稀疏非正交填充裂隙岩体水流—传热—应力模型与离散元模拟
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摘要
为研究填充裂隙水流速度对岩体温度和应力的影响,选取甘肃北山地区的花岗岩,制作了稀疏非正交裂隙岩体模型,采用河砂填充裂隙后进行模型试验;并对模型试验进行离散元数值模拟,分析了模型试验所测岩体温度和热应力与数值模拟结果的差异和原因。结果显示:填砂裂隙强化了裂隙介质的热导能力,无填充时岩体温度和热应力比填砂时低;模型试验和离散元模拟均表明,岩体温度和岩体应力随裂隙水流速度增大而减小,但是系统达到稳态所需要的时间变短;模型试验中斜裂隙水流对温度场起主要作用;由于现有3DEC软件不能考虑水的热物性参数随温度的变化,进而产生自然对流换热,斜裂隙水流和靠近热源侧的竖裂隙水流对温度场起主要作用。
Model tests and discrete element simulation are conducted to study the effects of water velocity on temperature and stress in a physical rock mass model with sparse non-orthogonal sand-filled fractures,and the differences in temperatures and thermal stresses between the tests and the discrete element simulations are analyzed and attributed to mismatches between the test setups and the discrete model setups. The granite rocks in Beishan area in Gansu Province are studied. Results show that the filled sand fractures strengthen thermal conductivity of fractures media, and both temperature and thermal stress of rock mass without filling are lower than those with filling sand. Both the tests and discrete element simulations indicate that the rock mass temperature and stress decrease with increasing fracture water velocity, but the time required for the system to reach the steady state becomes shorter. The model test shows that oblique fracture water flow controls the temperature field. Because the existing 3 DEC software does not take into account the changes of thermal property parameters of water with temperatures, thus generating natural convection heat transfer, oblique fracture water flow and vertical fracture water flow near the heat source control the temperature field.
Model tests and discrete element simulation are conducted to study the effects of water velocity on temperature and stress in a physical rock mass model with sparse non-orthogonal sand-filled fractures,and the differences in temperatures and thermal stresses between the tests and the discrete element simulations are analyzed and attributed to mismatches between the test setups and the discrete model setups. The granite rocks in Beishan area in Gansu Province are studied. Results show that the filled sand fractures strengthen thermal conductivity of fractures media, and both temperature and thermal stress of rock mass without filling are lower than those with filling sand. Both the tests and discrete element simulations indicate that the rock mass temperature and stress decrease with increasing fracture water velocity, but the time required for the system to reach the steady state becomes shorter. The model test shows that oblique fracture water flow controls the temperature field. Because the existing 3 DEC software does not take into account the changes of thermal property parameters of water with temperatures, thus generating natural convection heat transfer, oblique fracture water flow and vertical fracture water flow near the heat source control the temperature field.
引文
陈必光,宋二祥,程晓辉.2014.二维裂隙岩体渗流传热的离散裂隙网络模型数值计算方法[J].岩石力学与工程学报,1(33):43-51.
董海洲,罗日洪,张令.2013.岩石单裂隙渗流-传热模型及其参数敏感性分析[J].河海大学学报(自然科学版),41(1):42-46.
高俊义,项彦勇.2016.稀疏不规则裂隙岩体模型三维水流-传热对温度和应力影响的试验研究[J].岩土力学,37(11):3145-3154.
高俊义,项彦勇.2017.裂隙岩体交叉水流-传热对温度影响的数值分析[J].地下空间与工程学报,13(S2):598-604.
贾梅兰,李洪辉,毛亮,等.2018.间隙对于地质处置近场温度分布的影响[C]//第七届废物地下处置学术研讨会论文集.
梁海安,王瑜,张敏思,等.2018.高放废物地质处置库黏土岩渗流-应力耦合特性实验研究[C]//第七届废物地下处置学术研讨会论文集.
刘月妙,曹胜飞,谢敬礼,等.2018.高放废物地质处置库缓冲材料多场耦合模型试验设计方法[C]//第七届废物地下处置学术研讨会论文集.
龙伟,童富果,李彪.2014.裂隙岩体水-岩耦合传热研究[J].三峡大学学报(自然科学版),36(3):29-31.
路威,项彦勇,唐超.2011.填砂裂隙岩体渗流传热模型试验与数值模拟[J].岩土力学,32(11):3448-3454.
倪绍虎,何世海,汪小刚,等.2012.裂隙岩体水力学特性研究[J].岩石力学与工程学报,31(3):488-497.
