Water Inrush Risk Assessment Based on AHP and Advance Forecast Approach: A Case Study in the Micangshan Tunnel

Water inrush is a serious geological disaster in tunnel. For the effective prevention and control of the occurrence of water inrush, a static-dynamic water inrush risk assessment method is proposed by considering the Micangshan tunnel as an example. First, four possible types of water inrush phenomenon are identified based on the geological and hydrogeological conditions of the tunnel: water inrush in water-bearing cracks, fault fracture zones, karst pipelines, and karst caves. Next, evaluation indexes that affect water inrush are determined. By combining the index weight value calculated by analytic hierarchy process (AHP) with the index quantitative value, the static water inrush disaster evaluation model is established, which provides a basis for tunnel design. Finally, with the combination of the static evaluation model and advanced forecast method, a dynamic risk prediction method of water inrush is established, which provides guidance for safe construction.'e results confirm that the proposed method is a reliable theoretical basis for early assessment and prediction of tunnel water inrush disasters.


Introduction
Detection of anomalous geological structures such as fault zones, faults, aquifers, and karsts in the process of tunnel construction is challenging owing to their large buried depth and length of the tunnel [1][2][3][4]. In particular, during the construction of a tunnel in a complex karst area, high water pressure makes the surrounding rock unstable, resulting in a water gushing disaster, which in turn may cause delay in the construction, economic loss, and even serious casualties [5,6]. erefore, the prediction of the water gushing phenomenon in a tunnel is a key step in tunnel construction [7]. e analytic hierarchy process (AHP) by considering the several evaluation indexes of water inrush has been widely used as a decision support tool to solve complex decisionmaking problems [8]. Lyu et al. [9][10][11][12] applied remote sensing and GIS coupled with AHP techniques for delineating potential groundwater zones in semiarid areas. A hierarchical structure of multilevel goals, standards, substandards, and alternatives has been established [13]. Wang et al. [14] used a fuzzy AHP to construct water inrush indices of coal seam floors based on geological, hydrogeological, floor aquitard, and mine-size factors for predicting water inrush through coal seam floors. Xue et al. [15] selected seven main factors, namely, the surrounding rock grade, rock integrity, overburden thickness, seawater thickness, tunnel section, permeability coefficient, and construction technology level, as risk assessment indicators for the evaluation model. Zhang et al. [16] considered the karst geological conditions and selected nine main factors such as ground water level, land form and physiology, attitude of rock formation, and unfavorable geological conditions as the evaluation indexes affecting water inrush in tunnels. However, the existing prediction models do not introduce factors affecting the types of water inrush. First, rock roofs with different thickness have distinct failure patterns under complex pressure [17,18]. Moreover, the uncertainty of the geological conditions in front of the tunnel face causes different hydrogeological conditions and types of water inrush phenomenon in different areas. Second, in the AHP, the consistency test of the judgment matrix is complicated and requires multiple adjustments, and most of the existing evaluation models lack quantitative indicators of evaluation factors to analyze the risk of water inrush and hazards [19]. erefore, it is necessary to introduce evaluation indexes of the water inrush disaster types into the prediction model in order to establish a quantitative and qualitative water inrush prediction method.
Water inrush and mud inrush and their early warning system focusing on risk assessment and advanced prediction have been extensively researched. At present, advanced prediction methods of tunnels, such as tunnel seismic prediction (TSP), tunnel reflection tomography (TRT), ground penetrating radar (GPR) detection, infrared water detection, and advanced borehole detection, can determine different response characteristics with respect to the groundwater according to the specific characteristics of each detection method, and a follow-up dynamic prediction method is adopted to predict the location of water inrush disaster in the tunnel. For example, to prevent unforeseen unfavorable geological conditions, it is necessary to investigate the geological and hydrogeological conditions in front of tunnel excavation faces in the construction stage [20]. According to the properties of seismic waves, TSP is used as a long distance prediction method, and for this method, explosives are used as the seismic source to identify anomalies related to geological structures and aquifers [21][22][23]. Yamatoto et al. [24] developed a three-dimensional reflector tracking system, namely, TRT, which can detect the geological conditions at 100-150 m in front of the tunnel face. For the improvement of detection and interpretation, ground penetrating radar is used as a short-term prediction method [25,26]. With the interpretation of GPR images, abundant useful information can be extracted for describing and distinguishing groundwater and its specific location [27]. Corbeanu et al. [28] used GPR attributes to predict 3D fluid permeability and mudstone distribution in east-central Utah. GPR attributes have also been studied in the geological exploration of karst tunnels [27]. Advance drilling can detect the softness and hardness of formation rock, the integrity of rock mass, and the distribution location of possible faults and water inrush, through the analysis of the propulsion rate, rotation speed, and exposed lithology [29]. However, because the relationship between the interpretation standard of advanced prediction methods and geological structure is nonlinear, widespread uncertainty and multiple results exist in the interpretation of geological advanced prediction [30,31]. erefore, it is necessary to deeply understand the response characteristics of various advanced prediction methods for groundwater, establish a dynamic risk assessment system, and predict the risk of water inrush disaster in the construction process.
In this study, we established a static-dynamic risk assessment method to predict water inrush hazards taking the Micangshan tunnel as the research object. First, the types of water inrush disasters were classified based on engineering geological and hydrogeological conditions. According to the analytic hierarchy process and the scoring method, a quantitative and qualitative static evaluation method was established to quantify the risk of water inrush hazard, thereby providing a basis for the design stage. Second, according to the static evaluation method, three dynamic prediction methods corresponding to the water inrush disaster in the construction process were established. Finally, the reliability and applicability of the method were verified with an example for the tunnel water inrush disaster prediction, prevention, and control to provide reference.

