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sábado, 7 de junio de 2014

HANDBOOK OF TUNNEL ENGINEERING 2 VOL



ingenieria_arte: Handbook of Tunnel Engineering I: Structures and Methods  

Handbook of Tunnel Engineering I: Structures and Methods 
Autor: Maidl,Bernhard,Thewes,Markus, Maidl,Ulrich,Sturge,David S.


  • Páginas: 482
  • Tamaño: 17x24
  • Edición:
  • Idioma: Inglés
  • Año: 2013
  • 103,00
  •  
  • SI  LO DESEA PUEDE EFECTUAR SU PEDIDO EN WWW.INGENIERIAYARTE.COM

Tunnel engineering is one of the oldest, most interesting but also challenging engineering disciplines and demands not only theoretical knowledge but also practical experience in geology, geomechanics, structural design, concrete construction, machine technology, construction process technology and construction management. The two-volume "Handbuch des Tunnel- und Stollenbaus" has been the standard reference for German-speaking tunnellers in theory and practice for 30 years. The new English edition is based on a revised and adapted version of the third German edition and reflects the latest state of knowledge. The book is published in two volumes, with the first being devoted to more practical themes of construction and construction process in drill and blast and mechanised tunnelling. Microtunnelling and ventilation are also dealt with. All chapters include practical examples.
TOMO II A LA VENTA EN OCTUBRE
Table of Contents
Volume I: Structures and Methods
The authors
Foreword to the English edition
Foreword to the 3rd German edition
Foreword to the 2nd German edition
Foreword to the 1st German edition
1 Introduction
1.1 General
1.2 Historical development
1.3 Terms and descriptions
2 Support methods and materials
2.1 General
2.2 Action of the support materials
2.2.1 Stiffness and deformability
2.2.2 Bond
2.2.3 Time of installation
2.3 Timbering
2.3.1 General
2.3.2 Frame set timbering
2.3.3 Trussed timbering
2.3.4 Shoring and lagging
2.4 Steel ribs
2.4.1 General
2.4.2 Profile forms
2.4.3 Examples of typical arch forms for large and small tunnels
2.4.4 Installation
2.5 Lattice beam elements
2.6 Advance support measures
2.6.1 Steel lagging sheets and plates
2.6.2 Spiles
2.6.3 Injection tubes 
2.6.4 Pipe screens, grout screens, jet grout screens
2.6.5 Ground freezing
2.7 Rock bolts
2.7.1 General
2.7.2 Mode of action
2.7.3 Anchor length and spacing
2.7.4 Load-bearing behaviour
2.7.5 Anchor types
2.8 Concrete in tunnelling
2.8.1 General
2.8.2 Construction variants
2.8.2.1 Two-layer construction
2.8.2.2 Single-layer construction
2.8.3 Shotcrete
2.8.3.1 General
2.8.3.2 Process technology, equipment and handling
2.8.3.3 Mixing and recipes
2.8.3.4 Influence of materials technology and process technology
2.8.3.5 Quality criteria, material behaviour and calculation methods, quality control
2.8.3.6 Mechanisation of shotcrete technology
2.8.3.7 Steel fibre concrete
2.8.3.8 Working safety
2.8.4 Cast concrete 
2.8.4.1 Formwork
2.8.4.2 Concreting
2.8.4.3 Reinforced or unreinforced concrete lining
2.8.4.4 Factors affecting crack formation
2.8.4.5 Disadvantages of nominal reinforcement
2.8.4.6 Stripping times
2.8.4.7 Filling of the crown gap
2.8.4.8 Joint details
2.8.4.9 Single-pass process, extruded concrete
2.8.4.10 After-treatment
2.8.5 Precast elements, cast segments
2.8.5.1 Steel segments
2.8.5.2 Cast steel segments
2.8.5.3 Cast iron segments
2.8.5.4 Reinforced concrete segments
2.8.5.5 Geometrical shapes and arrangement
2.8.5.6 Details of radial joints
2.8.5.7 Circumferential joint details
2.8.5.8 Fixing and sealing systems
2.8.5.9 Segment gaskets
2.8.5.10 Production of reinforced concrete segments
2.8.5.11 Installation of segment lining
2.8.6 Linings for sewer tunnels
2.8.7 Yielding elements
3 The classic methods and their further developments
3.1 General
3.2 Full-face excavation
3.3 Partial-face excavation
3.3.1 Bench excavation
3.3.2 The Belgian or underpinning tunnelling method
3.3.3 The German or remaining core tunnelling method
3.3.4 The Austrian or upraise tunnelling method
3.3.5 The New Austrian Tunnelling Method
3.3.6 The English tunnelling method
3.3.7 The Italian or packing tunnelling method
3.4 Classic shield drives
3.5 The classic tunnelling machines
4 Shotcrete tunnelling
4.1 General
4.2 Top heading process
4.2.1 Shotcrete tunnelling method
4.2.2 Underpinning method
4.2.3 Crown pilot heading with crown beam 
4.2.4 Shotcrete tunnelling with longitudinal slots
4.3 Core tunnelling method with side headings
4.4 Special processes using shotcrete
4.4.1 Compressed air
4.4.2 Ground freezing, grouting
4.5 Shotcrete in mining
4.5.1 Tunnel support
4.5.2 Shaft insets
4.6 Outlook for further development
4.7 The new Italian tunnelling method (ADECCO-RS)
