Study on Model Experiment of Prestressed Concrete Skewed Box Girder with Transversely Segmental Construction

he　prestressed　concrete　skewed　box　girder　with　transversely　segmental　construction　was　brought　out　on　the　basis　of　the　need　in　the　engineering,both　model　experiments　and　FE　analysis　of　the　presented　construction　and　the　beam　box　with　integral　construction　were　carried　out　With　the　analysis　of　the　obtained　data　by　mathematical　statistics,comparison　of　table　and　graph,and　the　corresponding　FE　analysis,the　difference　of　mechanical　performances　of　both　constructions　was　analyzed　under　various　experimental　loading　cases　The　results show　that　(1)　the　deflection　of　the　presented　construction　is　about　53%　larger　than　that　of　the　beam　box　with　integral　construction,the　longitudinal　strain　is　135%　larger　than　that　of　the　latter,and　the　longitudinal　strain　of　the　cast　concrete　is　59％　as　large　as　that　of　the　same　area　at　the　beam　box　with　integral　construction　before　concrete　cracking;　(2)　there　exists　stress　redistribution　in　the　cross-section　of　presented　construction,which　can　restrain　the　tensional　distortion　of　the　wet?joint,and　the　value　of　the　stress　cannot　be　computed　by　the　current　FE　program     

Study of Design and Construction Technology of Ultra large span Tunnel at Badaling Great Wall Station（八达岭长城站超大跨度隧道设计施工技术研究）

The large span transition section at Badaling Great Wall Station with a maximum excavation span of 32.7 m and an excavation area of 494.4 m2 is the traffic tunnel with the largest excavation span and excavation section area in the world, resulting in substantial construction difficulty and high safety risk. To ensure the construction safety of Badaling Great Wall Station, the support parameter design, a new excavation method, and the surrounding rock deformation control principle for tunnels with an ultra large section are studied. The study results show that: (1) According to the checking calculation, the support system had a safety factor of 1.16-2.46 during the construction period and 1.59-3.54 during the operation period, i.e., its engineering structure is safe and reliable. (2) The innovative triangle type excavation applied to the tunnel with an ultra large span and section has the advantages of a simple and clear method, safe and reliable structure, high applicability of mechanical equipment and high construction efficiency. (3) Depending on different surrounding rock classes and spans, the criteria for total deformation control of the large span transition section at Badaling Great Wall Station are as follows: in the case of class Ⅱ surrounding rock, the total settlement is 20-30 mm, and the total horizontal convergence is 15-20 mm; in the case of class Ⅲ surrounding rock, the total settlement is 30-40 mm, and the total horizontal convergence is 20-25 mm; in the case of class Ⅳ surrounding rock, the total settlement is 60-90 mm, and the total horizontal convergence is 40-55 mm; in the case of class Ⅴ surrounding rock, the total settlement is 130-190 mm, and the total horizontal convergence is 90-105 mm. (4) According to the numerical simulation, the innovative triangle type excavation method results in deformation that is mainly centralized in the tunnel arch making stage, accounting for approximately 95% of the total, followed by deformation in the side making stage, accounting for 4% of the total, with the smallest deformation only accounting for 1% in the inverted arch making stage.     

Design Method and Application of Rock and Support System for Super large Span Tunnel（超大跨度隧道围岩支护体系构件化设计方法及其应用研究）

In order to guarantee the stability of surrounding rock and support structure of super large span tunnel and realize quantification of support structure design, the optimal excavation contour line shape is obtained based on study of influence of initial ground stress on bearing arch of surrounding rock; a new quantitative design method, in which the surrounding rock is regarded as an arch structure, bolts, cables, shotcrete and lining are designed to satisfy the intensity, rigidity and stability of the arch structure, is presented to design the support structure system. The method has been successfully applied to super large span tunnel of Badaling Great Wall Station on Beijing Zhangjiajie High speed Railway; and the applicable results show that the maximum accumulative settlement of crown top of large span section is only 17.3 mm, and the relative subsidence of crown top is only 0.09%, which can meet safety requirements.     

