煤矿底板突水机理与底板突水实时监测技术研究
摘要
华北石炭二迭系煤田是我国重要的产煤区之一,其下组煤位于含水丰富的奥灰含水层或太原群灰岩含水层以上,中间隔水层厚约30~100米,经常发生底板灰岩突水。
由于煤矿底板突水是在矿井开发中一种严重的地质灾害现象,因而受到国内外的广泛重视,通过研究人们认识到突水是可以预测预报的,因为发生突水的物质基础和物理基础是可以被认识的。鉴于突水直接影响到煤矿的生产安全对底板突水机理的研究及突水预测预报技术研究成为承压水上采煤的关键技术。本文分两大部分对底板突水的机理、突水预测预报的理论基础、具体的突水预测预报技术进行理论和应用研究。文中第一部分根据底板突水的机理设计了岩体水力学实验,对岩体裂隙的三轴应力渗透规律进行了研究,指出岩体裂隙突水时,岩体裂隙的渗透系数与裂隙正应力不是负指数关系,渗透系数有突然增大的现象。并利用岩石断裂力学理论对此现象进行了解释,指出在岩体应力和水压力的作用下,岩体裂隙发生拉-张型扩展(K_Ⅰ型)是裂隙渗透系数突然增大的关键原因。沿裂隙发生剪切(K_Ⅱ型)扩展,使充填物微观结构破坏而增强空隙度和渗透性,则对突水的贡献是次要的。由此推论,煤层底板突水主要是由于底板裂隙发生拉-张型扩展,继而在水压力的作用下沿裂隙发生管涌现象而造成的。在分析煤矿底板突水地质背景的基础上,指出利用线弹性断裂力学对底板突水进行分析是合适的,通过研究确定了底板突水的断裂力学标准。具体分析了构造应力场、工程应力、地下水等对底板裂隙应力强度因子的影响,从断裂力学的角度分析各种因素对底板突水的影响。
利用裂隙的亚临界扩展理论对底板滞后突水现象进行了分析。裂隙中的粘土充填物在地下水物理、化学的作用下,力学性能不断弱化,使岩体裂隙的临界应力强度因子不断降低,裂隙扩展具有时间效应,导致底板裂隙的滞后突水。
在对水压致裂技术进行断裂力学分析的基础上,推导了计算岩体裂隙临界应力强度因子的计算公式,确定了用水压致裂技术测定临界应力强度因子的方法,为利用岩石断裂力学标准进行突水判别奠定了理论和实验基础。
文中介绍了板壳断裂力学理论Kirchhoff及Reissner弯曲断裂理论。板壳承
受横向载荷,除了有面内位移外,还存在面外位移。板壳内的应力应变场沿厚度方
向变化。Rei Ssner弯曲断裂理论考虑了板壳的横向剪切变形和板的厚度效应,更
适合于采煤工作面底板的模拟。介绍了Rei ssner裂纹应力强度因子的计算方法,并
通过简单模型计算分析了板边长、板厚度、水压对应力强度因子的影响,证明板厚
度、水压对应力强度因子的影响巨大。
应用板壳断裂力学的方法分析工作面底板岩体在工程荷载的作用下引起裂隙扩
展而导致的突水问题,为分析底板岩体的突水问题提供了一条新的途径。
论文第二部分结合东庞矿9103工作面的带压开采,研究了底板工作面斜长的
确定方法;利用水压致裂技术求得了底板临界应力强度因子,结合工作面的实际水
文地质工程地质条件研究了底板突水前兆实时监测技术,监测的项目包括应力、应
变水压、水温,对9103工作面进行了21天的监测,利用第一部分的研究成果对监
测数据处理,计算了底板裂隙应力强度因子,运用断裂力学突水判别标准,判断9103
工作面不会突水,9103工作面实际回采结果与此相符。
The carboniferous and Permian coal field is a important coal field in china .The substrate coal bed is on the top of the Ordovician and carboniferous limestone aquifers .the a quatard between the aquifer and the coal is about 30-60meters thick .So floor water bursting occurs usually.
The floor water bursting is a geology hazard in coal mines in the east of china .But the water bursting can be predicted ,because the physical mechanism of water bursting can be studied . So the research on the water bursting mechanism and forecasting technique become the key technique of coal mining on top of the high pressure aquifer . In the dissertation the water bursting mechanism, water bursting theory and predicting technique are researched .
In the first part of the dissertation, the rock -hydraulic experiment is devised according to water bursting essence, and the stress-permeability under triaxial compression is studied , which indicates that the permeability coefficient is inversely proportional to the virtual direct stress ,and the permeability coefficient changes suddenly on some conditions .The phenomenon is explained according to the fracture mechanism ,which indicates the rock crevice stretches and spreads under the rock stress and hydraulic pressure .So the rock crevice permeability increases suddenly .The shearing spreading along the crevice which destruct the microstucture and increase the permeability is subordinate .It is pointed that analyzing the floor water bursting according to the fracture mechanism is adaptable when the geology condition and the fracture mechanic criterion of water bursting is decided .
