Application and evaluation of ground surface pre-grouting reinforcement for 800-m-deep underground opening through large fault zones

Faults are complex geological conditions that are commonly encountered during underground excavation. Many support schemes, such as using a single pilot heading method and 30-m-long borehole pre-grouting, have been implemented during the pilot excavation of an 800-m-deep underground opening that passes through large fault zones in East China. However, various geo-hazards, including groundwater inrush, debris flow, and roof collapse, are still occurring, which seriously threaten tunneling safety. To eliminate the geo-hazards and ensure tunneling safety, ground surface pre-grouting (GSPG) was proposed and implemented for the first time to reinforce the regional engineering rock mass for this proposed 800-m-deep underground opening passing through large fault zones. The minimum grouting pressure of GSPG at a depth of 800 m below the surface is put forward based on hydraulic fracturing theory, providing valuable guidance for GSPG engineering practice. Engineering practice demonstrates that GSPG eliminates geo-hazards, improves the objective rock mass stability, and ensures tunneling safety. Field measurements indicate that the displacement velocity of the surrounding rock shows an obvious fluctuation response under the influence of GSPG, and the impact of GSPG on the stability of the 800-m-deep underground opening that has been excavated dramatically decreases as the distance from the grouting borehole increases. Moreover, there is a strong negative exponential correlation between the maximum velocity of deformations and the distance from the grouting borehole. In addition, the safe distance underground during GSPG is greater than 137 m.

[1]  Süleyman Dalgıç,et al.  Tunneling in fault zones, Tuzla tunnel, Turkey , 2003 .

[2]  E. Hoek Support for very weak rock associated with faults and shear zones , 2018, Rock Support and Reinforcement Practice in Mining.

[3]  Aurèle Parriaux,et al.  Cataclastic rocks in underground structures - terminology and impact on the feasibility of projects (initial results) , 1999 .

[4]  Feng Xiang-dong Field measurement study on ground perforation grouting for ultradeep soil , 2005 .

[5]  Deyu Qian,et al.  Stability of Deep Underground Openings through Large Fault Zones in Argillaceous Rock , 2017 .

[6]  Alain Thoraval,et al.  The effect of joint constitutive laws on the modelling of an underground excavation and comparison with in situ measurements , 1997 .

[7]  E. T. Brown,et al.  Rock Mechanics: For Underground Mining , 1985 .

[8]  A.C.G. Nagelhout,et al.  Investigating fault slip in a model of an underground gas storage facility , 1997 .

[9]  Leonid N. Germanovich,et al.  Hydraulic fracture with multiple segments I. Observations and model formulation , 1997 .

[10]  Fu Jianjun SAFETY MONITORING AND STABILITY ANALYSIS OF LARGE-SCALE ROADWAY IN FAULT FRACTURE ZONE , 2010 .

[11]  Yang Xiaohua TREATMENT EFFECT ANALYSIS OF SHALLOW-BURIED CRUSHED SURROUNDING ROCKS UNDER UNSYMMETRICAL PRESSURE REINFORCED WITH SURFACE PREGROUTING TECHNOLOGY IN HIGHWAY TUNNEL , 2008 .

[12]  Tor L. Brekke,et al.  Functional Classification of Gouge Materials from Seams and Faults in Relation to Stability Problems in Underground Openings , 1974 .

[13]  Liu Bin Surrounding rock stability control theory and support technique in deep rock roadway for coal mine , 2011 .

[14]  S. Jeon,et al.  Effect of a fault and weak plane on the stability of a tunnel in rock—a scaled model test and numerical analysis , 2004 .

[15]  R. Azzam,et al.  The Plastic Zones and Displacements Around Underground Openings in Rock Masses Containing a Fault , 2005 .

[16]  Dingli Zhang,et al.  Grouting techniques for the unfavorable geological conditions of Xiang'an subsea tunnel in China , 2014 .

[17]  W. Schubert,et al.  Influence of Faults on Tunnelling , 1997 .