Challenges and Countermeasures in Construction of  Gaoligongshan Tunnel of Dali Ruili Railway（大瑞铁路高黎贡山隧道施工挑战与对策）

In order to resolve the challenges encountered in the construction of Gaoligongshan Tunnel such as soft rock deformation of inclined shafts, water drainage and protection of vertical shafts, TBM jam in crossing areas with adverse geology, solutions and key construction techniques are developed through theoretical analysis, field test, scheme optimization and staged review and summary. The performance results of field practice show that: (1)the goal of no damages and no replacement of the primary support can be achieved by adopting the comprehensive deformation prevention technique of "ring support early formation and quick closure", setting of proper excavation line curvature, and reinforcing of support; (2)the risk of vertical shaft flooding during construction in water rich weak granite can be greatly reduced by adopting the water control principle of "exploration for any excavation, plugging as the main method, and supplemented with drainage method" and the key pre grouting technique of S shaped deep boreholes; (3)the open type TBM can quickly and safely pass through the unfavorable mylonitic granite stratum by adopting the small pilot tunnel construction method, thus the fast and high efficiency construction performance of TBM can be fully utilized.     

Innovation and Future Application of Mechanized and Intelligentized Construction Technology for High speed Railway Tunnels: A CaseStudy of Hubei Section on Zhengzhou Wanzhou High speed Railway（高速铁路隧道机械化修建技术创新与智能化建造展望——以郑万高速铁路湖北段为例）

To ensure the safe, rapid and high quality construction of Zhengzhou Wanzhou High speed Railway, a series of exploration and innovation of construction technology, structural design and information management under the condition of large scale mechanization is used in the whole construction process. The technology includes: （1）A set of advanced geological prediction, advanced pre reinforcement technology of excavation face, mechanized construction technology of primary support, wide waterproof board trolley operation technology and intelligentized full face lining trolley of large scale mechanized construction technology are formed. （2）A classification method of surrounding rock stability is established based on the mechanized construction technology, and the design parameters of the tunnel support structure are optimized under the guidance of New Austria Tunneling Method. （3）To realize informatized management of tunnel construction, the tunnel construction management system, construction information record system, construction safety management system, quality management system of concrete mixing station and quality credit evaluation system are established. Finally, on the basis of mechanized and informatized construction, exploration and outlook of the tunnel intelligentized construction technology are given from the aspects of the dynamic intelligentized design system of tunnel support system, the intelligentized robot construction technology of tunnel support system and the intelligentized monitoring system of tunnel structure, to promote China′s tunnel construction technology.     

Innovation and Practice of Hard Rock TBM in China（我国硬岩掘进机的创新与实践）

In recent years, with the help of good national policy support, the design, manufacturing and construction technology for tunnel boring machine (TBM) in China have been greatly improved; but compared with foreign relatively proven technology, there is still a certain gap for domestic technology development and engineering application. Based on the situation analysis of research and application of TBM in China and abroad, the research work for TBM design is carried out according to the complex geological conditions of Gaoligongshan Tunnel on Dali Ruili Railway as follows. (1) The prototype disc cutter rock breaking and scaled disc cutter wearing experiment are carried out to provide reference for adaptable design of TBM cutterhead and key parameter calculation. (2) The TBM design scheme is discussed from the aspects of high efficiency rock breaking of cutters and cutterhead, TBM over excavation, integrated support system, etc. (3) Two kinds of advanced geological prediction technology, i.e. HSP method and RTP method, are researched. The study results can provide reference for design and manufacture of TBM with high adaptability in complex geology and construction application in Gaoligongshan Tunnel.     

杭州狭长软土基坑支护侧移规律与解析预测方法研究

In order to reduce the influence of deep narrow foundation pit construction on adjacent properties in urban area in Hangzhou, the characteristics of the support wall lateral deflection are analyzed and the corresponding analytical prediction method is proposed. The support wall lateral deflections of the deep narrow foundation pits at Wenyi West Road, Qingchun Station, Qiutao Station, Xingtang Station and Qingnian Station in Hangzhou soft clay are monitored and compared with those of deep foundation pits in Zhejiang and deep narrow foundation pits in Shanghai, Taipei and Singapore. The results show that the maximum support wall lateral deflection of the foundation pit on Wenyi West Road, 0.20%He ~0.25%He, where He is the maximum excavation depth, is close to that in Shanghai(0.15%He~0.41% He), but is smaller than those in Zhejiang, Taipei and Singapore(0.27% He~0.62% He); which is related to the high tangential modulus of Hangzhou soil and small width of the foundation pit. The support wall lateral deflection of the narrow deep foundation pits in Hangzhou can be precisely predicted based on the representative stress strain relationship at site and the modified mobilisable strength design (MMSD) method.     