The influence of the tectonic stress field .engineering stress and groundwater to the crevice stress intensity factors are analyzed. The phenomenon of the lagging water bursting is explained applying crevice inferior critical spreading .The mechanic capability of the crevice clay filling falls because the physiology and chemistry of the groundwater,which lags the crevice spreading and leads to the lagging floor water bursting.
On the basis of explaining hydraulic fracture technique applying fracture mechanics theory ,the computation equation of the critical stress intensity factor is deduced .So the testing method is obtained according to the theory, which lay a foundation of theory and experiments for distinguishing water bursting applying fracture theory.
The Kirchhoff and Reissner board bending fracture theory is introduced in the dissertation .The board endure transverse load ,which produce inner and outer displacement .The stress and strain in the board changes in the direction of thickness .Not only the board transverse shearing distortion but also the thickness is considered in Reissner board bending fracture theory .So Reissner theory is adapted to simulate the mining face floor .the computation of the crevice stress intensity factor is studied. The influence of the board width ,thickness and sustaining condition to the stress intensity factor is analyzed by ordinary model computation .the computation indicates the board thickness ,water pressure exert a tremendous influence to the stress intensity factor.
In the second part of the dissertation, the delimiting method of the stope width mining on high pressure aquifer is decided for the example of 9103 stope in Dong Pang Coal Mine .The critical stress intensity factor is tested applying the hydraulic fracture technique .The technique of monitoring face floor water bursting indications is researched on the basis of studying the practical hydrogeology and engineering geology condition .The 9103 stope is monitored for 21 days .The monitoring data is analyzed applying the Reissner board bending fracture theory ,and the floor stress intensity factor is computed .Applying the floor water bursting criterion of fracture mechanics , it is concluded that the stope water bursting will not arise .The mining practice of the stope proves the conclusion right.
由于煤矿底板突水是在矿井开发中一种严重的地质灾害现象,因而受到国内外的广泛重视,通过研究人们认识到突水是可以预测预报的,因为发生突水的物质基础和物理基础是可以被认识的。鉴于突水直接影响到煤矿的生产安全对底板突水机理的研究及突水预测预报技术研究成为承压水上采煤的关键技术。本文分两大部分对底板突水的机理、突水预测预报的理论基础、具体的突水预测预报技术进行理论和应用研究。文中第一部分根据底板突水的机理设计了岩体水力学实验,对岩体裂隙的三轴应力渗透规律进行了研究,指出岩体裂隙突水时,岩体裂隙的渗透系数与裂隙正应力不是负指数关系,渗透系数有突然增大的现象。并利用岩石断裂力学理论对此现象进行了解释,指出在岩体应力和水压力的作用下,岩体裂隙发生拉-张型扩展(K_Ⅰ型)是裂隙渗透系数突然增大的关键原因。沿裂隙发生剪切(K_Ⅱ型)扩展,使充填物微观结构破坏而增强空隙度和渗透性,则对突水的贡献是次要的。由此推论,煤层底板突水主要是由于底板裂隙发生拉-张型扩展,继而在水压力的作用下沿裂隙发生管涌现象而造成的。在分析煤矿底板突水地质背景的基础上,指出利用线弹性断裂力学对底板突水进行分析是合适的,通过研究确定了底板突水的断裂力学标准。具体分析了构造应力场、工程应力、地下水等对底板裂隙应力强度因子的影响,从断裂力学的角度分析各种因素对底板突水的影响。
利用裂隙的亚临界扩展理论对底板滞后突水现象进行了分析。裂隙中的粘土充填物在地下水物理、化学的作用下,力学性能不断弱化,使岩体裂隙的临界应力强度因子不断降低,裂隙扩展具有时间效应,导致底板裂隙的滞后突水。
在对水压致裂技术进行断裂力学分析的基础上,推导了计算岩体裂隙临界应力强度因子的计算公式,确定了用水压致裂技术测定临界应力强度因子的方法,为利用岩石断裂力学标准进行突水判别奠定了理论和实验基础。
文中介绍了板壳断裂力学理论Kirchhoff及Reissner弯曲断裂理论。板壳承
受横向载荷,除了有面内位移外,还存在面外位移。板壳内的应力应变场沿厚度方
向变化。Rei Ssner弯曲断裂理论考虑了板壳的横向剪切变形和板的厚度效应,更
适合于采煤工作面底板的模拟。介绍了Rei ssner裂纹应力强度因子的计算方法,并
通过简单模型计算分析了板边长、板厚度、水压对应力强度因子的影响,证明板厚
度、水压对应力强度因子的影响巨大。
应用板壳断裂力学的方法分析工作面底板岩体在工程荷载的作用下引起裂隙扩
展而导致的突水问题,为分析底板岩体的突水问题提供了一条新的途径。
论文第二部分结合东庞矿9103工作面的带压开采,研究了底板工作面斜长的
确定方法;利用水压致裂技术求得了底板临界应力强度因子,结合工作面的实际水
文地质工程地质条件研究了底板突水前兆实时监测技术,监测的项目包括应力、应
变水压、水温,对9103工作面进行了21天的监测,利用第一部分的研究成果对监
测数据处理,计算了底板裂隙应力强度因子,运用断裂力学突水判别标准,判断9103
工作面不会突水,9103工作面实际回采结果与此相符。
The carboniferous and Permian coal field is a important coal field in china .The substrate coal bed is on the top of the Ordovician and carboniferous limestone aquifers .the a quatard between the aquifer and the coal is about 30-60meters thick .So floor water bursting occurs usually.