Site and Geology.
e Micangshan tunnel connects the Shanxi Province with the Sichuan Province as shown in Figure 1. It is a separated deep-buried super-long twin tunnel and is a major engineering structure in the Taoba Expressway.
Its beginning-ending mileage is K39 + 733-K53 + 527; it is 13.8 km long and has the maximum buried depth of approximately 1055 m. e tunnel entrance is located in the Nanzheng County of Hanzhong City, Shaanxi Province. e distribution of precipitation in this area is uneven, mainly concentrated from July to September, accounting for 53% of the whole year, with an average annual precipitation of 920 mm. e exit of the tunnel is located in the Nanjiang County of Bazhong City, Sichuan Province. is area has abundant precipitation, with an average precipitation of 1828 mm for many years. e surface water body in the geological area of the tunnel is well developed, with most of the gullies developing into tree shape and most of the smaller gullies having only seasonal water. e groundwater in the tunnel area is mainly divided into clastic rock fissure water, karst fissure water, and bedrock fissure water.

Geological Structure.
e geological structure of the Micangshan tunnel is shown in Figure 2. Based on the borehole Z1-Z4 data, the lithology mainly comprises argillaceous siltstone, argillaceous limestone, dolomite, and quartz diorite. is well-developed structure consists of two syncline structures, i.e., Xiaoba and Neutron Mountain, and one anticline structure, i.e., Daba, as well as six fault fracture zones (F1-F6). Based on the borehole Z1 data, the axial strata of the Xiaoba syncline structures are severely crumpled, having the characteristics of karst. According to the exposure of borehole Z4, the Daba anticline structure is located in the concave valley, and the rock masses at its two wings and core are magmatic rocks with massive structure. e limestone section belongs to the regional karst section, with weak to medium karst development, relatively welldeveloped fissures, abundant water content, and high water head that bears high pressure. ere are surface karst caves, shafts, and funnels in some sections.
ere is a joint dense zone in the position of the rock contact zone, syncline structure, and fault fracture zone. Tectonics and waterproofing effect make the soluble rocks in the region beneficial to the recharging of groundwater and the dissolution of soluble rock components, resulting in a strong degree of karst development and various dissolution forms in this area.