Reflections on Construction of Bohai Bay Crossing Corridor（对兴建渤海海峡跨海通道有关问题的思考）

The author discusses the necessity and urgency of constructing the Bohai Bay Crossing Corridor from the following aspects such as the increasing traffic volume, the convenience of the transportation after the corridor is constructed, and the regional benefit brought by the corridor. As for the timing of the construction of the sea crossing corridor, the author thinks that as long as the national economic situation permits and relevant conditions are basically available, the preliminary work should be carried out as soon as possible so as to promote the early commencement of the construction. Regarding the proposal of building another coastal national highway/high speed railway along the Bohai Bay coast, the author puts forward his viewpoints. In the aspect of construction risks, the author thinks that the geological risks in the construction of the Bohai Bay Crossing Corridor are very difficult to be dealt with; therefore, strict and detailed risk assessment should be carried out, and effective safety measures should be taken to mitigate the risks. The author also briefly describes the technological advantages of the tunnel proposal selected for the Bohai Bay Crossing Corridor, and briefly analyzes some key technological issues in the tunnel construction. The author describes the construction scheme and construction period estimation for the sea crossing corridor in details. The author makes the following proposal are given: (1)the hard rock tunnel boring machine (TBM) assisted by the drilling and blasting method should be used for the construction of the long sea crossing tunnel of Bohai Bay Crossing Corridor; (2) a parallel service tunnel shall be arranged between the twin main tunnel tubes; (3) in Proposal 2, the diameters of the twin main tunnel tubes and the service tunnel should be 8.0 m and 55 m, respectively. The proposal has two optional solutions: Solution 1: The service tunnel ( 55 m) located between the main tunnel tubes will be constructed first; for the main tunnel tubes, the disassembled TBMs ( 8 m) and the backup gantries are assembled for tunneling after arriving at the main tunnel tubes through the service tunnel and the cross passage; Solution 2 (alternative): Tunneling with  55 m TBM is carried out; the  55 m TBM will be dismantled to pass through the cross passage, and then be re assembled after arriving at the main tunnel; the start section (180 m) of main tunnel tube will be formed by  55 m TBM before it is enlarged to  8 m by drilling and blasting method; or the cross passage is enlarged to a large curved space to allow the 5.5 m TBM passing throught without disassembly. Comparison and contrast will be made and the preferred solution will be adopted. According to the rough estimation on the construction period of the 125 km long sea crossing tunnel, the total construction period of "completed tunnel" will be about 19 years (including 5 years of detailed offshore investigation) in Solution 1.     

Micromechanical Analysis on Viscoelasticity of Asphalt Mixtures

Mori-Tanaka　equivalent　inclusion　micromechanics　theory　was　employed　to　investigate　the　viscoelasticity　of　asphalt　mixture　Asphalt　mixture　was　regarded　as　composites　which　treated　coarse　aggregate　as　a　rigid　inclusion　and　the　mixture　of　fine　aggregate,filler　and　binder　as　viscoelastic　matrix　The　constitutive　relations　of　coarse　aggregate　inclusion　and　fine　aggregate-filler-binder　matrix　were　converted　into　elastic　problems　by　Laplace　transformation　Then　the　Mori-Tanaka　equivalent　inclusion　and　average　theory　were　used　to　deduce　the 　viscoelastic　performance　of　asphalt　mixture　based　on　that　of　asphalt　mortar　in 　Laplace　space　The　result　shows　that　(1)　coarse　aggregate　inclusion　can　enhance the　viscoelastic　performance　of　fine　aggregate?filler?binder　matrix　and　viscoelastic　constitutive　relation　of　asphalt　mixtures　can　be　expressed　as　the　product　of　an　enhancement　coefficient　of　coarse　aggregate　and　the　viscoelastic　constitutive　relation　of　fine　aggregate?filler?binder　matrix;　(2)　the　viscoelasticity　of　the　complex　asphalt　mixture　can　be　predicted　from　the　viscoelasticity　of　the　homogeneous　fine　aggregate?filler?binder　matrix　by　using　the　nhancement　coefficient;　(3)　the　enhancement　coefficient　is　higher　than　10　and　it　rises　with　increasing　of　coarse　aggregates'　volumetric　fraction　or　Poisson's　ratio　of　fine　aggregate-filler-binder　matrix　but　the　effect　of　the　former　is　more　important　than　that　of　the　latter     

