [Doctoral dissertation D]. Shanghai: Tongji University, 2003.
Chen X.B., Wang Y.S., Tang M.X., et al. Characterization of periodic four-component local resonant pile band gap and vibration isolation performance. Geotechnics, 2022, 43(1): 110–118.
Chen, Zongji. One-way problems of consolidation and sub-temporal effects. Journal of Civil Engineering, 1958, 5(1): 1–10.
Wang Taiheng et al. Analysis of Factors Influencing Mechanical Properties of Corrugated Steel Based on Entropy Method. European Journal of Computational Mechanics, 2022, 31(4): 539–554.
Cai Yuanqiang, Liang X, Zheng Zaofeng, et al. One-dimensional consolidation of viscoelastic soil layers with semi-permeable boundaries under cyclic loading. Journal of Civil Engineering, 2003, 36(8): 86–90.
Zeng QY, Zhou J, Qu JT. A method for calculating long-term settlement of pile foundations considering stress-strain time effects. Geotechnics, 2005, 26(8): 1283–1287.
Ai Zhiyong, Wang He Mu, Jin Jing. Timing study of laminar fractional-order viscoelastic saturated foundations acting together with beams. Journal of Mechanics, 2021, 53(5), 1402–1411.
Ai Z Y, Zhao Y Z, Cheng Y C. Time-dependent response of laterally loaded piles and pile groups embedded in transversely isotropic saturated viscoelastic soils. Computers and Geotechnics, 2020, 128: 103815.
He LJ, Kong LW, Wu WJ, et al. A model for describing creep in soft clay using fractional order derivatives. Geotechnics, 2011, 32(S2): 239–243.
