Deep buried tunnel surrounding rock stability analysis of the cusp catastrophe theory

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Available online www.jocpr.com Journal of Chemical and Pharmaceutical Research, 3, 5(9):57-54 Research Article ISSN : 975-7384 COEN(USA) : JCPRC5 eep buried tunnel surrounding rock stability analysis of the cusp catastrophe theory Hong Jiang epartment of Municipal Engineering, Anhui Technical College of Water Resources and Hydroelectric Power, Hefei, PR China ABSTRACT Surrounding rock system of underground engineering is highly nonlinear, and there is no unified cognition for its stability criteria. A simplified mechanical model for the surrounding rock is built, considering the influence of the water,introducing water weakening function, using the cusp catastrophe theory,the necessary and sufficient mechanics criterion of the surrounding rock is obtained, and the critical radial displacement of deep buried tunnel instability is obtained. In practical engineering,it is show that catastrophe theory is a feasibility method to study the instability problem of the eep buried tunnel. Key words: catastrophe theory, cusp catastrophic model, surrounding rock stability INTROUCTION Underground engineering rock mass stability is influenced by a variety of factors, it is not only has the complicated deformation failure mechanism, but also has the highly nonlinear characteristics, the nonlinear characteristics of rock mass is mainly manifested in the cumulative damage, the deformation of rock mass develop from disorder to order and the evolution of rock mass develop from linear curve to nonlinear (Chuanhua Xu, et al.3-4). The influence factors of the stability of underground surrounding rock have complicated variability and uncertainty, therefore, the scholars have no unified cognition for its stability criteria. The theories of nonlinear science, such as the theory of dissipative structures theory, synergetic and catastrophe theory (Siqing Qin, et al.993), are powerful tools to study rocks nonlinear problems. In view of the deep buried tunnel surrounding rock stability, In the paper, we build a simplified mechanical model for the surrounding rock, Using the cusp catastrophe theory, the necessary and sufficient mechanics criterion of the surrounding rock is obtained, and the critical radial displacement of deep buried tunnel instability is obtained. CUSP CATASTROPHIC MOEL The Catastrophe theory(sha Ma,), which is put forward by Thom(97), is a branch of nonlinear theory, its main theory is bifurcation theory and singular theory, it pays great attention to study the outside control conditions when system state changes suddenly, describe the reason why some variables of the system changes in system state mutation, and parameters of continuous change how to lead to generation of discontinuous phenomenon. Seven catastrophe models were summarized by Thom, cusp catastrophic model is the most common model(sha Ma,). Potential function V of cusp catastrophe model is a two-parameter function (two control variables are μ and ν), state variables is x (uhua Ling,987). 4 U x ux vx () 4 57

Hong Jiang J. Chem. Pharm. Res., 3, 5(9):57-54 The corresponding equilibrium position should meet: U x 3 ux v x () The graph, in the ( u, v, x ) space, is the catastrophe manifold, it has a fold surface M, thus, the equilibrium position is, or 3 in different zone. The middle lobe potential function takes a maximum value, and the equilibrium position is unstable, but to the superior lobe and the inferior lobe of the equilibrium position is stable. igure is the cusp catastrophe model schematic diagram, The equilibrium surface M contains the type all the stationary state solution of formula (). In the overlap, a point ( uv, ), in the parameter space, corresponding to three different steady state solutions, this is the reason why call them isolated, as well as the multiplicity of the steady state solution, two steady state solutions together at the edge of the overlapped, they all called non isolated singularity set S, projection to parameter control plane C, get the bifurcation set B. ig. Cusp Catastrophe Model Schematic iagram The non-isolated odd point set S is necessary to satisfy the formula (), but also need to satisfy the following formula: U x 3x u By type () and type (3), we can get the equation of bifurcation set B is, the system will cross bifurcation set mutations. u (3) 3 4u 7v, Only when the EEP BURIE TUNNEL INSTABILITY MOEL eep buried tunnel excavation, there will be stress reducing zone (relaxation zone), elevated stress zone (bearing zone) and the original rock stress zone around the tunnel. We assume that the tunnel section is circular cross section, no support, elastic-plastic stress diagram of the surrounding rock can be expressed as figure (Xue u et al.98).in the figure, R is the plastic zone radius, a is the tunnel excavation radius. In the process of tunnel excavation, surrounding rock will inevitably be the disturbance and damage, in the elastic deformation zone,the small disturbance of surrounding rock damage degree, so its bearing capacity is higher, The constitutive relation show linear elastic characteristics(bc section in the figure 3); in the plastic deformation zone,the disturbance of surrounding rock damage degree, its deformation is more than the elastic limit, with the increase of rock mass deformation,the ability to resist rock mass deformation will be lower, a plastic strain softening phenomenon will be showed, the constitutive relation show obvious nonlinear characteristics( section in the figure 3). 58