Prediction of Types of Water Inrush.
e water inrush of the tunnel involves three aspects: the disaster source, water inrush channel, and antioutburst structure. e disaster source is the most important source of power and material basis for the water inrush. e possibility and states of water inrush in the Micangshan tunnel are predicted according to its underlying geological and hydrogeological conditions. Four main types of water inrush are identified: water inrush in water-bearing cracks, fault fracture zones, karst pipelines, and karst caves [32,33]. Figure 3, when excavating in rock strata with poor permeability, the stress around the surrounding rock constantly changes because the disturbance caused by tunnel excavation destroys the original seepage balance system.

Water Inrush in Water-Bearing Cracks. As shown in
Under the combined action of high groundwater pressure head and surrounding rock stress, the groundwater weakens the fractured rock mass and forms water wedges in it. When the groundwater pressure in the fracture plane exceeds the ultimate strength of the fracture expansion in the rock mass, the water-bearing fracture may expand and split gradually [32,33]. e scouring and enlarging effect of groundwater will expand the water inrush channel continuously, which leads to the groundwater directly gushing into the tunnel or infiltrating into the tunnel from the cracks, forming a water gushing channel and causing the water inrush phenomenon. Figure 4, the special tectonic action of the fault leads to the formation of a large number of fracture zones in the rock mass, and most of the fillers in the fault zone are angular and of different sizes. Because the water permeability of the fault fracture zone is higher than that of the aquifer rock mass, strong tangential stress and circumferential stress may appear in the fault fracture zone, leading to the relaxation of the original fault zone, further expansion of the original fracture, and even formation of new cracks. At the same time, groundwater can collect between two rock masses in the    Advances in Civil Engineering faults, providing space and channels for the storage and migration of groundwater. When tunnel excavation is performed at such faults, the amount of water gushing may be considerably large [32,33]. Figure 5, the topographical and lithological effects cause low-lying areas to easily form basins and become recharge areas of karst groundwater. Owing to the long-term action of surface water or groundwater, the rock is eroded, and the presence of waterbearing pipes with good connectivity, strongly permeable waterbearing strata, fissures, or other water-bearing structures with good permeability in the surrounding rock results in the formation of karst pipelines [32,33]. e excavation of the tunnel in the areas with karst pipelines directly reveals the waterbearing structure in the surrounding rock, which leads to the water inrush phenomenon in the tunnel.

Water Inrush in Karst
Caves. As shown in Figure 6, due to geological tectonics, the fissures and interlayer sliding spaces formed in the soluble rock strata create the original space for the formation and expansion of karst caves. Under the action of chemical dissolution for a long time, the groundwater carries sediment, debris, and other materials into the karst cave through the fracture channel, forming a filling medium in the karst cave, together with the source rock, gravel, breccia, and other materials. During the construction of the tunnel, the karst caves are disturbed and they directly push over the waterproof layer; when they reach the critical state, because of the strong water pressure, the previously deposited materials are flushed out, forming a geological hazard of water and mud inrush into the tunnel [32,33].

Scoring Method and Analysis of Static Water Inrush Disasters
A static water inrush disaster assessment model is a risk assessment system of the water inrush phenomenon based on the AHP and the scoring method. First, the evaluation indexes affecting the water inrush risk are determined. Based on the AHP, each evaluation index is further divided into several evaluation factors, and the weight of each index is determined. Second, the disaster risk value is associated with the quantitative score of each evaluation index by a certain method, and the quantitative value that can accurately reflect the characteristics of environmental factors is input. According to the scoring method, the effect of the quantitative standard of each basic evaluation index or evaluation factor on the development of things is scored. Finally, a numerical model is established using the reverse-order superposition method, and the actual analysis is combined with it to determine the final judgment.