4.7.1 Theoretical model
4.7.2 Procedure through the example of the new line from Bologna – Florence
5 Drill and blast tunnelling
5.1 Historical development
5.2 Drilling 
5.2.1 General
5.2.2 Drills
5.2.3 Drill bits
5.2.4 Wear
5.2.5 Performance
5.2.6 Costs
5.3 Blasting
5.3.1 General 211
5.3.2 Explosives in tunnelling
5.3.3 Detonators and detonation systems in tunnelling
5.3.4 Transport, storage and handling of explosives
5.3.5 Charge determination
5.3.6 The drilling and firing pattern
5.3.7 Charge loading
5.3.8 Time calculation
5.3.9 Blasting technology aspects
5.4 Mucking
5.4.1 General
5.4.2 Loading machines
5.4.3 Muck conveyance
5.4.4 Output of transport vehicles
5.4.5 Examples of transport chains
5.4.6 Further developments
5.5 Combination of drill and blast with mechanised tunnelling processes
5.5.1 Combinations with roadheaders
5.5.2 Combination with full-face machines
5.6 Effects of blasting on the surroundings
5.6.1 Vibration
5.6.2 Composition and effects of the blasting gas emissions
5.7 Mechanisation and Automation
5.7.1 General
5.7.2 Emphasis of mechanisation
5.7.3 Computer-assisted drill jumbos
5.7.4 Mucking and tunnel logistics
6 Mechanised tunnelling
6.1 General
6.2 Categories of tunnelling machines
6.3 Shield machines
6.3.1 Categories of shield machines
6.3.2 Basic principle, definition
6.3.3 Face without support
6.3.4 Face with mechanical support
6.3.5 Face under compressed air
6.3.6 Face with slurry support
6.3.6.1 Functional principle
6.3.6.2 Slurry shield
6.3.6.3 Thixshield
6.3.6.4 Hydroshield
6.3.6.5 Mixshield as a Hydroshield version
6.3.6.6 Hydrojetshield
6.3.6.7 Hydraulic soil transport
6.3.6.8 Soil separation in shield operation with hydraulic transport
6.3.7 Face with earth pressure support
6.3.7.1 Functional principle
6.3.7.2 Scope of application and soil conditioning process
6.3.7.3 Use of foam with earth pressure shields
6.3.8 Blade tunnelling and blade shields
6.3.9 The most important verification calculations
6.3.9.1 Calculation of face stability with slurry and earth pressure support
6.3.9.2 Calculation of safety against breakup and blowout
6.3.9.3 Calculation of thrust force
6.3.9.4 Determination of the air demand for compressed air support
6.4 Tunnel boring machines in hard rock
6.4.1 Categorisation of machines for use in hard rock
6.4.2 Basic principles 
6.4.3 Boring system
6.4.4 Thrust and bracing system
6.4.5 Support system
6.4.6 Ventilation
6.4.7 The use of slurry and earth pressure shields in hard rock formations
6.5 Special processes: combinations of TBM drives with shotcrete tunnelling
6.5.1 Areas of application
6.5.2 Construction possibilities
6.5.3 Example
6.6 Roadheaders (TSM) and tunnel excavators
6.6.1 Basic principle of a roadheader
6.6.2 Rock excavation by a roadheader
6.6.3 Ventilation and dust control with a roadheader
6.6.4 Profile and directional control of roadheaders
6.6.5 Construction sequence using a roadheader
6.6.6 Additional equipment and variations of roadheaders
6.6.7 Criteria for the selection of a roadheader
6.6.8 Comparison of partial face and full face machines
6.6.9 Combination of full face and partial face machines
6.6.10 Contour cutting process
6.6.11 Tunnel excavators
6.7 Checking the tunnelling machine for suitability and acceptance based on a risk analysis
6.7.1 Strategy to contain risk
6.7.2 Basic design
6.7.3 Analysis of obstructions
6.7.4 Machine specification
6.7.5 Acceptance of the TBM
6.7.6 Shield handbook
6.7.7 Data checks, functional tests
6.7.8 Implementation of the strategy through the example of the Elbe Tunnel and the Lefortovo Tunnel
6.7.9 Recommendations for the future
7 The driving of small cross-sections
7.1 General
7.2 Manned processes
7.2.1 General 
7.2.2 Pipe jacking
7.3 Unmanned processes
7.3.1 General
7.3.2 Non-steerable processes, or with limited control of direction
7.3.3 Guided processes
7.4 Shafts and jacking stations
7.4.1 Thrust shaft
7.4.2 Reception shaft
7.4.3 Main jacking station
7.4.4 Intermediate jacking stations
7.5 Support, product pipe
7.5.1 Loading during pipe jacking
7.5.2 Loading in operation
7.5.3 Insertion of the product pipe
8 Ventilation during the construction phase
8.1 General
8.2 Ventilation systems
8.2.1 Natural ventilation
8.2.2 Positive pressure ventilation
8.2.3 Extraction ventilation
8.2.4 Reversible ventilation
8.2.5 Combined ventilation.
8.2.6 Recirculation systems
8.3 Materials
8.3.1 Fans
8.3.2 Air ducts
8.3.3 Dedusters
8.4 Design and cost
8.5 Special ventilation systems
8.5.1 Ventilation for TBM drives
8.5.2 Ventilation of roadheader drives
8.5.3 Automatic ventilation
Bibliography
Index
  ingenieria_arte: Handbook of Tunnel Engineering II: Basics and Additional Services for Design and Construction