The floor water bursting is a geology hazard in coal mines in the east of china .But the water bursting can be predicted ,because the physical mechanism of water bursting can be studied . So the research on the water bursting mechanism and forecasting technique become the key technique of coal mining on top of the high pressure aquifer . In the dissertation the water bursting mechanism, water bursting theory and predicting technique are researched .
In the first part of the dissertation, the rock -hydraulic experiment is devised according to water bursting essence, and the stress-permeability under triaxial compression is studied , which indicates that the permeability coefficient is inversely proportional to the virtual direct stress ,and the permeability coefficient changes suddenly on some conditions .The phenomenon is explained according to the fracture mechanism ,which indicates the rock crevice stretches and spreads under the rock stress and hydraulic pressure .So the rock crevice permeability increases suddenly .The shearing spreading along the crevice which destruct the microstucture and increase the permeability is subordinate .It is pointed that analyzing the floor water bursting according to the fracture mechanism is adaptable when the geology condition and the fracture mechanic criterion of water bursting is decided .
The influence of the tectonic stress field .engineering stress and groundwater to the crevice stress intensity factors are analyzed. The phenomenon of the lagging water bursting is explained applying crevice inferior critical spreading .The mechanic capability of the crevice clay filling falls because the physiology and chemistry of the groundwater,which lags the crevice spreading and leads to the lagging floor water bursting.
On the basis of explaining hydraulic fracture technique applying fracture mechanics theory ,the computation equation of the critical stress intensity factor is deduced .So the testing method is obtained according to the theory, which lay a foundation of theory and experiments for distinguishing water bursting applying fracture theory.
The Kirchhoff and Reissner board bending fracture theory is introduced in the dissertation .The board endure transverse load ,which produce inner and outer displacement .The stress and strain in the board changes in the direction of thickness .Not only the board transverse shearing distortion but also the thickness is considered in Reissner board bending fracture theory .So Reissner theory is adapted to simulate the mining face floor .the computation of the crevice stress intensity factor is studied. The influence of the board width ,thickness and sustaining condition to the stress intensity factor is analyzed by ordinary model computation .the computation indicates the board thickness ,water pressure exert a tremendous influence to the stress intensity factor.
In the second part of the dissertation, the delimiting method of the stope width mining on high pressure aquifer is decided for the example of 9103 stope in Dong Pang Coal Mine .The critical stress intensity factor is tested applying the hydraulic fracture technique .The technique of monitoring face floor water bursting indications is researched on the basis of studying the practical hydrogeology and engineering geology condition .The 9103 stope is monitored for 21 days .The monitoring data is analyzed applying the Reissner board bending fracture theory ,and the floor stress intensity factor is computed .Applying the floor water bursting criterion of fracture mechanics , it is concluded that the stope water bursting will not arise .The mining practice of the stope proves the conclusion right.
引文
[1] 李兴高、高延法.采场底板岩层破坏与损伤分析.岩石力学与工程学报,22(1),Jan.,2003。
[2] [英]B.K.阿特金森,岩石断裂力学.北京:地震出版社,1992:231—253.
[3] 陆毅中.工程断裂力学.西安,西安交通大学出版社,1987.1.
[4] 高庆.工程断裂力学,重庆,重庆大学出版社,1986.8.
[5] 孙广忠.工程地质与地质工程[M].北京:地震出版社,1993,142-145.
[6] 仵彦卿,张倬元等.岩体水力学导论[M].成都:西南交通大学出版社,1995,51~57.
[7] 徐芝纶.弹性力学[M].北京:高等教育出版社,1978,245-249.
[8] 王连国,宋杨.煤层底板突水的突变模型[J].工程地质学报,2000,(6).
[9] 刘均,郭志.岩体力学试验的理论分析[J].工程地质学报,1997,(6).
[10] 许兵.关于岩体结构力学基本观点探讨[J].工程地质学报,1997,(12).
[11] 孙广忠.论岩体结构控制论[J].工程地质学报,1993.Vol,1,No,1.
[12] 孙广忠.地质工程理论与实践.地震出版社,1996:80-81.
[13] 国家煤矿安全监察局.煤矿安全规程.煤炭工业出版社,2001:137-150.
[14] 粟一凡.材料力学.北京:高等教育出版社,1986:228-232
[15] 许学汉,王杰等.煤矿突水预报研究.北京:地质出版社,1991.
[16] 柳春图、蒋持平.板壳断裂力学.北京:国防工业出版社,2000.
[17] 柳春图.Reissner型中厚板在弯曲问题中裂纹尖端附近应力应变场.中国科学院力学研究所工作报告,1980.
[18] 柳春图.承受弯曲的板在裂纹尖端的应力和变形.固体力学学报,1983,4(3),441-448.