AHP Analysis
Method. e AHP, which was recommended by Saaty [34], is a hierarchical weighting multiobjective comprehensive evaluation decision analysis method based on the network system theory. is combined quantitative-qualitative analysis is used for multiobjective decision-making and evaluation for complex problems. It involves the following major steps.
In this step, the overall goal is established, the decisionmaking problem is decomposed in detail, hierarchical and organized characteristics are formed, and a multilevel gradient structure model is developed. In the developed model, the elements are divided into the top, middle, and lower layers according to their attributes and interrelationships. e elements of the upper layer are composed of the elements of the lower layer, and they play a dominant role in determining the relevant elements of the subsequent layer. A linear series connection is adopted to build a hierarchical level of characteristics.
Step 2. Establish the comparative judgment matrix.
In this step, a certain factor U is considered the standard of the judgment matrix, based on which the factors of the lower layer are compared, and the n-order judgment matrix is obtained as shown in the following equation: Suppose there are n factors (U 1 , U 2 , . . ., U n ) in the same layer; then all the factors are compared in pairs; for example, U i is compared with U j and the relative importance is evaluated on a scale of 1-9; the implications of the scales are shown in Table 1.
Step 3. Calculate the relative weights of elements following the single criterion and its consistency check.
According to the judgment matrix, the eigenvector corresponding to the maximum eigenvalue of Z is obtained by using linear algebra. e eigenvector obtained is the order of importance of each evaluation factor, and then the normalized factors give the weight distribution. In this paper, the approximate solution technique of the sumproduct method is adopted.
(1) Each column is normalized by the judgment matrix, as shown in the following equation: (2) Each column of the normalized judgment matrix is added by row, as shown in the following equation: (3) As shown in equation (4), the vector A � (a 1 , a 2 , a 1 ) obtained in turn is the eigenvector. (4) As shown in equation (5), the maximum eigenvalue λ max is calculated: (5) Consistency judgment: to verify whether the judgment matrix results have satisfactory consistency, the value of consistency ratio (CR) is used for judgment, as shown in the following equation: where CI is the consistency indicator; RI is the random index determined by the number of evaluation factors in the judgment matrix (Table 2); λ max is the maximum eigenvalue of the judgment matrix; and n is the number of indicators. When CR < 0.1, the measures of the consistency levels of the judgment matrix-based results are satisfactory, which signifies that the weight distributions are reasonable and reliable. Otherwise, the matrix must be restructured until the consistency is satisfied.
Step 4. Calculate the element relative weights following the total criterion and its consistency check.
With the hierarchical ranking, the weight of each influencing factor relative to the overall goal is calculated, generally by using the top-down method. Subsequently, the consistency of the final synthesized results is checked to judge the overall consistency.

e Scoring Method.
e scoring method is used to calculate the comprehensive evaluation score of water inrush and determine the risk level of water inrush. First, the factors that affect the development of things are decomposed into a number of evaluation indexes (U 1 , U 2 , . . ., U n ). Second, each evaluation index is divided into several basic evaluation factors (C 1 , C 2 , . . ., C n ), and the scores of the impact of each basic evaluation index or evaluation factor on the development of things are determined according to the quantitative criteria. Finally, the risk value of the water inrush is obtained with the reverse-order superposition method, which is a linear combination relationship; the final evaluation is performed in combination with the actual analysis. e specific methods of the reverse-order superposition method are given by equations (7) and (8): where the risk value of the water inrush (i.e., TRV) is the comprehensive evaluation index of the water inrush phenomenon; the higher the TRV value, the greater the possibility of water inrush in the tunnel; U n is the quantitative score of each evaluation index; W un is the weight of each evaluation index; C n is the quantitative score of the basic evaluation factors; W cn is the weight of each basic evaluation factor.