Hong Jiang J. Chem. Pharm. Res., 3, 5(9):57-54 σ σ σ r a 3 4 r R ig. Tunnel Surrounding Rock Stress and the Partition (Where and are plastically deforming zone; 3 and 4 are elastic deformation zone is relaxation zone; and 3 are bearing zone;4 is original rock stress zone.) C B ε O ε C ε ε ig3. Rock Stress-Strain Curve According to the paper(changbin Yan et al. 6), the rock constitutive relation can be expressed as: () Linear elastic stage: σ Eε c (4) () The plastic softening stage: 3 A B (5) Where: A n m m m B 3Am (7) m (8) n (9) (6) 59

Hong Jiang J. Chem. Pharm. Res., 3, 5(9):57-54, are peak stress and corresponding strain,, are stress and corresponding strain of the curve inflexion point which after the peak value, E is the rock elastic modulus. The slope absolute value of point is the rock drop modulus, its value can be obtained as follows: λ 3AEm () In order to reflect the effects of groundwater, a hypothetical water weakening functions will be introduced(youquan et al. 994): w f w () Where w is the water content; is the saturated softening coefficient of rock-soil body. The equation() was put forward by scholars through the experimental curve, It is a monotone decreasing function, in the dry condition, w, f w w, f w., in saturated water condition, After introducing the water weakening functions in the equation (4) and equation (5), we can get the constitutive relation under the influence of water: σ f w E c () 3 f w A B (3) Where w is rock mass water content in elastic stage; w is rock mass water content in the plastic softening stage. EEP BURIE TUNNEL SURROUNING ROCK INSTABILITY CUSP CATASTROPHE MOEL We choose the deep buried tunnel radial displacement as the state variables, and set the compressive stress and the compressive strain is positive. Assume that within the scope of the surrounding rock, volume incompressible. Then the system total potential energy can be expressed as: U U U (4) E S Where UE is surrounding rock system elastic strain energy, US is surrounding rock system plastic strain energy. U E E a R r r rdrd f w R (5) U S R (6) Wrdrd a Where is radial displacement when r =a, W is Strain-Energy ensity in plastic zone, its value can be expressed as: d W (7) To combine formula (3) with formula (7): W A f w B f w 4 3 AB f w 4 3 (8) 4 3 3 a a a 5

Hong Jiang J. Chem. Pharm. Res., 3, 5(9):57-54 Where is radial strain when r =a. Then: A f w R a B f w R a 4 3 A BR a f w U S 4 3 3 4a 3a (9) The total potential energy of the system can be obtained: 4 3 U A B C () Where: A B 4 3 4a A f w R a () 3 3a B f w R a () C Ef w a R (3) A B R a f w (4) When U / in the formula (), we can get the equations of equilibrium curved surface M of tunnel stability analysis: U 4A 3B C (5) ' 3 ''' The equilibrium curved surface M is smooth surface, when U, we can get the equation of equilibrium curved surface tip point displacement : ''' U 4A 6B (6) So, the radial displacement of the tip point is: B (7) a 4A As we can get the value from the equation (7) just as the rock plastic softening extents medium constitutive curve displacement value of the turning points. According to the paper[8],as one dimensional case, the stiffness can be defined as: k ' du (8) d epending on the stiffness definition, we can get: () The elastic zone stiffness is: k e due E a d R f w (9) 5

Hong Jiang J. Chem. Pharm. Res., 3, 5(9):57-54 () The plastic zone stiffness is: dus ks A 6B (3) d In the turning point, that is, when R ks f w a Then: E a k f w R k f w R a e s f k (3) (3) The formula (5) develop as Taylor formula at tip point, interception to cubic term, the standard form of equilibrium curved surface can be obtained: 3 x ux v (33) Where: x (34) u 3 fk (35) v 3 fk (36) k f E R R a a f w (38) f w 4E ζ A Ba (39) m Parameter k is the ratio of the stiffness of elastic segment medium to the point stiffness of plastic softening phase medium, which not consider the effect of water factor, referred to as stiffness ratio; Parameter f is the ratio of the elastic section medium water weakened coefficient to the water weakened coefficient of plastic softening extents, referred to as water weakened coefficient ratio, ζ is Geometry-mechanical parameters. Thus, we can get bifurcation set control equation according to the catastrophe theory: 3 4u 7v (4) ormula (35) and (36) into (39): fk fk 3 4 9 (4) (37) 5