[19] 柳春图,李英治.Reissner型板裂纹尖端的应力应变场及应力强度因子的计算.力学学报,1987,19(2):125-135.
[21] 中国科学研究院.应力强度因子手册,北京:科学出版社,1981.
[22] 柳春图,李英治.平面弯曲断裂问题的研究进展.力学发展,1982,12(4),346—359
[23] 柳春图,李英治.含裂纹板壳及三维裂纹体断裂问题的研究进展.力学发展,1986,16(2),185-193.
[24] Irwin G R. Analysis of stresses and strains near the end of a crack traversing a plate.J Appl Mech, 1957,24,361-364.
[25] 谷德振.地质构造与工程建设.科学通报,1963,No.10.
[26] Knowles, J,K. and,N. M.on the bending of an elastic plate containing a crack.J. Math.Phys.1960(39),223.
[27] R. J. Hartranft, G. C. sih, effect of plate thickness on the bending stress distribution around through crack. J. Math.Phys.1967.
[28] Reissner E. on bending of elastic plate .Quarterly AppIMath ,1947, 5,55-68.
[28] 柳春图,张端重.Reissner型板中应力强度因子的近似方程和近似解法.力学学报,1988,20(6),515-521.
[29] 黄克智等.板壳理论.北京:清华大学出版社,1987,407.
[30] 徐芝纶.弹性力学下册.北京:人民教育出版社,1979,377.
[31] 蒋持平,刘习文,王辉.一类应力强度因子的实用价值.北京航空航天大学学报.1996,22(4);448-453.
[32] 陈卫中,李术才,朱维申.岩石裂纹扩展的试验和数值分析研究.岩石力学和工程学报,2003,22(1),18-23.
[33] 郭中华,王炜,陆健等.砂浆-灰岩双向材料剪切强度及压剪断裂判据探析.岩石力学和工程学报,2003,22(3),429-433.
[34] 李兴高,高延法.采场底板岩层破坏与损伤分析.岩石力学和工程学报,2003,22(1),35-39.
[36] 汤连声,张鹏程,王思敬.水岩化学作用之岩石断裂力学的实验研究.岩石力学和工程学报,2002,21(6),822-827.
[37] 陈纲林,周仁德.水对受力岩石变形破坏宏观力学效应的实验研究[J].地球物理学报,1991,34(3),335-342.
[38] 汤连声,王思敬.水岩化学作用对岩体变形破坏力学效应研究进展[J].地球科学进展,1999,14(5),433-439.
[39] Colback P S B,wild B L.influence of moisture content on the compressive strength of rock.Proc.3rd Canadian Rockmech.Symp.[C].Canada:A.A. Balkema, 1965,385-391.
[40] 王泳嘉,冯夏庭.化学环境侵蚀下的岩石破裂特性-第二部分,时间分形研究[J].岩石力学与工程学报,2000,19(5),551-556.
[41] 汤连声,张鹏程,王思敬.水岩化学作用之岩石宏观力学的实验研究.岩石力学和工程学报,2002,21(6),822-827.
[42] Dunning J,Douglas B, Miller M ,et al.the role of thechemical environment in friction deformation.stress corrosion cracking and comminution [J].Pure.ApplGeophys, 1994, 143(1/2/3): 151-178.
[43] Logan J M, Black well M I. the influence of chemically active fluids on the frictional behavior of sandstone [J]. EOS, trans. AM Geophys. Union, 1983, 64 (2), 835-837.
[44] 汤连声,王思敬.岩石水化学损伤的机理及量化方法探讨。岩石力学和工程学报,2001,20(3),314-319.
[45] 杨天鸿,唐春安,朱万成,冯其言。岩石破裂过程渗流与应力的耦合分析.岩土工程学报,2001,23(4),489-493.
[46] 刘保县,鲜学富,姜德义.煤与瓦斯突出机理及其预测预报的研究.岩石力学和工程学报,2002,21(5),647-650.
[47] 刘亚晨,蔡永庆,刘泉声,吴玉山.温度饱和水下的裂隙岩体力学特性研究.岩石力学和工程学报,2002,21(2),233-237.
[48] 姜振泉,季梁军,左如松,曹丽文.岩石在伺服条件下的渗透性与应变、应力的关联性特征.岩石力学和工程学报,2002,21(10),1442-1446.
[49] 石平五.发展科学监测体系,制止矿山重大事故.煤炭学报,2002:27(3),225-227.
[50] 倪宏革,罗国煜.地下开采中优势面控水控稳机制分析.工程地质学报,2000,08(03),316-319.
[51] 许兵.工程地质基本理论座谈综述.工程地质学报,2003,11(03),334-336.
[52] 朱维申,李术才,白世伟,刘泉声.施工过程力学原理的若干发展和工程实例分析.
岩石力学和工程学报,2003,22(10),1586-1591.
[53] 吴刚.工程岩体卸荷破坏机制研究的现状及展望.工程地质学报,2001,9(2),175—180.
[54] 徐继善.强度理论及其应用[M].北京:水利电力出版社,1984.
[55] 郑永学.矿山岩体力学[M].北京:冶金工业出版社,1988.