Model Analysis.
More than 100 cases of water inrush in tunnels in China have been systematically summarized and analyzed mainly based on the variation characteristics and occurrence conditions of water inrush in the tunnel [16,[35][36][37][38]. e tunnel water inrush disaster is caused by the effect of tunneling engineering and its interaction with the groundwater environment. Formation lithology is the basis of groundwater storage. e level of the surrounding rock and the lithology of the stratum in which it is located are different. Topography conditions play an important role in groundwater recharge, runoff, and discharge and serve as an important factor affecting the alternation of the groundwater cycle. Geological structure conditions are the dominant factor controlling the direction of groundwater burial, distribution, and movement. Because the location of the tunnel section in the geological structure varies, the stratigraphic production and catchment area in the tunnel sections also significantly vary. e length and burial depth of the tunnel are external factors affecting the formation of the disaster; the longer the tunnel extends in the construction process, the more hydrogeological units and rock layers it traverses; the deeper the tunnel, the larger the catchment area, runoff, and recharge area of the tunnel site. Karst development is an intrinsic factor affecting the water inrush phenomenon.
In this paper, a static water inrush disaster evaluation model of the Micangshan tunnel is established taking into consideration the engineering geological conditions, tunnel section characteristics, and hydrogeological conditions of the tunnel, as well as the statistical analysis of the type of water inrush development. ese characteristics are mainly classified as formation lithology (U 1 ), topography conditions (U 2 ), geological structure conditions (U 3 ), tunnel length and buried depth (U 4 ), and karst development (U 5 ). ese are further divided into five evaluation indicators and 12 evaluation factors (C 1 , C 2 , C 3 , C 4 , C 5 , C 6 , C 7 , C 8 , C 9 , C 10 , C 11 , C 12 ).
e AHP hierarchical structure model of the water inrush disaster is shown in Figure 7. e level of water inrush disaster is divided into five types, namely, very low risk (risk level I), low risk (risk level II), medium risk (risk level III), high risk (risk level IV), and extremely high risk (risk level V).
Experts' judgment questionnaire is a key point of AHP. ere are two approaches to do experts questionnaire: (1) one is the pairwise comparison, proposed by Saaty [34], improved by Li et al. [39]; (2) another method to do questionnaire is to use table comparison proposed by Lyu et al. [40]. e paper used the second method to conduct the questionnaire, which can not only get the appropriate experts' reply but also determine the fuzzy number based on experts' replies. e authors selected six experienced experts with expertise in hydrogeological geological and tunnel engineering to assess the water inrush risk of Micangshan tunnel.
As shown in Tables 3-8, the judgment matrix of the index layer can be calculated. e largest eigenvalue (λ max ) of the judgment matrix can be calculated by equation (5), and the CR can be calculated and verified by equation (6). e other judgment matrices of the subindex layer to the index i has the same importance, or i or j compares to itself 3 i is slightly more important than j 5 i is obviously more important than j 7 i is much more important than j 9 i is extraordinarily more important than j 2, 4, 6, 8 Scales between two consecutive scales given above Reciprocal Contrast to the above condition, namely, j is more important than i layer can also be obtained. In addition, the weight of each judgment matrix can be calculated using the aforementioned method. As shown in Tables 9 and 10, the weight values of the primary and secondary evaluation indexes in this level are calculated separately, and the rationality of the CR is calculated and verified. e CR is less than 0.1, which indicates that the judgment matrix is consistent.
According to the degree and range of disaster causing factors in the evaluation index, the quantitative value of disaster causing factors is determined (see Table 11) [41][42][43]. At least five tunnel engineering experts are selected for scoring based on the field geological and hydrogeological conditions. e average score of each evaluation index is calculated based on the scores of all the experts, which can improve the accuracy of the final score of each index. Using equations (7) and (8) and the determined weights of the evaluation indexes, the risk value of the water inrush (TRV) is calculated using the scoring method as follows: TRV � 5 * 0.5 * U 1 + 0.06 * U 2 + 0.29 * U 3 + 0.03 * U 4 * 0.12 * U 5 , e maximum score of U n is 20.
is score must be increased by five times to meet the target TRV value of 100. According to the THR value, the risk grade can be divided into five grades; the higher the score, the higher the level of risk of the disaster, as shown in Table 12.