Experimental Study on Damage Assessment of Concrete T-beam Bridges

The　effect　of　damaged　transverse　connection　of　diaphragm　beams　on　the　bearing　capacity　of　prefabricated　concrete　T?beam　bridges　was　studied　through　model　experiment　and　finite　element　analysis　On　the　basis　of　standard　drawing　of　16　m　T?beam　bridge,a　refabricated　concrete　T?beam　bridge　model　on　the　scale　of　1　to　4　was　designed　by　using　of　welding　steel　plate　The　impacts　of　different　condition　on　transverse　load　distribution　were　discussed　The　result　shows　that　(1)　flange　connection　has　little　impact　on　the　transverse　load　distribution　when　the　diaphragm　beams　are　connected　reliably;　(2)　the　damage　of　transverse　connections　has　much　influence　on　the　transverse　load　distribution　of　adjacent　girders　but　it　has　little　effect　on　the　girders　apart　from　them;　(3)　if　a　certain　transverse　connection　is　damaged　entirely　except　for　that　of　the　end　diaphragm　beams,the　load　distribution　would　not　degenerate　to　the　conditions　determined　by　the　flange　connection　because　of　the　advantageous　effects　of　the　other　diaphragm　beams;　(4)　only　when　the　bilateral　diaphragms　of　one　beam　are　damaged　at　the　same　time,the　lateral　load　distribution　will　degenerate　to　the　conditions　determined　by　the　flange　connection     

Study of Tunneling Technology in Tertiary Sandy Mudstone Strata with Rich Water under High Pressure: Case Study of Shuangfeng Tunnel of Mudanjiang Suifenhe Railway（第三系高压富水砂泥岩地层隧道技术研究——以牡绥铁路双丰隧道为例）

In order to deal with the technical problems of Shuangfeng Tunnel passing through water rich Tertiary sandy mudstone strata with long distance and big overburden, such as dewatering, advance reinforcement, structural design and construction method etc., reducing tunnel deformation, preventing water inrush, gushing mud and tunnel collapse, the technical route of "stereo exploration, pressure reduction by water releasing, pre grouting, supporting timely, overall monitoring" is established after the field test and data analysis. Methods of full dimensional exploration and water pressure reducing are proposed, which form the preceding reinforcing technology that are different between inside the excavation contour and outside the excavation contour. Support linings are constructed immediately after excavation of upper bench. Safety performance of tunnel structure is evaluated according to the monitoring results. The research is conducted based on Shuangfeng Tunnel and the study results are applied in the construction of the tunnel. Results indicate that it can make sense to control deformation and ensure safety by using methods of reducing pressure through full dimensional water release, adopting advance reinforcement measures that are different between inside the excavation contour and outside the excavation contour, proposing mini bench method during tunnel construction and supporting timely after excavation for tunnels passing through water rich Tertiary sandy mudstone strata.     

Research on Heat Transfer Model of Asphalt Pavements Subjected to Microwave Heating Recycling

In　order　to　assess　temperature　field　in　microwave　heating　for　recycling　asphalt　pavements,a　2D　mathematic　heat　transfer　model　was　developed　based　on　Fourier　heat　transfer　theory　The　microwave　internal　heat?generation　was　researched　by　using　surface　field　of　pyramidal　horn　replacing　approximate　radiation　field　In　addition,the　boundary　conditions　were　built　and　normalization　processing　was　implemented　The　control　volume　based　finite　differential　method　(CV-BDM)　was　used　to　establish　the　implicit　discrete　scheme　of　the　conservation equations,and　the　numerical　value　simulation　was　employed　By　continuous　or　intermittent　 radiation　heating　technique,a　microwave　heating　experimental　system　at　2　145　GHz　was　carried　out　to　investigate　temperature　variation　characteristics　of　asphalt　pavements　along　with　heating　time　The　result　shows　that　(1)　the　increase　of　temperature　of　asphalt　mixture　during　microwave　heating　is　obviously　nonlinear,the　temperature　rises　slowly　in　the　initial　stage　of　the　heating　but　increases　rapidly　in　the　late　heating　period;　(2)　the　temperature　distribution　is　non-uniform　that　the　temperature　in　central　area　of　the　surface　is　higher　while　it　is　lower　on　edge;　(3)　the　uniformity　of　temperature　within　asphalt　mixtures　can　be　improved　by　using　intermittent　heating　technique,and　the　heating　time　must　be　reasonable　The　simulation　results　are　in　preferable　agreement　with　the　experiment     

