Table of Contents

Open Pit Mine Plannign & Design, 2nd Edition

VOLUME 1

PREFACE

ACKNOWLEDGEMENTS

1 MINE PLANNING

• 1.1 Introduction
• 1.1.1 The meaning of ore
• 1.1.2 Some important definitions
• 1.2 Mine development phases
• 1.3 An initial data collection checklist
• 1.4 The planning phase
• 1.4.1 Introduction
• 1.4.2 The content of an intermediate valuation report
• 1.4.3 The content of the feasibility report
• 1.5 Planning costs
• 1.6 Accuracy of estimates
• 1.6.1 Tonnage and grade
• 1.6.2 Performance
• 1.6.3 Costs
• 1.6.4 Price and revenue
• 1.7 Feasibility study preparation
• 1.8 Critical path representation
• 1.9 Mine reclamation
• 1.9.1 Introduction
• 1.9.2 Multiple-use management
• 1.9.3 Reclamation plan purpose
• 1.9.4 Reclamation plan content
• 1.9.5 Reclamation standards
• 1.9.6 Surface and ground water management
• 1.9.7 Mine waste management
• 1.9.8 Tailings and slime ponds
• 1.9.9 Cyanide heap and vat leach systems
• 1.9.10 Landform reclamation
• 1.10 Environmental planning procedures
• 1.10.1 Initial project evaluation
• 1.10.2 The strategic plan
• 1.10.3 The environmental planning team
• 1.11 A sample list of project permits and approvals
• References

2 MINING REVENUES AND COSTS

• 2.1 Introduction
• 2.2 Economic concepts including cash flow
• 2.2.1 Future worth
• 2.2.2 Present value
• 2.2.3 Present value of a series of uniform contributions
• 2.2.4 Payback period
• 2.2.5 Rate of return on an investment
• 2.2.6 Cash flow (CF)
• 2.2.7 Discounted cash flow (DCF)
• 2.2.8 Discounted cash flow rate of return (DCFROR)
• 2.2.9 Cash flows, DCF and DCFROR including depreciation
• 2.2.10 Depletion
• 2.2.11 Cash flows, including depletion
• 2.3 Estimating revenues
• 2.3.1 Current mineral prices
• 2.3.2 Historical price data
• 2.3.3 Trend analysis
• 2.3.4 Econometric models
• 2.3.5 Net smelter return
• 2.3.6 Price-cost relationships
• 2.4 Estimating costs
• 2.4.1 Types of costs
• 2.4.2 Costs from actual operations
• 2.4.3 Escalation of older costs
• 2.4.4 The original O’Hara cost estimator
• 2.4.5 The updated O’Hara cost estimator
• 2.4.6 Detailed cost calculations
• 2.4.7 Quick-and-dirty mining cost estimates
• 2.4.8 Current equipment, supplies and labor costs
• References

3 OREBODY DESCRIPTION

• 3.1 Introduction
• 3.2 Mine maps
• 3.3 Geologic information
• 3.4 Compositing and tonnage factor calculations
• 3.4.1 Compositing
• 3.4.2 Tonnage factors
• 3.5 Method of vertical sections
• 3.5.1 Introduction
• 3.5.2 Procedures
• 3.5.3 Construction of a cross-section
• 3.5.4 Calculation of tonnage and average grade for a pit
• 3.6 Method of vertical sections (grade contours)
• 3.7 The method of horizontal sections
• 3.7.1 Introduction
• 3.7.2 Triangles
• 3.7.3 Polygons
• 3.8 Block models
• 3.8.1 Introduction
• 3.8.2 Rule-of-nearest points
• 3.8.3 Constant distance weighting techniques
• 3.9 Statistical basis for grade assignment
• 3.9.1 Some statistics on the orebody
• 3.9.2 Range of sample influence
• 3.9.3 Illustrative example
• 3.9.4 Describing variograms by mathematical models
• 3.9.5 Quantification of a deposit through variograms
• 3.10 Kriging
• 3.10.1 Introduction
• 3.10.2 Concept development
• 3.10.3 Kriging example
• 3.10.4 Example of estimation for a level
• 3.10.5 Block kriging
• 3.10.6 Common problems associated with the use of the kriging technique
• 3.10.7 Comparison of results using several techniques
• References