Method of Dynamic Risk Prediction of Water
Inrush Phenomenon e dynamic prediction of the water inrush phenomenon is based on the risk grade of static water inrush, and the advance prediction method is used to determine and analyze the location of the water inrush position in the construction stage. e dynamic prediction of the tunnel water inrush disaster is realized through an integrated advanced prediction method that combines the long distance (e.g., TSP, TRT) and short distance (e.g., GPR, TEM, infrared water detection method, advanced drilling) prediction methods.    Table 4: Secondary index judgment matrix in U 1 . Table 5: Secondary index judgment matrix in U 2 . Table 6: Secondary index judgment matrix in U 3 . Table 7: Secondary index judgment matrix in U 4 .       To judge whether there is a waterbearing body in front of the tunnel face by observing whether the borehole is out of water and determining the amount of water flowing out of it Accurate observation of the water output and water pressure e long distance means that the predicted distance from the tunnel face is about 100 m, and the short distance means that the predicted distance from the tunnel face is about 30 m. According to the characteristics of each advance prediction method, the diversity of solutions can be reduced and the reliability of detection results can be improved.

Advanced Prediction Method of the Tunnel.
Conventional prediction methods are geological analysis methods (e.g., palm-top geological analysis, advanced drilling), seismic wave methods (e.g., TSP, TRT), electromagnetic methods (e.g., GPR, TEM), and other methods (e.g., infrared water detection method). Each detection method is based on the difference in some properties of the geological medium (such as elasticity, resistivity, and wave velocity). Owing to the limitations and constraints of factors such as the complexity of geological conditions in the crossing area of long and deep-buried tunnels and the multiple solutions of geophysical methods, each advanced prediction method has its own advantages and limitations (see, for example, Table 13). Using only a single advanced prediction method, it is difficult to accurately detect the geological conditions in front of the tunnel. In particular, under the complex geological and hydrogeological conditions such as those in the Micangshan tunnel, it is more important to determine a scientific, effective, and accurate advance geological prediction method [44,45].

Dynamic Prediction Method.
According to the static evaluation results of water inrush risk in different sections of Micangshan tunnel, the risk levels of different water inrush disasters are determined. en, the dynamic water inrush disaster prediction method is adopted, with different advanced prediction methods for different risk levels of water inrush disasters to predict the position of water inrush disasters in the construction process. erefore, three dynamic water inrush prediction methods are divided, namely, primary dynamic prediction, secondary dynamic prediction, and terminal dynamic prediction (Table 14). Based on this, a comprehensive advanced geological prediction system suitable for tunnel engineering is constructed, and the process of dynamic prediction is formed.