Design and Application of Double shield TBMs  for Urban Metro Tunnels（城市地铁双护盾TBM设计及应用）

With reference to the construction conditions and features of metro tunnels, the design features of double shield TBMs are analyzed and key issues to be considered and settled when a double shield TBMs is used for metro tunnel construction are proposed. The issues include cutterhead′s rock breaking capacity, small curve excavation, selection of backfill grouting technology and jamming prevention and release function in fault and fracture zone, etc., which all have a direct effect on the geological adaptability, tunnel lining quality and tunneling performance of double shield TBMs. Subsequently, the specific design and optimization scheme, which includes the design of cutterhead thick steel plates, tapered shield, monorail hoist and pea gravel backfill and cement slurry grouting, etc., are studied. The success of double shield TBMs in Shenzhen Metro project well proved its remarkable geological adaptability and advantages in efficient mechanized construction.     

Key Rock Mechanics Problems and Countermeasures on Huge Diversion Tunnel of Baihetan Hydropower Station（白鹤滩水电站巨型导流洞关键岩石力学问题与对策）

The large scale diversion tunnel of Baihetan Hydropower Station has complex geological conditions, thus various problems of rock mechanics appeared during the process of excavation. Typical damage and fracture mechanics are analyzed in depth, including the collapse along weak rock joint, stress controlled spalling, failure modes of fractured rock mass, relaxation damage of fractured rock columnar joints, localized stress affected by structural surfaces and stress controlled problems of superior fracture combinations. Engineering countermeasures are also summarised, which includes supporting measures, construction methods, supporting time, and monitoring and feedback methods for different types of failure. Through these measures, rock mechanics problems are successfully solved. Stability control of the surrounding rock of underground caverns under complicated geological conditions are achieved, ensuring successful completion of the enormous diversion tunnel of Baihetan.      

Key Construction Technologies for Overlapping Twisted Shield bored Tunnels in Weak Water rich Strata(富水软弱地层中麻花型盾构隧道群施工关键技术)

The project under study is an overlapping twisted shield bored tunnels in weak water rich strata. The purpose of the study is to solve the key technological problems in the construction of the project. The optimal construction sequence of the overlapping twisted shield tunnels is determined according to the engineering geological conditions, the surrounding working environment, and theoretical analysis on the spatial relationship of the four tunnels, and verification control are carried out via monitoring means. The tunnel construction is properly timed, smart self propelled movable support jumbo is adopted, and grouting reinforcement technology is used to ensure the construction safety of the overlapping twisted shield bored tunnels. The grouting pre reinforcement technology and the clay shock technology are adopted to ensure the safety of the surrounding buildings. The technologies for the construction of the overlapping twisted shield bored tunnels described in this paper is of great significance for the construction of similar overlapping tunnels with high shield launching/receiving risks and crossing under important structures with small clearance.     

括苍山隧道二号通风竖井正向施工导碴井、二次扩挖法施工技术

No. 2 ventilation shaft of Kuocangshan tunnel on Zhuji Yongjia expressway has complex geologic condition, many construction difficulties and short construction schedule. In order to complete the project on time, the construction technology of "muck dropping shaft sinking and secondary enlarging excavation" is selected for the sinking of the shaft from several shaft sinking methods, including conventional one time shaft sinking method, "muck dropping shaft sinking and secondary enlarging excavation" method and raise boring method. The selected construction technology is presented in this paper. This technology not only achieves good results in construction schedule, construction safety and construction quality, but also reduces the construction cost.     

Achievements and Challenges of Tunneling Technology in China over Past 40 Years（中国隧道工程技术发展40年）

In this paper, the current situation of tunnel engineering in China is introduced, especially the achievements obtained in the field of tunnel construction since the reform and opening up over 40 years. The 34 708 km long traffic tunnel built after reform and opening up takes 96% of the total length. The challenges met and achievements obtained during the key tunnel projects construction in China are presented emphatically from the aspects of extra long tunnel, deep tunnel, large tunnel, tunnel at high altitude and tunnel in complex environment. It is pointed out that: the main technological challenges during extra long tunnel construction are the accuracy of geological investigation, rapid construction and running disaster prevention; the main challenges during deep tunnel construction are high geostress, high waterpressure and high geothermal; the large tunnel faces high design and construction challenges; the challenges during tunnel construction at high altitude are freezing thawing and hypoxia; but still, many tunnels have been built under complex environments, including karst, gas, high geostress, high waterpressure, expansive rock, etc., and many technological breakthroughs have been achieved. The development trend of tunnel projects in China is proposed from the aspects of investigation, design, construction and operation, turning the development speed into development quality. It is generally acknowledged that the tunnel engineering achievements in China over the past 40 years benefit significantly from the development of international tunnel technology. Meanwhile, the development of tunneling technology in China has also greatly contributed to the international tunnel engineering development.     