Handbook of Tunnel Engineering II: Basics and Additional Services for Design and Construction  

Autor: Maidl,Bernhard, Thewes,Markus, Maidl,Ulrich


  • Páginas: 458
  • Tamaño: 17x24
  • Edición:
  • Idioma: Inglés
  • Año: 2014
  • 103,00 Euros  
 SI LO DESEA PUEDE EFECTUAR SU COMPRA EN  WWW.INGENIERIAYARTE.COM
Tunnel engineering is one of the oldest, most interesting but also challenging engineering disciplines and demands not only theoretical knowledge but also practical experience in geology, geomechanics, structural design, concrete construction, machine technology, construction process technology and construction management. The two-volume "Handbuch des Tunnel- und Stollenbaus" has been the standard reference work for German-speaking tunnellers in theory and practice for 30 years. The new English edition is based on a revised and adapted version of the third German edition and reflects the latest state of knowledge. The book is published in two volumes, with the second volume covering both theoretical themes like design basics, geological engineering, structural design of tunnels and monitoring instrumentation, and also the practical side of work on the construction site such as dewatering, waterproofing and scheduling as well as questions of tendering, award and contracts, data management and process controlling. As with volume I, all chapters include practical examples.
Table of Contents
Volume II: Basics and Additional Services for Design and Construction*
The authors V
Foreword to the English edition
Foreword to the 3rd German edition
Foreword to the 2nd German edition
Foreword to the 1st German edition
1 General Principles for the Design of the Cross-section
1.1 General
1.2 Dependence on intended use 
1.2.1 Road tunnels
1.2.2 Constructional measures for road safety in tunnels
1.2.3 Rail tunnels
1.2.4 Construction of rail tunnels
1.2.5 Underground railway and underground tram tunnels
1.2.6 Innovative transport systems 
1.2.7 Monorail with magnetic levitation, Transrapid, Metrorapid
1.2.8 Other underground works  
1.3 The influence of the ground
1.4 Dependency on construction process
2 Engineering geology aspects for design and classification
2.1 General
2.2 Origin, properties and categorisation of rocks
2.2.1 General basics
2.2.2 Categorisation of rocks 
2.2.3 Categorisation of soils 
2.3 Engineering geology and rock mechanics in
2.3.2 Rock mechanics investigations
2.4 The ground and its classification 
2.4.1 Ground
2.4.2 Classification of the rock mass
2.4.2.1 General
2.4.2.2 Basic system of classification 
2.4.2.3 Q System (Quality System)
2.4.2.4 RMR System (Rock Mass Rating System)
2.4.2.5 Relationship between Q and RMR systems
2.4.3 Standards, guidelines and recommendations 
2.4.3.1 Classification in Germany
2.4.3.2 Classification in Switzerland (“Klassierung” according to the SIA standard) 
2.4.3.3 Classification in Austria
2.4.4 Example of a project-related classification according to DIN 18312 for the shotcrete process
2.4.4.1 Procedure at the Oerlinghausen Tunnel
2.4.4.2 Description of the tunnelling classes for the Oerlinghausen Tunnel
2.5 Special features for tunnelling machines
2.5.1 General
2.5.2 Influences on the boring process
2.5.3 Influences on the machine bracing
2.5.4 Influences on the temporary support
2.5.5 Classification for excavation and support
2.5.5.1 General and objective for mechanised tunnelling
2.5.5.2 Classification systems and investigation of suitability for tunnel boring machines
2.5.6 Standards, guidelines and recommendations 
2.5.6.1 Classification in Germany
2.5.6.2 Classification in Switzerland 
2.5.6.3 Classification in Austria
2.5.7 New classification proposal
3 Structural design verifications, structural analysis of tunnels
3.1 General
3.2 Ground pressure theories 
3.2.1 Historical development 
3.2.2 Primary and secondary stress states in the rock mass
3.2.2.1 Primary stress state
3.2.2.2 Secondary stress state 
3.2.2.3.General steps of model formation  
3.4 Analytical processes and their modelling
3.4.1 Modelling of shallow tunnels in loose ground
3.4.2 Modelling deep tunnels in loose ground
3.4.3 Modelling tunnels in solid rock
3.4.4 Bedded beam models 
3.5 Numerical methods
3.5.1 Finite Difference Method (FDM)
3.5.2 Finite Element Method (FEM)
3.5.3 Boundary Element Method (BEM)
3.5.4 Combination of finite element and boundary element methods
3.6 The application of the finite element method in tunnelling 
3.6.1 “Step-by-Step” technique  
3.6.2 Iteration process
3.6.3 Simulation of uncoupled partial excavations 
3.7 Special applications of the FEM in tunnelling
3.7.1 Modelling of deformation slots
3.7.2 Determination of the loosening of the rock mass from blasting
3.8 Structural design
3.8.1 General principles 
3.8.2 Design method for steel fibre concrete tunnel linings
3.8.3 Conventionally reinforced shotcrete versus steel fibre shotcrete
4 Measurement for monitoring, probing and recording evidence
4.1 General
4.2 Measurement programme
4.2.1 General
4.2.2 Measurements of construction states
4.2.2.1 Standard monitoring section
4.2.2.2 Principal monitoring sections 