[56] 林天健.岩石力学若干假说及其工程意义评述.力学与实践,1989,11(6),64-70
[57] Griffith A. A. The phenomena of rupture and flow in solids [J].Phil.Trans.Roy Soc.,London:1921, A221:163-198.
[58] Griffith A. A. theory of rupture [A].Proc. first Int .congress Appl. Mech. [C],1924, Delft:55-63.
[59] 尹光志,李贺,鲜学富.工程应力变化对岩石强度特性影响的实验研究[J].岩土工程学报,1987,9(2):20-27.
[60] 杨延毅.节理裂隙岩体损伤-断裂力学模型及其在岩体工程中的应用(博士学位论文)[D],北京:清华大学,1990.
[61] 唐春安,徐小荷.岩石破裂过程失稳的尖点灾变模型.岩石力学和工程学报,1990,9(2),100-107.
[62] 陶振宇,试论岩石力学的最新进展[J].力学进展,1992,22(2):161-172.
[63] 郭志.岩体变形和破坏机制研究.工程地质力学研究,地质出版社,1985.
[64] 郭志.岩石微结构的力学效应.水文地质工程地质.地质出版社,1987.
[65] 孙广忠.岩体结构力学.北京:科学出版社,1988.
[66] 郑雨天等.岩石力学实验建议方法.北京:煤炭工业出版社,1980.
[67] 高航,孙振鹏.煤层底板采动影响的研究.山东矿业学院学报,NO.1,1987.
[68] 蒋金泉,宋振骐.回采工作面底板活动及其对突水影响的研究.山东矿业学院学报,No.4,1987.
[69] 谷德振.岩体工程地质力学基础.北京:科学出版社,1979.
[70] 罗灼礼.震源孕育过程的讨论.自然科学争鸣,NO.6,1977.
[71] 许学汉,岩体抗剪结构效应试验研究.工程地质科学新进展,成都科技大学出版社,1989.
[72] Irwin,G.R.,Fracture Dynamics, Fracture of metals,ASM (1948),147-166.
[73] 黄克智,余寿文.弹塑性断裂力学,清华大学出版社,1985.
[74] 曲永新.泥质岩的工程分类和膨胀势的快速预报.水文地质工程地质,1988(5).
[75] 余定声,吴玉庚.裂隙岩体的地质力学模型试验研究.岩体工程地质力学问题(八),科学出版社,1987.
[76] 穆斯海立什维,赵惠元.数学弹性力学的几个基本问题,科学出版社,1958.
[77] 煤炭科学研究总院西安分院.华北型煤田奥灰岩溶水综合防治工业性试验二期实验工程技术成果报告配套技术之二,1995.
[78] [英]B.R.劳恩,T.R威尔肖.脆性固体断裂力学.地震出版社,1985,47-52.
[79] [澳]J.C.耶格.弹性断裂和流变.地震出版社,1982,160-182.
[80] S.铁摩辛柯,S.沃诺斯基.板壳理论.科学出版社,1977,389-397.
[81] 蒋持平,刘习文,王辉.一类应力强度因子的实用价值.
[82] Timosschenko S and woinowsky-kriege S. Theory of plates and shells. Newyork:McGraw-Hill book company, 1959.
[83] Williams M L. The bending stress distribution at the base of a stanionary crack .J APPL Mech ,1961,28:78-82.
[84] sih G C,Pris P C,Erdogan F. crack tip,stress -intensity factors for plane extention and plate bending problem ,J Appl Mech ,1962,29:306-310.
[85] Jiang c p and Liu C T .A new analytical technique for the linear hardening mertirials with a surface crack.Computational Mechanics,brook field: backema publisher ,1991,963-967.
[86] Liu C T .Analysis of cracked plates and shells ,and its application in engineering .In proc of ICF 7, Houston ,1989,3-22.
[87] Sih G C ed.Mechanics of fracture 3: plates and shells with cracks. Leyden :Noorhoff .International publishing ,1977,302.
[88] Sih G C. Handbook of stress intensity factors ,1973.
[89] Tadn,H.paris ,P .C and Irwin,G,R.,The stress analysis of cracks handbook ,1973, Del Research corp .,Hellertown ,pa.
[90] Eekelen,van, H. A.M (1982).Hydraulic Frackture Geometry:fractue containment in layerecs formations. SPE/AIME, 341-349.
[91] Gowd ,T. N. and Rummel, F. (1983).In-situ sress measurementas by hydraulic fracturing in the underground mines of Kolar Gold fields ,India. 2nd kep, Indo-german colloboration project, KFA Julich, 1983.
[92] 余贤斌,杨锦灿,李汉宜。桥后盐矿巷道变形收敛观测及结果分析[J].昆明工学院学报,1994,19(5).
[93] 靳晓光,王兰生,李晓江.地下工程围岩二次应力场的现场测试与监测[J].岩石力学与工程学报,2002,21(5),651-653.
[94] 徐林生,孙均,蒋树屏.洋碰隧道进口右线施工中现场监控量测[J].岩石力学与工程学报,2002,21(5),675-678.