4 GEOMETRICAL CONSIDERATIONS

• 4.1 Introduction
• 4.2 Basic bench geometry
• 4.3 Ore access
• 4.4 The pit expansion process
• 4.4.1 Introduction
• 4.4.2 Frontal cuts
• 4.4.3 Drive-by cuts
• 4.4.4 Parallel cuts
• 4.4.5 Minimum required operating room for parallel cuts
• 4.4.6 Cut sequencing
• 4.5 Pit slope geometry
• 4.6 Final pit slope angles
• 4.6.1 Introduction
• 4.6.2 Geomechanical background
• 4.6.3 Planar failure
• 4.6.4 Circular failure
• 4.6.5 Stability of curved wall sections
• 4.6.6 Slope stability data presentation
• 4.6.7 Slope analysis example
• 4.6.8 Economic aspects of final slope angles
• 4.7 Plan representation of bench geometry
• 4.8 Addition of a road
• 4.8.1 Introduction
• 4.8.2 Design of a spiral road – inside the wall
• 4.8.3 Design of a spiral ramp – outside the wall
• 4.8.4 Design of a switchback
• 4.8.5 The volume represented by a road
• 4.9 Road construction
• 4.9.1 Introduction
• 4.9.2 Road section design
• 4.9.3 Straight segment design
• 4.9.4 Curve design
• 4.9.5 Conventional parallel berm design
• 4.9.6 Median berm design
• 4.9.7 Haulage road gradients
• 4.9.8 Practical road building and maintenance tips
• 4.10 Stripping ratios
• 4.11 Geometric sequencing
• 4.12 Summary
• References

5 PIT LIMITS

• 5.1 Introduction
• 5.2 Hand methods
• 5.2.1 The basic concept
• 5.2.2 The net value calculation
• 5.2.3 Location of pit limits – pit bottom in waste
• 5.2.4 Location of pit limits – pit bottom in ore
• 5.2.5 Location of pit limits – one side plus pit bottom in ore
• 5.2.6 Radial sections
• 5.2.7 Generating a final pit outline
• 5.2.8 Destinations for in-pit materials
• 5.3 Economic block models
• 5.4 The floating cone technique
• 5.5 The Lerchs-Grossmann 2-D algorithm
• 5.6 Modification of the Lerchs-Grossmann 2-D algorithm to a 2½-D algorithm
• 5.7 The Lerchs-Grossmann 3-D algorithm
• 5.7.1 Introduction
• 5.7.2 Definition of some important terms and concepts
• 5.7.3 Two approaches to tree construction
• 5.7.4 The arbitrary tree approach (Approach 1)
• 5.7.5 The all root connection approach (Approach 2)
• 5.7.6 The tree ‘cutting’ process
• 5.7.7 A more complicated example
• 5.8 Computer assisted methods
• 5.8.1 The RTZ open-pit generator
• 5.8.2 Computer assisted pit design based upon sections
• References