4.2.2.3 Surface measurements  
4.2.2.4 Basic rules for implementation and evaluation 
4.2.3 Measurement of the final state
4.2.3.1 Measurement programme  
4.2.3.2 Evaluation
4.2.4 Special features of shield drives
4.2.4.1 Instrumentation
4.2.4.2 Recording and evaluation of machine data
4.2.5 IT systems for the recording and evaluation of geotechnical data
4.3 Measurement processes, instruments
4.3.1 Deformation measurement
4.3.1.1 Geodetic surveying
4.3.1.2 Convergence measurements
4.3.1.3 Optical surveying of displacement with electronic total station
4.3.1.4 Surface surveying 
4.3.1.5 Extensometer measurements
4.3.1.7 Sliding micrometer measurements
4.3.1.8 Trivec measurements 
4.3.2 Profile surveying
4.3.2.1 Photogrammetric scanner 
4.3.3 Stress and strain measurements in the support layer
4.3.3.1 Radial and tangential stress measurement in concrete
4.3.3.2 Measurements in steel arches 
4.3.4 Measurements of the loading and function of anchors
4.3.4.1 Checking of anchor forces in unbonded anchors
4.3.4.2 Checking of anchor forces with mechanical measurement anchors
4.4 Geophysical exploration ahead of the face
4.4.1 Seismology
4.4.2 Geoelectrical
4.4.3 Gravimetric
4.4.4 Geomagnetic
4.4.5 Geothermal
4.4.6 Examples and experience  
4.4.6.1 Probing with SSP (Sonic Softground Probing) 
4.4.6.2 Probing karst caves
4.5 Monitoring and evidence-gathering measures for tunnelling beneath buildings and transport infrastructure
4.5.1 General
4.5.2 Monitoring and evidence-gathering measures
4.5.3 Noise and vibration protection
4.5.4 Permissible deformation of buildings
5 Dewatering, waterproofing and drainage
5.1 General
5.2 Dewatering during construction
5.2.1 Water quantity and difficulties
5.2.1.1 Water flow in the ground  
5.2.1.2 Forms of underground water 
5.2.1.3 Payment and quantity measurement
5.2.2 Measures to collect and drain groundwater
5.2.2.1 Measures to collect water 
5.2.2.2 Measures to drain water, open dewatering
5.2.2.3 Drainage boreholes and drainage tunnels
5.2.3 Obstructions and reduced performance
5.2.3.1 General description
5.2.3.2 Influence of groundwater on the advance rate
5.2.3.3 Influence of groundwater on tunnelling costs 
5.2.4 Environmental impact and cleaning
5.2.4.1 Effect on the groundwater system
5.2.4.2 Effects on groundwater quality
5.2.5 Sealing groundwater
5.2.5.1 Grouting process
5.2.5.2 Ground freezing
5.3 Tunnel waterproofing
5.3.1 Requirements 
5.3.1.1 Required degree of water-tightness
5.3.1.2 Requirements resulting from geological and hydrological conditions
5.3.1.3 Material requirements 
5.3.1.4 Requirements for the construction process
5.3.1.5 Requirements for design and detailing
5.3.1.6 Maintenance
5.3.1.7 Requirements of the users 
5.3.1.8 Requirements of environmental and waterways protection
5.3.1.9 Requirements of cost-effectiveness
5.3.2 Waterproofing concepts
5.3.2.1 Categorisation 
5.3.2.2 Preliminary waterproofing
5.3.2.3 Main waterproofing
5.3.2.4 Repair of waterproofing
5.3.3 Waterproofing elements and materials
5.3.3.1 Waterproof concrete
5.3.3.2 Water-resistant plaster, sealing mortar, resin concrete
5.3.3.3 Bituminous waterproofing
5.3.3.4 Plastic waterproofing membranes
5.3.3.5 Sprayed waterproofing 
5.3.3.6 Metallic waterproofing materials
5.3.4 Testing of seams in waterproofing membranes 
5.4 Tunnel drainage
5.4.1 The origin of sintering 
5.4.2 Design of tunnel drainage for low sintering
5.4.3 Construction of tunnel drainage to reduce sintering
5.4.3.1 Camera surveys of the pipe runs between the manholes
5.4.3.2 Data processing and administration
5.4.3.3 Other quality assurance measures during the construction phase
5.4.4 Operation and maintenance of drainage systems to reduce sintering
5.4.4.1 Concepts to reduce maintenance through improvements to systems
5.4.4.2 Cleaning of drainage systems
6 New measurement and control technology in tunnelling
6.1 General
6.2 Measurement instruments
6.2.1 Gyroscopic devices
6.2.2 Lasers
6.2.3 Optical components for laser devices
6.2.4 Optical receiver devices
6.2.5 Hose levelling instruments
6.2.6 Inclinometer
6.3 Control in drill and blast tunnelling
6.3.1 Drilling jumbo navigation
6.3.2 Determining the position of a drilling boom 
6.3.3 Hydraulic parallel holding of the feeds
6.3.4 Control of drill booms by microprocessors
6.3.5 Hydraulic drill booms 
6.4 Control of roadheaders
6.4.1 Movement parameters determined by the control system
6.4.2 Roadheader control system from Voest Alpine 
6.4.3 Roadheader control system from Eickhoff
6.4.4 Roadheader control system from ZED
6.5 Control of tunnel boring machines (TBM)
6.5.1 General
6.5.2 Steering with laser beam and active target
6.6 Steering of small diameter tunnels
6.6.1 General
6.6.2 Steering with a ship’s gyrocompass
6.6.3 Pipe jacking steering with laser beam and active target
6.6.4 Steering with travelling total station
7 Special features of scheduling tunnel works
7.1 General
7.2 Historical overview
7.3 General planning of tunnel drives 
7.4 Planning tools
7.5 Control methods
7.5.1 Control of deadlines
7.5.2 Cost control