[95] 王立中,胡亚元,王柏林等.崩塌松散围岩隧道施工稳定分析与监控[J].岩石力学与工程学报,2003,22(4),589-595.
[96] 王成、邓安福.岩体内压致裂解析研究[J].岩石力学与工程报,2002(5):640~643.
[97] 刘宝县,鲜学富,善德义.煤与瓦斯延期突出机理及预测预报研究[J].岩石力学与工程学报,2002,21(5),647-650.
[98] 刘允芳,钟作武,汪洁.水压致裂三维地应力测量结果计算与分析的探讨[J].岩石力学与工程学报,2002,21(6),833-838.
[99] 罗国煜,阎长虹,李晓昭等.新世纪中叶中国工程地质回顾与展望.[J].岩石力学与工程学报,2002,10(1),3-9.
[100] 刘桂雄、申柏华等,迅速崛起的网络智能化传感技术。传感器技术,2002,21(9):4—7.
[101] 侯美丽、王晓娟等.先进的集成微型传感器的研究进展.传感器技术,2002,21(10),1-3.
[102] 肖正学,张志呈,郭学彬.断裂控制爆破裂纹扩展规律的研究.[J].岩石力学与工程学报,2002,21(4),546-549.
[103] 肖洪天,周维垣.脆性岩石变形与破坏的细观力学模型研究.岩石力学与工程学报.岩石力学与工程学报,2001,20(2):151-155.
[104] 郑少河,朱维申.裂隙岩体渗流损伤耦合模型的理论分析.岩石力学与工程学报,2001,20(2):156-159.
[105] 金衍,陈勉.利用测井资料预测深部地层岩石断裂韧性.岩石力学与工程学报,2001,20(4):454-456.
[2] [英]B.K.阿特金森,岩石断裂力学.北京:地震出版社,1992:231—253.
[3] 陆毅中.工程断裂力学.西安,西安交通大学出版社,1987.1.
[4] 高庆.工程断裂力学,重庆,重庆大学出版社,1986.8.
[5] 孙广忠.工程地质与地质工程[M].北京:地震出版社,1993,142-145.
[6] 仵彦卿,张倬元等.岩体水力学导论[M].成都:西南交通大学出版社,1995,51~57.
[7] 徐芝纶.弹性力学[M].北京:高等教育出版社,1978,245-249.
[8] 王连国,宋杨.煤层底板突水的突变模型[J].工程地质学报,2000,(6).
[9] 刘均,郭志.岩体力学试验的理论分析[J].工程地质学报,1997,(6).
[10] 许兵.关于岩体结构力学基本观点探讨[J].工程地质学报,1997,(12).
[11] 孙广忠.论岩体结构控制论[J].工程地质学报,1993.Vol,1,No,1.
[12] 孙广忠.地质工程理论与实践.地震出版社,1996:80-81.
[13] 国家煤矿安全监察局.煤矿安全规程.煤炭工业出版社,2001:137-150.
[14] 粟一凡.材料力学.北京:高等教育出版社,1986:228-232
[15] 许学汉,王杰等.煤矿突水预报研究.北京:地质出版社,1991.
[16] 柳春图、蒋持平.板壳断裂力学.北京:国防工业出版社,2000.
[17] 柳春图.Reissner型中厚板在弯曲问题中裂纹尖端附近应力应变场.中国科学院力学研究所工作报告,1980.
[18] 柳春图.承受弯曲的板在裂纹尖端的应力和变形.固体力学学报,1983,4(3),441-448.
[19] 柳春图,李英治.Reissner型板裂纹尖端的应力应变场及应力强度因子的计算.力学学报,1987,19(2):125-135.
[21] 中国科学研究院.应力强度因子手册,北京:科学出版社,1981.
[22] 柳春图,李英治.平面弯曲断裂问题的研究进展.力学发展,1982,12(4),346—359
[23] 柳春图,李英治.含裂纹板壳及三维裂纹体断裂问题的研究进展.力学发展,1986,16(2),185-193.
[24] Irwin G R. Analysis of stresses and strains near the end of a crack traversing a plate.J Appl Mech, 1957,24,361-364.
[25] 谷德振.地质构造与工程建设.科学通报,1963,No.10.
[26] Knowles, J,K. and,N. M.on the bending of an elastic plate containing a crack.J. Math.Phys.1960(39),223.
[27] R. J. Hartranft, G. C. sih, effect of plate thickness on the bending stress distribution around through crack. J. Math.Phys.1967.
[28] Reissner E. on bending of elastic plate .Quarterly AppIMath ,1947, 5,55-68.
[28] 柳春图,张端重.Reissner型板中应力强度因子的近似方程和近似解法.力学学报,1988,20(6),515-521.
[29] 黄克智等.板壳理论.北京:清华大学出版社,1987,407.
[30] 徐芝纶.弹性力学下册.北京:人民教育出版社,1979,377.
[31] 蒋持平,刘习文,王辉.一类应力强度因子的实用价值.北京航空航天大学学报.1996,22(4);448-453.
[32] 陈卫中,李术才,朱维申.岩石裂纹扩展的试验和数值分析研究.岩石力学和工程学报,2003,22(1),18-23.