6 PRODUCTION PLANNING

• 6.1 Introduction
• 6.2 Some basic mine life – plant size concepts
• 6.3 Taylor’s mine life rule
• 6.4 Sequencing by nested pits
• 6.5 Cash flow calculations
• 6.6 Mine and mill plant sizing
• 6.6.1 Ore reserves supporting the plant size decision
• 6.6.2 Incremental financial analysis principles
• 6.6.3 Plant sizing example
• 6.7 Lanes algorithm
• 6.7.1 Introduction
• 6.7.2 Model definition
• 6.7.3 The basic equations
• 6.7.4 An illustrative example
• 6.7.5 Cutoff grade for maximum profit
• 6.7.6 Net present value maximization
• 6.8 Material destination considerations
• 6.8.1 Introduction
• 6.8.2 The leach dump alternative
• 6.8.3 The stockpile alternative
• 6.9 Production scheduling
• 6.9.1 Introduction
• 6.9.2 Phase scheduling
• 6.9.3 Block sequencing using set dynamic programming
• 6.9.4 Some scheduling examples
• 6.10 Push back design
• 6.10.1 Introduction
• 6.10.2 The basic manual steps
• 6.10.3 Manual push back design example
• 6.10.4 Time period plans
• 6.10.5 Equipment fleet requirements
• 6.10.6 Other planning considerations
• 6.11 The mine planning and design process – summary and closing remarks
• References

7 REPORTING OF MINERAL RESOURCES AND ORE RESERVES

• 7.1 Introduction
• 7.2 The jorc code – 4 edition
• 7.2.1 Preamble
• 7.2.2 Foreword
• 7.2.3 Introduction
• 7.2.4 Scope
• 7.2.5 Competence and responsibility
• 7.2.6 Reporting terminology
• 7.2.7 Reporting – General
• 7.2.8 Reporting of Exploration Results
• 7.2.9 Reporting of Mineral Resources
• 7.2.10 Reporting of Ore Reserves
• 7.2.11 Reporting of mineralized stope fill, stockpiles, remnants, pillars, low grade mineralization and tailings
• 7.3 The cim best practice guidelines for the estimation of mineral resources and mineral reserves – general guidelines
• 7.3.1 Preamble
• 7.3.2 Foreword
• 7.3.3 The Resource Database
• 7.3.4 Geological interpretation and modeling
• 7.3.5 Mineral Resource estimation
• 7.3.6 Quantifying elements to convert a Mineral Resource to a Mineral Reserve
• 7.3.7 Mineral Reserve estimation
• 7.3.8 Reporting
• 7.3.9 Reconciliation of Mineral Reserves
• Selected References
• References

8 RESPONSIBLE MINING

• 8.1 Introduction
• 8.2 The 2 united nations conference on the human environment
• 8.3 TheWorld Conservation Strategy (WCS) – 0
• 8.4 World Commission on Environment and Development (7)
• 8.5 The ‘Earth Summit’
• 8.5.1 The Rio Declaration
• 8.5.2 Agenda 21
• 8.6 World Summit on Sustainable Development (WSSD)
• 8.7 Mining industry and mining industry-related initiatives
• 8.7.1 Introduction
• 8.7.2 The Global Mining Initiative (GMI)
• 8.7.3 International Council on Mining and Metals (ICMM)
• 8.7.4 Mining, Minerals, and Sustainable Development (MMSD)
• 8.7.5 The U.S. Government and Federal Land Management
• 8.7.6 The Position of the U.S. National Mining Association (NMA)
• 8.7.7 The View of One Mining Company Executive
• 8.8 ‘Responsible Mining’ – the way forward is good engineering
• 8.8.1 Introduction
• 8.8.2 The Milos Statement
• 8.9 Concluding remarks
• References

Index

VOLUME 2

PREFACE

9 THE CSMine TUTORIAL

• 9.1 Getting started
• 9.1.1 Hardware requirements
• 9.1.2 Installing CSMine
• 9.1.3 Running CSMine
• 9.2 The arizcu property description
• 9.3 Steps needed to create a block model
• 9.4 Data files required for creating a block model
• 9.5 CSMine program design overview
• 9.6 Executing commands with CSMine
• 9.7 Starting the tutorial
• 9.8 The drill hole mode
• 9.8.1 Reading the drill hole file
• 9.8.2 Defining the block grid
• 9.8.3 Creating a drill hole plan map
• 9.8.4 Creating a drill hole section map
• 9.9 The composite mode
• 9.9.1 Calculating composites
• 9.9.2 Storing and loading composite files
• 9.9.3 Drill hole section plots with composites
• 9.10 The block mode
• 9.10.1 Calculating block grades
• 9.10.2 Creating block value plots
• 9.10.3 Creating contour maps
• 9.10.4 Assigning economic values to the blocks
• 9.10.5 The Restrictions command
• 9.10.6 Pit plots
• 9.10.7 The Slopes command
• 9.10.8 The Save and Print commands
• 9.11 Conclusion
• 9.12 Suggested exercises