7.6 Examples of construction schedules 
7.6.1 Construction schedule for the City Tunnel, Leipzig
7.6.2 Scheduling of rail tunnels through the example of the Landrücken Tunnel and the particular question of starting points
7.6.3 Scheduling of road tunnels through the example of the Arlberg Tunnel
7.6.4 Scheduling of inner-city tunnelling through the example of the Stadtbahn Dortmund
7.6.5 Scheduling of a shield tunnel through the example of Stadtbahn Essen
8 Safety and safety planning 
8.1 General
8.2 International guidelines and national regulations
8.2.1 Directive 89/391/EEC 
8.2.2 Directive 92/57/EEC 
8.2.3 Directive 93/15/EEC
8.2.5 Implementation into national regulations for blasting
8.3 Integrated safety plan
8.3.1 The safety plan as a management plan
8.3.2 Safety objectives
8.3.3 Danger scenarios and risk analyses
8.3.4 Measures plan
8.4 Transport, storage and handling of explosives
8.4.1 Transport to the site
8.4.2 Storage on the site
8.4.3 Transport on site
8.4.4 Handling
8.5 Training of skilled workers
8.6 The construction site regulations (BaustellV)
8.6.1 General
8.6.2 The tools of the construction site regulations 
8.6.3 The health and safety plan (health and safety plan)
8.6.4 Working steps in the production of a health and safety plan
8.7 Example of a tender for health and safety protection
8.7.1 General
8.7.2 Health and safety concept  
8.7.2.1 Hazard analyses
8.7.2.2 Fire protection, escape and rescue concept
8.7.2.3 Health protection concept  
8.7.2.4 Site facilities plans
8.7.2.5 Concept for traffic control measures inside the site area
8.7.2.6 Documents with information for later works to the structure
8.7.2.7 Measures to prevent danger to third parties resulting from the duty to maintain road safety
9 Special features in tendering, award and contract
9.1 General
9.2 Examples of forms of contract
9.2.1 Procedure in Switzerland  
9.2.2 Procedure in the Netherlands 
9.2.3 Procedure in Germany  
9.3 Design and geotechnical requirements for the tendering of mechanised tunnelling as an alternative proposal  
9.3.1 General
9.3.2 Examples: Adler Tunnel, Sieberg Tunnel, Stuttgart Airport Tunnel, Rennsteig Tunnel, Lainzer Tunnel
9.3.3 Additional requirements for mechanised tunnelling in the tender documents
9.3.4 Costs as a decision criterion
9.3.5 Outlook
10 Process controlling and data management
10.1 Introduction
10.2 Procedure
10.3 Data management
10.4 Target-actual comparison 
10.5 Target process structure
10.6 Analysis of the actual process
11 DAUB recommendations for the selection of tunnelling machines
11.1 Preliminary notes
11.2 Regulatory works
11.2.1 National regulations
11.2.2 International standards  
11.2.3 Standards and other regulatory works
11.3 Definitions and abbreviations
11.3.1 Definitions
11.3.2 Abbreviations 
11.4 Application and structure of the recommendations
11.5 Categorisation of tunnelling machines
11.5.1 Types of tunnelling machine (TVM)
11.5.2 Tunnel boring machines (TBM)
11.5.2.1 Tunnel boring machines without shield (Gripper TBM)
11.5.2.2 Enlargement tunnel boring machines (ETBM) 
11.5.2.3 Tunnel boring machine with shield (TBM-S)
11.5.3 Double shield machines (DSM)
11.5.4 Shield machines (SM)  
11.5.4.1 Shield machines for full-face excavation (SM-V)
11.5.4.2 Shield machines with partial face excavation (SM-T)
11.5.5 Adaptable shield machines with convertible process technology (KSM)
11.5.6 Special types
11.5.6.2 Shields with multiple circular cross-sections 
11.5.6.3 Articulated shields
11.5.7 Support and lining
11.5.7.1 Tunnel boring machines (TBM)
11.5.7.2 Tunnel boring machines with shield (TBM-S), Shield machines (SM, DSM, KSM)
11.5.7.3 Advance support
11.5.7.4 Support next to the tunnelling machine
11.6 Ground and system behaviour
11.6.1 Preliminary remarks
11.6.2 Ground stability and face support
11.6.3 Excavation
11.6.3.1 Sticking
11.6.3.2 Wear
11.6.3.3 Soil conditioning
11.6.3.4 Soil separation
11.6.3.5 Soil transport and tipping  
11.7 Environmental aspects
11.8 Other project conditions 
11.9 Scope of application and selection criteria
11.9.1 General notes about the use of the tables
11.9.1.1 Core area of application
11.9.1.2 Possible areas of application
11.9.1.3 Critical areas of application
11.9.1.4 Classification in soft ground
11.9.1.5 Classification in rock 
11.9.2 Notes about each type of tunnelling machine
11.9.2.1 TBM (Tunnel boring machine)
11.9.2.2 DSM (Double shield machines)
11.9.2.3 SM-V1 (full-face excavation, face without support)
11.9.2.4 SM-V2 (full-face excavation, face with mechanical support)
11.9.2.5 SM-V3 (Full-face excavation, face with compressed air application)
11.9.2.6 SM-V4 (full-face excavation, face with slurry support)
11.9.2.7 SM-V5 (full-face excavation, face with earth pressure balance support)
11.9.2.8 SM-T1 (partial excavation, face without support)
11.9.2.9 SM-T2 (partial excavation, face with mechanical support)
11.9.2.10 SM-T3 (partial excavation, face with compressed air application)
11.9.2.11 SM-T4 (Partial excavation, face with slurry support)
11.9.2.12 KSM (Convertible shield machines)
11.10 Appendices
Bibliography  
Index