[33] 郭中华,王炜,陆健等.砂浆-灰岩双向材料剪切强度及压剪断裂判据探析.岩石力学和工程学报,2003,22(3),429-433.
[34] 李兴高,高延法.采场底板岩层破坏与损伤分析.岩石力学和工程学报,2003,22(1),35-39.
[36] 汤连声,张鹏程,王思敬.水岩化学作用之岩石断裂力学的实验研究.岩石力学和工程学报,2002,21(6),822-827.
[37] 陈纲林,周仁德.水对受力岩石变形破坏宏观力学效应的实验研究[J].地球物理学报,1991,34(3),335-342.
[38] 汤连声,王思敬.水岩化学作用对岩体变形破坏力学效应研究进展[J].地球科学进展,1999,14(5),433-439.
[39] Colback P S B,wild B L.influence of moisture content on the compressive strength of rock.Proc.3rd Canadian Rockmech.Symp.[C].Canada:A.A. Balkema, 1965,385-391.
[40] 王泳嘉,冯夏庭.化学环境侵蚀下的岩石破裂特性-第二部分,时间分形研究[J].岩石力学与工程学报,2000,19(5),551-556.
[41] 汤连声,张鹏程,王思敬.水岩化学作用之岩石宏观力学的实验研究.岩石力学和工程学报,2002,21(6),822-827.
[42] Dunning J,Douglas B, Miller M ,et al.the role of thechemical environment in friction deformation.stress corrosion cracking and comminution [J].Pure.ApplGeophys, 1994, 143(1/2/3): 151-178.
[43] Logan J M, Black well M I. the influence of chemically active fluids on the frictional behavior of sandstone [J]. EOS, trans. AM Geophys. Union, 1983, 64 (2), 835-837.
[44] 汤连声,王思敬.岩石水化学损伤的机理及量化方法探讨。岩石力学和工程学报,2001,20(3),314-319.
[45] 杨天鸿,唐春安,朱万成,冯其言。岩石破裂过程渗流与应力的耦合分析.岩土工程学报,2001,23(4),489-493.
[46] 刘保县,鲜学富,姜德义.煤与瓦斯突出机理及其预测预报的研究.岩石力学和工程学报,2002,21(5),647-650.
[47] 刘亚晨,蔡永庆,刘泉声,吴玉山.温度饱和水下的裂隙岩体力学特性研究.岩石力学和工程学报,2002,21(2),233-237.
[48] 姜振泉,季梁军,左如松,曹丽文.岩石在伺服条件下的渗透性与应变、应力的关联性特征.岩石力学和工程学报,2002,21(10),1442-1446.
[49] 石平五.发展科学监测体系,制止矿山重大事故.煤炭学报,2002:27(3),225-227.
[50] 倪宏革,罗国煜.地下开采中优势面控水控稳机制分析.工程地质学报,2000,08(03),316-319.
[51] 许兵.工程地质基本理论座谈综述.工程地质学报,2003,11(03),334-336.
[52] 朱维申,李术才,白世伟,刘泉声.施工过程力学原理的若干发展和工程实例分析.
岩石力学和工程学报,2003,22(10),1586-1591.
[53] 吴刚.工程岩体卸荷破坏机制研究的现状及展望.工程地质学报,2001,9(2),175—180.
[54] 徐继善.强度理论及其应用[M].北京:水利电力出版社,1984.
[55] 郑永学.矿山岩体力学[M].北京:冶金工业出版社,1988.
[56] 林天健.岩石力学若干假说及其工程意义评述.力学与实践,1989,11(6),64-70
[57] Griffith A. A. The phenomena of rupture and flow in solids [J].Phil.Trans.Roy Soc.,London:1921, A221:163-198.
[58] Griffith A. A. theory of rupture [A].Proc. first Int .congress Appl. Mech. [C],1924, Delft:55-63.
[59] 尹光志,李贺,鲜学富.工程应力变化对岩石强度特性影响的实验研究[J].岩土工程学报,1987,9(2):20-27.
[60] 杨延毅.节理裂隙岩体损伤-断裂力学模型及其在岩体工程中的应用(博士学位论文)[D],北京:清华大学,1990.
[61] 唐春安,徐小荷.岩石破裂过程失稳的尖点灾变模型.岩石力学和工程学报,1990,9(2),100-107.
[62] 陶振宇,试论岩石力学的最新进展[J].力学进展,1992,22(2):161-172.
[63] 郭志.岩体变形和破坏机制研究.工程地质力学研究,地质出版社,1985.
[64] 郭志.岩石微结构的力学效应.水文地质工程地质.地质出版社,1987.
[65] 孙广忠.岩体结构力学.北京:科学出版社,1988.
[66] 郑雨天等.岩石力学实验建议方法.北京:煤炭工业出版社,1980.
[67] 高航,孙振鹏.煤层底板采动影响的研究.山东矿业学院学报,NO.1,1987.
[68] 蒋金泉,宋振骐.回采工作面底板活动及其对突水影响的研究.山东矿业学院学报,No.4,1987.
[69] 谷德振.岩体工程地质力学基础.北京:科学出版社,1979.