速宝玉,詹美礼,张祝添.1994.充填裂隙渗流特性试验研究[J].岩土力学,15(4):46-51.
徐维生,周创兵.2014.岩体裂隙网络渗流变水温影响分析[J].岩土力学,35(1):204-210.
张树光,李志建,徐义洪,等.2011.裂隙岩体流-热耦合传热的三维数值模拟分析[J].岩土力学,32(8):2507-2511.
朱峰,高学农.2015.温度对环氧树脂热物性影响的研究[J].广东化工,42(299):4-5.
Gens A,Sánchez M,Don Guimar?es L,et al.2009.A full-scale in situ heating test for high-level nuclear waste disposal:observations,analysis and interpretation[J].Ge′otechnique,59(4):377-399.
Ivars D M.2006.Water inflow into excavations in fractured rock-Athree-dimensional hydro-mechanical numerical study[J].International Journal of Rock Mechanics and Mining Sciences,(05):705-725.
Maheshwar S,Verma A K,Singh T N,et al.2015.Study of thermo-hydromechanical processes at a potential site of an Indian nuclear waste repository[J].J.Earth Syst.,124(8):1693-1708.
Selvadurai A P S,Suvorov A P and Selvadurai P A.2015.Thermohydro-mechanical processes in fractured rock formations during a glacial advance[J].Geosci.Model Dev.,8:2167-2185.
Thomas H R,Vardon P J and Cleall P J.2014.Three-dimensional behaviour of a prototype radioactive waste repository in fractured granitic rock[J].Can.Geotech.J.,51:246-259.
董海洲,罗日洪,张令.2013.岩石单裂隙渗流-传热模型及其参数敏感性分析[J].河海大学学报(自然科学版),41(1):42-46.
高俊义,项彦勇.2016.稀疏不规则裂隙岩体模型三维水流-传热对温度和应力影响的试验研究[J].岩土力学,37(11):3145-3154.
高俊义,项彦勇.2017.裂隙岩体交叉水流-传热对温度影响的数值分析[J].地下空间与工程学报,13(S2):598-604.
贾梅兰,李洪辉,毛亮,等.2018.间隙对于地质处置近场温度分布的影响[C]//第七届废物地下处置学术研讨会论文集.
梁海安,王瑜,张敏思,等.2018.高放废物地质处置库黏土岩渗流-应力耦合特性实验研究[C]//第七届废物地下处置学术研讨会论文集.
刘月妙,曹胜飞,谢敬礼,等.2018.高放废物地质处置库缓冲材料多场耦合模型试验设计方法[C]//第七届废物地下处置学术研讨会论文集.
龙伟,童富果,李彪.2014.裂隙岩体水-岩耦合传热研究[J].三峡大学学报(自然科学版),36(3):29-31.
路威,项彦勇,唐超.2011.填砂裂隙岩体渗流传热模型试验与数值模拟[J].岩土力学,32(11):3448-3454.
倪绍虎,何世海,汪小刚,等.2012.裂隙岩体水力学特性研究[J].岩石力学与工程学报,31(3):488-497.
速宝玉,詹美礼,张祝添.1994.充填裂隙渗流特性试验研究[J].岩土力学,15(4):46-51.
徐维生,周创兵.2014.岩体裂隙网络渗流变水温影响分析[J].岩土力学,35(1):204-210.
张树光,李志建,徐义洪,等.2011.裂隙岩体流-热耦合传热的三维数值模拟分析[J].岩土力学,32(8):2507-2511.
朱峰,高学农.2015.温度对环氧树脂热物性影响的研究[J].广东化工,42(299):4-5.
Gens A,Sánchez M,Don Guimar?es L,et al.2009.A full-scale in situ heating test for high-level nuclear waste disposal:observations,analysis and interpretation[J].Ge′otechnique,59(4):377-399.
Ivars D M.2006.Water inflow into excavations in fractured rock-Athree-dimensional hydro-mechanical numerical study[J].International Journal of Rock Mechanics and Mining Sciences,(05):705-725.
Maheshwar S,Verma A K,Singh T N,et al.2015.Study of thermo-hydromechanical processes at a potential site of an Indian nuclear waste repository[J].J.Earth Syst.,124(8):1693-1708.
Selvadurai A P S,Suvorov A P and Selvadurai P A.2015.Thermohydro-mechanical processes in fractured rock formations during a glacial advance[J].Geosci.Model Dev.,8:2167-2185.
Thomas H R,Vardon P J and Cleall P J.2014.Three-dimensional behaviour of a prototype radioactive waste repository in fractured granitic rock[J].Can.Geotech.J.,51:246-259.
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