Experimental Research on Fatigue Behavior of Reinforced Concrete Reams Strengthened with HPFL under Overloading Conditions

In　order　to　study　the　fatigue　behavior　of　RC　beams　strengthened　with　High　Performance　Ferrocement　Laminates　(HPFL)　under　overloading　conditions,static　and　fatigue　experiments　were　conducted　on　two　control　beams　and　nine　strengthened　beams　The　failure　mode,fatigue　life,deflection　and　material　strain　under　overloading　conditions　were　analyzed　The　result　shows　that　(1)　fatigue　failure　of　the　beams　subjected　to　overload　starts　with　steel　rupture　at　the　bottom　and　the　fatigue　life　is　only　between　327　000　and　668　000　while　fatigue　 life　of　strengthened　beams　is　greater　than　two　million　times　in　case　of　not　overload ing;　(2)　compared　with　the　control　specimen,the　fatigue　life　of　strengthened　beams　is　obvio usly　extended　and　increased　with　the　increase　of　steel　mesh　consumption;　(3)　after　the　same　number　of　cycles,the　deflections,the　strains　of　concrete　and　steels　of　four　strengthened　beams　are　lower　than　those　of　the　control　specimen　Debonding　at　the　interface　of　HPFL　and　concrete　is　not　observed　because　of　shear　pins　planted　at　the　end　of　the　beams     

Research on Adaptability of Semi?rigid Material as Base Course for Long-life Asphalt Pavement

In　the　light　of　semi?rigid　material　as　base　course　for　perpetual　asphalt　pavement,the　bearing　capacity　and　fatigue　life　of　asphalt　pavement　with　semi-rigid　base　cause　and　different　asphalt　layer's　thickness　were　computed　with　BISAR30　after　chosen　typical　pavement　The　impact　of　thickened　layer　on　the　stress　of　the　semi?rigid　base,the　dry　shrinkage　and　temperature　shrinkages　of　the　material　were　analyzed,and　its　adaptability　as　base　for　perpetual　pavement　was　studied　The　result　shows　that　(1)　under　the　same　load,with　thickening　of　the　asphalt　layer,the　compressive　stress　on　the　top　and　the　tensile　stress　at　the　bottom　of　the　semi?rigid　base　decrease　obviously　and　the　fatigue　life　of 　the　base　increases　substantially;　(2)the　impact　of　temperature　and　humidity　on　the 　semi-rigid　base　is　remarkably　weakened,which　leads　to　the　fractures,erosion　and　reflecting　cracks　of　the　semi?rigid　base　to　be　controlled　effectively     

Some Key Technical Issues on Construction of Ultra long Deep buried Water Conveyance Tunnel under Complex Geological Conditions（复杂地质条件下跨流域调水超长深埋隧洞建设需研究的关键技术问题）

For the water conveyance tunnels in the long distance water diversion projects constructed or planned in China, most of them have to pass through mountain areas with complex geological conditions, due to the constraints of route selection. These tunnels might face engineering problems such as harsh natural environment, high seismic intensity and steep terrain, leading to difficulties in construction and high operational risks. In this paper, some key technical issues on the construction of ultra long deep buried water conveyance tunnels under complex geological conditions are summarized into 5 aspects, namely, (1) exploration and testing techniques for deep buried tunnels, (2) prediction and prevention for large deformation and rock burst in the surrounding rock masses, (3) failure mechanism and anti faulting techniques of the surrounding rock masses and lining for tunnels crossing active faults, (4) synergistic load bearing mechanism and life cycle design theory for rock support system of deep buried tunnels, (5) disaster treatment for deep and long tunnels such as prevention of high pressure water inrush. The scientific and technical problems to be solved and their development directions are pointed out, which can provide some reference for engineering construction of ultra long deep buried tunnels.