GEOTECHNICAL DESIGN FOR SUBLEVEL OPEN STOPING



ingenieria_arte: Geotechnical Design for Sublevel Open Stoping  

Geotechnical Design for Sublevel Open Stoping  
Autor: Villaescusa,Ernesto
  • Páginas: 542
  • Tamaño: 17x24
  • Edición:
  • Idioma: Inglés
  • Año: 2014
  •  155,00
SI LO DESEA PUEDE EFECTUAR SU COMPRA EN    www.ingenieriayarte.com

 The first comprehensive work on one of the most important underground mining methods worldwide, Geotechnical Design for Sublevel Open Stoping presents topics according to the conventional sublevel stoping process used by most mining houses, in which a sublevel stoping geometry is chosen for a particular mining method, equipment availability, and work force experience. Summarizing state-of-the-art practices encountered during his 25+ years of experience at industry-leading underground mines, the author:

    Covers the design and operation of sublevel open stoping, including variants such as bench stoping
    Discusses increases in sublevel spacing due to advances in the drilling of longer and accurate production holes, as well as advances in explosive types, charges, and initiation systems
    Considers improvements in slot rising through vertical crater retreat, inverse drop rise, and raise boring
    Devotes a chapter to rock mass characterization, since increases in sublevel spacing have meant that larger, unsupported stope walls must stand without collapsing
    Describes methodologies to design optimum open spans and pillars, rock reinforcement of development access and stope walls, and fill masses to support the resulting stope voids
    Reviews the sequencing of stoping blocks to minimize in situ stress concentrations
    Examines dilution control action plans and techniques to back-analyze and optimize stope wall performance

Featuring numerous case studies from the world-renowned Mount Isa Mines and examples from underground mines in Western Australia, Geotechnical Design for Sublevel Open Stoping is both a practical reference for industry and a specialized textbook for advanced undergraduate and postgraduate mining studies.



