不同模型参数对面板堆石坝应力变形的影响研究
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摘要
为探讨室内三轴压缩试验及大型现场压缩模量试验在研究面板堆石坝坝筑坝材料实际力学特性的科学合理性,结合某100 m级混凝土面板堆石坝工程,分别对各区筑坝材料进行上述两种试验研究,其中对现场压缩试验成果采用基于免疫遗传算法的反演方法计算得到材料的邓肯E-B模型参数,同时整理室内压缩试验成果得到另一组参数。基于以上两组参数,运用三维非线性有限元法进行数值计算。计算结果显示,室内三轴试验过程因为缩尺试验料与实际筑坝料之间较大的颗粒粒径差异,计算得到的坝体及面板变形协调性较差,试验成果难以客观反映材料实际的力学性质,建议加强对缩尺效应及颗粒破碎机理的进一步研究以及直接对原级配筑坝材料试验方法的探索。
In order to discuss the scientific reasonability of the indoor triaxial compression experiment and the large-scale on-site compressive modulus experiment in the aspect of the study made on the actual mechanical properties of the dam construction materials for concrete face rockfill dam, both the experimental studies mentioned above are respectively made on the dam construction materials for all the construction zones in combination with a 100 m-grade concrete face rockfill dam project, in which the Duncan E-B model parameters of the materials are obtained from the calculation with the immune genetic algorithm-based inversion method for the result from the indoor triaxial compression experiment, while another set of parameters is obtained through sorting out the results from the indoor compression experiment. Based on both sets of the parameters, the 3-D nonlinear finite element method is used for the relevant numerical calculation. The calculation result shows that due to the larger difference between the particle sizes of both the scaled experiment materials and the actual dam construction materials, the coordination between the deformations of both the dam body and the dam face obtained from the calculation during the indoor triaxial experiment is poor, and then the experiment result is difficult to objectively reflect the actual mechanical properties of the materials, thus it is suggested that the further study on the scale effect and the mechanism of particle breakage as well as the direct exploration on the experiment method for dam construction materials of the original gradation are necessary to be strengthened.
In order to discuss the scientific reasonability of the indoor triaxial compression experiment and the large-scale on-site compressive modulus experiment in the aspect of the study made on the actual mechanical properties of the dam construction materials for concrete face rockfill dam, both the experimental studies mentioned above are respectively made on the dam construction materials for all the construction zones in combination with a 100 m-grade concrete face rockfill dam project, in which the Duncan E-B model parameters of the materials are obtained from the calculation with the immune genetic algorithm-based inversion method for the result from the indoor triaxial compression experiment, while another set of parameters is obtained through sorting out the results from the indoor compression experiment. Based on both sets of the parameters, the 3-D nonlinear finite element method is used for the relevant numerical calculation. The calculation result shows that due to the larger difference between the particle sizes of both the scaled experiment materials and the actual dam construction materials, the coordination between the deformations of both the dam body and the dam face obtained from the calculation during the indoor triaxial experiment is poor, and then the experiment result is difficult to objectively reflect the actual mechanical properties of the materials, thus it is suggested that the further study on the scale effect and the mechanism of particle breakage as well as the direct exploration on the experiment method for dam construction materials of the original gradation are necessary to be strengthened.
引文
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[2] 党继军,杜文礼,李绍鹏,等.高面板堆石坝建设进展[J].云南水力发电,2015,31(4):71- 72.
[3] 朱晟,钟春欣,郑希镭,等.堆石体的填筑标准与级配优化研究[J].岩土工程学报,2018,40(1):108- 115.
[4] 朱晟,钟春欣,王京,等.高堆石坝填筑标准的试验研究[J].岩土工程学报,2018,40(1):108- 115.
[5] 刘京茂,孔宪京,邹德高.考虑振动碾压引起的颗粒破碎对堆石坝变形计算的影响[J].水利学报,2018,46(8):934- 942.
[6] 朱晟,宁致远,钟春欣,等.考虑级配效应的堆石料颗粒破碎与变形特性研究[J].水利学报,2018,49(7):849- 857.
[7] 武力强,朱晟,章晓桦,等.粗粒料试验缩尺效应的分析研究[J].岩土力学,2016,37(8):2187- 2197.
[8] 朱晟,梁现培,冯树荣.基于现场大型承载试验的原级配筑坝堆石料力学参数反演研究[J].岩土工程学报,2009,31(7):1138- 1143.
[9] 钱家欢,殷宗泽.土工原理与计算[M].北京:水利水电出版社,2003.
[10] 顾淦臣,朱晟.混凝土面板堆石坝三维非线性有限元静力动力分析程序[M].北京:科学技术出版社,1991.
[11] 朱晟,王永明,胡祥群.免疫遗传算法在土石坝筑坝粗粒料本构模型参数反演中的应用研究[J].岩土力学,2010,31(3):961- 966.
[12] 柏树田,崔亦昊.堆石的力学性质[J].水力发电学报,1997(3):21- 29.
[13] 张鸥,盛超.面板堆石坝筑坝材料力学特性参数反演分析[J].杨凌职业技术学院学报,2013,12(4):31- 33.
[14] 王永明.筑坝粗粒料缩尺效应及弹塑性模型研究[D].南京:河海大学,2010.
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