Hong Jiang J. Chem. Pharm. Res., 3, 5(9):57-54 Only when u, system will come to a non-equilibrium state, That the necessary conditions of the system instability is u, we can obtain: k f (4) rom above, the necessary and sufficient mechanical conditions of systems instability systems is : fk fk 3 4 9 k f (43) ormula (37) into (4): E k R R f a a (44) General condition, the water content of the plastic softening zone is more than that of the elastic zone, that, in other words, f, thus, from formula (44), the rock mass instability, the stiffness ratio of is f w f w its plastic zone is less than.so we need to control the size of the relative radius, so as to improve the stiffness ratio of plastic zone and plastic softening zone. By the nature of the equilibrium curved surface M and the solution of cubic equation, we can obtain the hole radial displacement value when mutations by the formula (33). 3v fk 3 x u ( fk ) (45) The formula (45) is the expression of critical radial displacement of the tunnel, the relationship of f, k,ζ must satisfy the formula (43), can be obtained from formula (7). When the hole radial displacement values reach and exceed the value in formula 45, the surrounding rock will be destroyed, and the surrounding rock instability. ENGINEERING PROJECT APPLICATIONS Taking Jinping II hydropower engineering project as an example, this research selects the White Mountain Group II surrounding rock at the depth of m as the research object, and prove the surrounding rock stability by using the cusp catastrophe model. The tunnel diameter is 3 m, according to the research reports of Hohai University 3, the related parameters of the White Mountain Group II surrounding rock as follows: Uniaxial compressive strength modulus 97.87MPa, E =3.6GPa, Poisson's ratio.8, 5.48MPa, 3 5.8. Thus: m.57, n.78. 5.5MPa c, elastic 3.7 According to the geophysical detection results from JinpingII hydropower, the range of surrounding rock relaxation depth is approximately. m. Thus, the radius of the plastic zone is about 8.7m. rom the formula (37), k =.65. Stiffness ratio k is less than,so there is the possibility of instability of surrounding wall. Besides, in the light of observations on spot, tunnel does have the tendency of instability, which shows that the results of this calculation are reasonable to some extent. Therefore, in the process of construction, we need to minimize the disturbance of surrounding rocks, control the range of plastic zone and try to prevent impacts of groundwater on the surrounding 3 53

Hong Jiang J. Chem. Pharm. Res., 3, 5(9):57-54 rock. CONCLUSION Catastrophe theory is an effective method to study the instability problem of the tunnel. Because the surrounding rocks system of deep buried tunnel is not only has the complicated deformation failure mechanism, but also has the highly nonlinear characteristics, Using the cusp catastrophe theory to analysis the surrounding rock stability of deep buried tunnel has certain rationality. Establish a simplified surrounding rock instability model,considering the influence of the water,introducing water weakening function, using the cusp catastrophe theory, the necessary and sufficient mechanics criterion of the surrounding rock is obtained, and the critical radial displacement of deep buried tunnel instability is obtained. The mechanical model is simple, and it is very different with the actual situation, in order to be closer to the actual situation, urther research is needed to establish more close to the actual mechanics model. Engineering case study shows that the analysis results consistent with the actual situation. The results of the study can provide a reference for preventing tunnel instability, adopting the reasonable technology of construction and supporting measures. REERENCES [] Changbin Yan,Guoyuan Xu,6.Journal of Engineering Geology, 4:58-5. [] Chuanhua Xu,Wenqing Ren,4.Rock and Soil Mechanics, 3: 437-44. [3] Chuanhua Xu,Wenqing Ren,3.Geotechnical Engineering Technique, 3:4-46. [4] Chuanhua Xu,4. In:Nonlinear theory research and application of Rock mass destruction. Ph thesis, Hohai university, China. [5] uhua Ling,987. In:Catastrophe theory and its application. Shanghai Jiaotong University Press. [6] Sha Ma,. In: Nonlinear theory and method of surrounding rockmass stability.china Water Power Press. [7] Siqing Qin,Zuoyuan Zhang,Shitian Wang and Runqiu Huang,993.I n: Guidance of nonlinear engineering geology. Southwest jiaotong university press, China. [8] The research reports of Hohai university, China, 3. In: Tunnel surrounding rock stability analysis and the experimental study on rock mechanics parameters on high ground stress and external water pressure conditions of the project area in Jinping II hydropower station. [9] Xue u,yinren Zheng and Huaiheng Liu,98: Stability analysis of surrounding rock of underground engineering. Coal industry publishing house. [] Youquan,Jing u,994. Journal of earthquake, 4 : 46-4. 54

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