Table Contenst

Introduction

Mining Method Selection

Self-Supported Mining Methods

Sublevel Open Stoping

Factors Controlling Stope Wall Behaviour

Scope and Contents of This Book

Sublevel Stoping Geometry

Introduction

Stoping Geometries

Multiple Lift Open Stoping

Single Lift Stoping

Shallow Dipping Tabular Orebodies

Bench Stoping

Planning and Design

Introduction

Geological and Geotechnical Characterisation

Stress Analysis in Stope Design

Design of Stoping Blocks

Detailed Stope Design

Rock Mass Characterisation

Introduction

Characterisation from Exploration Core

Analysis of Logging Data

Geotechnical Mapping of Underground Exposures

Analysis of Mapping Data

Intact Rock Strength

The Mechanical Properties of Rock Masses

Rock Stress

Span and Pillar Design

Background

Empirical Span Determination Using Rock Mass Classification Methods

The Stability Graph Method

Numerical Modelling of Stope Wall Stability

Pillar Stability Analysis

Drilling and Blasting

Introduction

Longhole Drilling

Blast Design Parameters

Ring Design

Explosive Selection

Explosive Placement

Initiation Systems

Raise and Cut-Off Slot Blasting

Trough Undercut Blasting

Rock Diaphragm Blasting

Rock Reinforcement and Support

Introduction

Terminology

Ground Support Design

Rock Bolting of Open Stope Development Drives

Cable Bolting of Open Stope Walls

Cable Bolt Corrosion

Cement Grouting of Cable Bolts

Support Systems

Mine Fill

Introduction

Unconsolidated Rock Fill

Cemented Rock Fill

Hydraulic Fill

Cemented Paste Fill

Open Stope Fill Operations Systems

Fill Monitoring and Quality Control

Dilution Control

Introduction

Types of Dilution

Economic Impact of Dilution

Parameters Influencing Dilution

Cavity Monitoring System (CMS)

Dilution Control Plan

Scale-Independent Measures of Stope Performance

ENGINEERING GEOLOGY FOR UNDERGROUD WORKS



ingenieria_arte: Engineering Geology for Underground Works l

Engineering Geology for Underground Works  
Autor: Gattinoni, Paola, Pizzarotti, Enrico, Scesi, Laura

  • Páginas: 305
  • Tamaño: 17x24
  • Edición:
  • Idioma: Inglés
  • Año: 2014
  • 155,00 Euros 
SI LO DESEA PUEDE EFECTUAR SU COMPRA EN www.ingenieriayarte.com

 This book contains a careful analysis of geological and environmental issues and a correct reconstruction of the conceptual model
This leads to optimal design solutions
This book presents a synthesis of current knowledge about all the issues needed to ensure the safety to the workers during construction and to the users

The construction of tunnels involves the resolution of various complex technical problems depending on the geological and geological-environmental context in which the work fits.

Only a careful analysis of all the geological and geological-environmental issues and a correct reconstruction of the conceptual model can lead to optimal design solutions from all points of view (including financial) and ensure the safety of workers during the construction and users in the operation phase.

It was therefore felt that there was a need to collect in one volume the state of current knowledge about:
•all the geological and environmental issues related to the construction of underground works
•the different methodologies used for the reconstruction of the conceptual model
•the different risk typologies that it is possible to encounter or that can arise from tunnel construction, and
•the most important risk assessment, management and mitigation methodologies that are used in tunneling studies

Table Contents

1.1 Introduction
1.2 Lithological and Structural Features
1.2.1 Lithological Features
1.2.2 Structural Features
1.3 Tectonic Setting
1.3.1 Faults
1.3.2 Folds
1.4 Scale Effect
1.5 In Situ Stress State
1.6 Morphological Conditions
1.6.1 UndergroundWorks at Shallow Depth
1.6.2 Portals
1.7 Hydrogeological Setting
1.7.1 AggressiveWaters
1.8 Weathering and Swelling Phenomena
1.8.1 Weathering
1.8.2 Swelling
1.9 Geothermal Gradient
1.10 Seismic Aspects
1.11 Gas, Radioactivity and Hazardous Materials
1.11.1 Gas
1.11.2 Radon
1.11.3 Asbestos
References

2 Environmental-Geological Problems due to Underground Works

2.1 Introduction
2.2 Surface Settlements
2.3 Slope Instability
2.4 Interaction with SurfaceWater and Groundwater
2.5 Inert Waste
2.6 Noises and Vibrations During Excavation
References

3 Geological Conceptual Model for Underground Works Design

3.1 Introduction
3.2 Geological Studies and Investigations
3.2.1 Characterization of Shallow-Overburden Stretches
3.2.2 Characterization of Medium-High Overburden Stretches
3.2.3 Hydrogeological Surveys
3.3 Geological-Technical Characterization
3.4 Geomechanical Classifications
3.4.1 Bieniawski Classification (or of the RMR Index, Only Relevant for Rock Masses)
3.5 Rock Mass Excavability Index RME
3.5.1 Rock Mass index RMi
3.5.2 Surface Rock Classification SRC
3.5.3 Barton Q-System Classification
3.5.4 QTBM Classification System
3.6 Hoek-Brown Constitutive Model for Rock Mass
3.7 Strength of Discontinuities
3.7.1 Patton Criterion
3.7.2 Barton Equation
3.7.3 Ladanyi and Archanbault Criterion
References