[70] 罗灼礼.震源孕育过程的讨论.自然科学争鸣,NO.6,1977.
[71] 许学汉,岩体抗剪结构效应试验研究.工程地质科学新进展,成都科技大学出版社,1989.
[72] Irwin,G.R.,Fracture Dynamics, Fracture of metals,ASM (1948),147-166.
[73] 黄克智,余寿文.弹塑性断裂力学,清华大学出版社,1985.
[74] 曲永新.泥质岩的工程分类和膨胀势的快速预报.水文地质工程地质,1988(5).
[75] 余定声,吴玉庚.裂隙岩体的地质力学模型试验研究.岩体工程地质力学问题(八),科学出版社,1987.
[76] 穆斯海立什维,赵惠元.数学弹性力学的几个基本问题,科学出版社,1958.
[77] 煤炭科学研究总院西安分院.华北型煤田奥灰岩溶水综合防治工业性试验二期实验工程技术成果报告配套技术之二,1995.
[78] [英]B.R.劳恩,T.R威尔肖.脆性固体断裂力学.地震出版社,1985,47-52.
[79] [澳]J.C.耶格.弹性断裂和流变.地震出版社,1982,160-182.
[80] S.铁摩辛柯,S.沃诺斯基.板壳理论.科学出版社,1977,389-397.
[81] 蒋持平,刘习文,王辉.一类应力强度因子的实用价值.
[82] Timosschenko S and woinowsky-kriege S. Theory of plates and shells. Newyork:McGraw-Hill book company, 1959.
[83] Williams M L. The bending stress distribution at the base of a stanionary crack .J APPL Mech ,1961,28:78-82.
[84] sih G C,Pris P C,Erdogan F. crack tip,stress -intensity factors for plane extention and plate bending problem ,J Appl Mech ,1962,29:306-310.
[85] Jiang c p and Liu C T .A new analytical technique for the linear hardening mertirials with a surface crack.Computational Mechanics,brook field: backema publisher ,1991,963-967.
[86] Liu C T .Analysis of cracked plates and shells ,and its application in engineering .In proc of ICF 7, Houston ,1989,3-22.
[87] Sih G C ed.Mechanics of fracture 3: plates and shells with cracks. Leyden :Noorhoff .International publishing ,1977,302.
[88] Sih G C. Handbook of stress intensity factors ,1973.
[89] Tadn,H.paris ,P .C and Irwin,G,R.,The stress analysis of cracks handbook ,1973, Del Research corp .,Hellertown ,pa.
[90] Eekelen,van, H. A.M (1982).Hydraulic Frackture Geometry:fractue containment in layerecs formations. SPE/AIME, 341-349.
[91] Gowd ,T. N. and Rummel, F. (1983).In-situ sress measurementas by hydraulic fracturing in the underground mines of Kolar Gold fields ,India. 2nd kep, Indo-german colloboration project, KFA Julich, 1983.
[92] 余贤斌,杨锦灿,李汉宜。桥后盐矿巷道变形收敛观测及结果分析[J].昆明工学院学报,1994,19(5).
[93] 靳晓光,王兰生,李晓江.地下工程围岩二次应力场的现场测试与监测[J].岩石力学与工程学报,2002,21(5),651-653.
[94] 徐林生,孙均,蒋树屏.洋碰隧道进口右线施工中现场监控量测[J].岩石力学与工程学报,2002,21(5),675-678.
[95] 王立中,胡亚元,王柏林等.崩塌松散围岩隧道施工稳定分析与监控[J].岩石力学与工程学报,2003,22(4),589-595.
[96] 王成、邓安福.岩体内压致裂解析研究[J].岩石力学与工程报,2002(5):640~643.
[97] 刘宝县,鲜学富,善德义.煤与瓦斯延期突出机理及预测预报研究[J].岩石力学与工程学报,2002,21(5),647-650.
[98] 刘允芳,钟作武,汪洁.水压致裂三维地应力测量结果计算与分析的探讨[J].岩石力学与工程学报,2002,21(6),833-838.
[99] 罗国煜,阎长虹,李晓昭等.新世纪中叶中国工程地质回顾与展望.[J].岩石力学与工程学报,2002,10(1),3-9.
[100] 刘桂雄、申柏华等,迅速崛起的网络智能化传感技术。传感器技术,2002,21(9):4—7.
[101] 侯美丽、王晓娟等.先进的集成微型传感器的研究进展.传感器技术,2002,21(10),1-3.
[102] 肖正学,张志呈,郭学彬.断裂控制爆破裂纹扩展规律的研究.[J].岩石力学与工程学报,2002,21(4),546-549.
[103] 肖洪天,周维垣.脆性岩石变形与破坏的细观力学模型研究.岩石力学与工程学报.岩石力学与工程学报,2001,20(2):151-155.
[104] 郑少河,朱维申.裂隙岩体渗流损伤耦合模型的理论分析.岩石力学与工程学报,2001,20(2):156-159.
[105] 金衍,陈勉.利用测井资料预测深部地层岩石断裂韧性.岩石力学与工程学报,2001,20(4):454-456.