Model Verification
e buried depth of the K41 + 440-K43 + 080 mileage section of the Micangshan tunnel is 751 m, the lithology mainly comprises dolomite, and the rock is formed in the middle  layer. e sectional view indicates that it is a parallel type below the valley, and the groundwater is karst fissure water, with local water inrush, occurring in water-bearing cracks. e face of the tunnel excavated in the K42 + 480 section is shown in Figure 8. e surrounding rock is mainly dolomite, and the bedding plane is slightly bent and partially broken because of tectonic movement. e joints in the tunnel face are nonuniformly distributed, the source of the vault is rain, and water gushes from the cracks on the left side of the face of the tunnel. According to the specifications for design of highway tunnels, the surrounding rock is of level V. e quantitative and qualitative analysis of the static evaluation model provides a TRV value of 75, implying that this tunnel area has grade-V risk. As shown in Table 14, tertiary dynamic prediction is adopted in the area, including geological analysis of the tunnel face analysis, TSP detection, the GPR water detection method, and advanced drilling.
In the TSP method, seismic waves are generated by an artificially excited source and propagated in front of the tunnel along the tunnel axis. When unfavorable geological bodies (such as karst caves or fissures) are encountered in front of the tunnel face, the waves are reflected, which are received by highly sensitive sensors. According to the reflection time, propagation speed, and waveform of the reflected waves, different data characteristics are processed by TSPwin Light software to predict the location of the unfavorable geological bodies. As shown in Figure 9(a), the physical and mechanical parameter results obtained by TSP for the K42 + 510-K42 + 540 section clearly show that the velocities of both P and S waves decrease and the waveforms are abnormal. e ratio of P to S waves increases, while the elastic modulus and density decrease. e reflection layer produced by TSP in the corresponding section indicates the significant enhancement of the negative reflection region (Figure 9(b)). e prediction results obtained by TSP for the K42 + 510-K42 + 540 section clearly indicate that there is considerable fracture development and a large amount of water content in this section.
In the GPR method, the distribution law of rock mass media is determined by transmitting pulsed electromagnetic waves in a certain frequency range. rough the comprehensive analysis and processing of radar data and complex meteorological elements, various characteristic parameters of disaster sources can be obtained, and adverse geological structures such as caves and faults in tunnels can be detected. According to the key water inrush areas predicted by the TSP method, SIR3000 GPR is used to detect geological structures in the K42 + 510-K42 + 540 section. Two measuring lines are used for measurement to ensure high detection accuracy. e radar is moved from left to right in uniform motion during implementation while avoiding the phenomena of disengaging, stagnation, and sudden drive as much as possible.
e velocity and position of the two lines are consistent.
e GPR interpretation results for the K42 + 510-K42 + 540 section show that the radar-reflected wave amplitude increases significantly and the strong reflection interface is clear (see Figure 10). is indicates broken rock mass in the cave section, likely containing voids and cavernous geological structures. e K42 + 492 section is mainly composed of medium dolomite, and advanced drilling is used in this section. e advanced drilling results indicate that the drilling speed increases to a large value and remains constant. Water gushes out from the pipe core, with a jet distance of approximately 1 m (Figure 11). is area has well-developed joints and fissures and high water pressure, and the groundwater gushes out through boreholes. When the tunnel is excavated to the K42 + 530 mileage section, the tunnel face mainly comprises dolomite, which is relatively weak and the cracks are developed as a whole. According to the static evaluation results of water inrush and the interpretation of the dynamic evaluation results, high risk of water inrush is considered highly likely to occur in this section. e surrounding rock is easy to deform after excavation and unloading, and the unloading fissure gradually expands to form a seepage or outburst channel for groundwater discharge. As shown in Figure 12, a large amount of water gushes out of the boreholes and cracks, and water inrush continuously increases at approximately 800 m 3 / h on average. As a result, the tunnel is flooded 60 m behind the work face. During advanced drilling, to release high-pressure water stored in the surrounding rock beforehand, emergency evacuation of workers and equipment was carried out and timely drainage measures were undertaken in the tunnel, avoiding any catastrophic water gushing accident. e staticdynamic water inrush risk assessment method realizes the accurate prediction of water inrush risk in karst tunnels. It  would considerably reduce the possibility of water inrush and provide the design basis for the treatment.

Conclusions
(1) Based on the geological and hydrogeological conditions of the Micangshan tunnel, four types of water inrush were identified: water inrush in water-bearing cracks, fault fracture zones, karst pipelines, and karst caves.
(2) By considering the qualitative and quantitative factors, 5 first-level evaluation indexes and 12 second-level evaluation indexes were extracted, which form the tunnel water inrush risk assessment indexes. Based on these indexes, a static water inrush disaster risk assessment model was established. e risk of the water inrush disaster in terms of the TRV values was graded as I (very low risk), II (low risk), III (medium risk), IV (high risk), and V (extremely high risk). To accurately identify occurrence characteristics and the damage level of the water-bearing body, the sensitivity of the advanced prediction method to groundwater was summarized and analyzed, and the following three dynamic prediction methods were established: primary dynamic prediction, secondary dynamic prediction, and terminal dynamic prediction methods.
(3) e excavation of the K42 + 510-K42 + 540 mileage section of the Micangshan tunnel was assessed using the static water inrush risk assessment method and was judged as high risk. Based on the dynamic evaluation model and using the terminal dynamic prediction method in the construction process, it can be inferred that rich fissure water develops before the tunnel face, and the connectivity between the tunnel face and groundwater is good. e accuracy of the static-dynamic water inrush disaster risk assessment and prediction method was verified and the rationality and applicability of the method were proved.

Data Availability
e underlying data supporting the results of our study are unavailable.

Conflicts of Interest
e authors declare that they have no conflicts of interest.