4 Underground Excavation Analysis

4.1 Introduction
4.2 Discontinuous Medium and Equivalent Continuum
4.3 Convergence and Confinement
4.4 UndergroundWorks at Shallow and Great Depth
4.5 Analysis Methods of the Excavation Behaviour
4.5.1 Block Theory
4.5.2 Characteristic Lines
4.5.3 Numerical Methods
4.5.3.1 Distinct Elements Method
4.5.3.2 Finite Elements or Finite Difference Methods
4.6 Squeezing and Time-Dependent Behaviour
4.6.1 Singh et al. (1992) Empirical Approach
4.6.2 Goel et al. (1995) Empirical Approach
4.6.3 Hoek and Marinos (2000) Semi-Empirical Method
4.6.4 Jehtwa et al. Method (1984)
4.6.5 Bhasin Method (1994)
4.6.6 Panet Method (1995)
4.7 Rock Burst
4.8 Face Stability Assessment
4.8.1 Shallow Overburden
4.8.1.1 Undrained Behaviour of Cohesive Soils
4.8.1.2 Grain Material with Drained Behaviour
4.8.1.3 Stability of the Excavation Face by Tamez (1985)
4.8.2 High Overburden
4.8.2.1 Face Stability as a Function of Characteristic Strength of Rock Mass
4.8.2.2 Face Stability with Convergence–Confinement Method
4.8.2.3 Face Stability as a Function of Shear Strength
4.8.2.4 Face Stability in Relationship to the Tensional Field and Mechanical Characteristics of RockMasses
4.8.2.5 Face Stability with the Ground Reaction Curve Method
4.8.2.6 Face Stability Caquot Method
4.9 GroundWater Influence
4.9.1 Assessment of Tunnel Inflows
4.9.1.1 The Draining Process from an Advancing Tunnel
4.9.2 The Influence ofWater on the Mass Behaviour
References

5 Geological Risk Management

5.1 Introduction
5.2 Definitions and General Concepts
5.3 Geological Risk Assessment for UndergroundWorks
5.3.1 Qualitative Methods for Risk Analysis
5.3.2 Quantitative Methods for Risk Analysis: Safety Methods
5.3.3 Monte Carlo Method for Quantitative Risk Analysis
5.3.4 Risk Evaluation
5.4 Applicative Example: The Decision Aid in Tunnelling (DAT)
5.5 From Risk Assessment to Risk Mitigation
References

6 Risk Mitigation and Control


6.1 Introduction
6.2 Excavation Methods
6.2.1 Shielded and Pressurized TBM
6.3 Injections
6.3.1 Injections via Impregnation and Fracturing
6.3.2 Jet-Grouting.
6.4 Freezing
6.5 Cutter Soil Mix (CSM)
6.6 Anchors
6.6.1 Nails
6.6.2 Bolts
6.6.3 Tiebacks
6.7 Drainage
6.8 Reinforced Protective Umbrella Methods (RPUM)
6.8.1 Forepoling
6.8.2 Jet-grouting Vaults
6.8.3 Precutting
6.8.4 Pretunnel
6.9 Linings
6.9.1 First Stage Linings
6.9.1.1 Shotcrete
6.9.1.2 Steel Ribs.
6.9.2 Final Linings
6.9.2.1 In Situ Cast Concrete (Unreinforced and Reinforced)
6.9.2.2 Waterproofing andWater Management Systems
6.9.2.3 Prefabricated Linings
6.9.2.4 Single-Shell (Monocoque) Linings
References

7 Ground-Structure Interaction

7.1 Rabcewicz Theory
7.2 Method of Hyperstatic Reactions
7.3 Evaluation of the Loads Acting on the Linings
7.3.1 Vertical Loads
7.3.1.1 Soils: Caquot and Kerisel’s (1956) and Terzaghi’s (1946) Formulations
7.3.1.2 Rock masses: Terzaghi’s (1946) Classification and Approaches Based on Bieniawski’s Characterization
7.3.2 Horizontal Loads
7.3.3 Inclined Loads
7.3.4 Loads Assessment on the Lining in Case of Tunnel Under Groundwater Table
7.4 Nailing
7.4.1 Method of the Confinement Pressure
7.4.2 Homogenization Method
7.4.3 Modelling of the Cross Section with Continuum Discretization Methods
7.5 Spiling
7.6 Forepoling
7.7 Stabilization of the Excavation Face: Number and Length of the Forepoles
7.8 Characteristic Lines: Analysis of the Linings
7.9 Numerical Methods
7.10 Seismic Aspects
7.11 Final Considerations
References

8 Monitoring

8.1 Introduction
8.2 Geomechanical Surveys
8.3 Measurements of Convergence
8.4 Measures of Rock Deformations
8.4.1 Face Extrusion
8.4.2 Radial Deformations
8.5 Measures on Linings
8.5.1 Assessment of the Strain with ‘Strain Gauges’
8.5.2 Assessment of the Stress
8.6 Measurements of Pressure and Flow Rate
8.6.1 Piezometers
8.7 Measures of Acoustic Emissions
8.8 Monitoring in Excavation by TBM
8.8.1 Measure of the Machine Parameters
8.8.2 Geophysical Seismic Surveys
8.8.3 Geoelectic Surveys of the Cutting Head (Shielded TBM)
8.9 Surface Settlements and Surrounding Infrastructures Monitoring
8.9.1 Settlement Gauges and Multibase Extensometers
8.9.2 Inclinometers
8.9.3 Other Instruments for Buildings and Facilities Monitoring
8.9.4 Settlements Monitoring
Index