10 CSMine USER’S GUIDE

• 10.1 Basics
• 10.1.1 File types
• 10.1.2 The project file
• 10.1.3 Changing modes
• 10.1.4 Formatting the data screen
• 10.1.5 Sorting data
• 10.1.6 Printing data
• 10.1.7 Coordinate system description
• 10.2 Drill hole mode
• 10.2.1 Drill hole data file description
• 10.2.2 Reading a drill hole file
• 10.2.3 Plotting a drill hole plan map
• 10.2.4 Plotting a drill hole section map
• 10.3 Composite mode
• 10.3.1 How composites are calculated
• 10.3.2 Creating composites
• 10.3.3 Saving composite files
• 10.3.4 Reading composite files
• 10.3.5 Composite file description
• 10.4 Block model mode
• 10.4.1 Defining the block model grid
• 10.4.2 Surface topography
• 10.4.3 Assigning block values
• 10.4.4 Creating a block model
• 10.4.5 Saving a block file
• 10.4.6 Reading a block file
• 10.4.7 Block file description
• 10.5 Economic block values
• 10.5.1 How economic values are calculated
• 10.5.2 Evaluation of the default formulas
• 10.5.3 Creating an economic block model
• 10.6 Pit modeling
• 10.6.1 Surface topography restrictions
• 10.6.2 Geometric pit limit restriction and pit slopes
• 10.6.3 Positive apexed cone limits
• 10.6.4 Three-dimensional floating cone
• 10.6.5 Entering pit slopes
• 10.6.6 Turning pit restrictions on and off
• 10.7 Block plots
• 10.7.1 The Configure command
• 10.7.2 The Next command
• 10.7.3 The Previous command
• 10.7.4 The Return command
• 10.7.5 Controlling which blocks are plotted
• 10.8 Contour plots
• 10.8.1 The Configure command
• 10.8.2 The Next command
• 10.8.3 The Previous command
• 10.8.4 The Return command
• 10.9 Plotting pit profiles
• 10.9.1 The Configure command
• 10.9.2 The Surface command
• 10.9.3 The Geometric command
• 10.9.4 The Outer_Economic command
• 10.9.5 The Floating_Cone command
• 10.9.6 The Return command
• 10.10 Block reports
• 10.10.1 The Restrictions command
• 10.10.2 The Configure command
• 10.10.3 The Return command
• 10.11 Summary statistics
• 10.11.1 The EX1.CMP data set
• 10.11.2 The EX2.CMP data set
• 10.11.3 Summary statistics description
• 10.11.4 Is a distribution normal?
• 10.11.5 Is a distribution lognormal?
• 10.11.6 The Transform command
• 10.11.7 The Statistics command
• 10.12 Variogram modeling
• 10.12.1 Introduction
• 10.12.2 Experimental variogram modeling
• 10.12.3 Anisotropy
• 10.12.4 The Variogram command
• References

11 OREBODY CASE EXAMPLES

• 11.1 Introduction
• 11.2 CSMine arizona copper property
• 11.2.1 Introduction
• 11.2.2 Historical background
• 11.2.3 Property topography
• 11.2.4 Geologic description
• 11.2.5 Mineralization
• 11.2.6 Drill hole data
• 11.2.7 Mining considerations
• 11.3 The minnesota natural iron property
• 11.3.1 Introduction
• 11.3.2 Access
• 11.3.3 Climatic conditions
• 11.3.4 Historical background
• 11.3.5 Topography
• 11.3.6 General geologic setting
• 11.3.7 Mine-specific geology
• 11.3.8 An initial hand design
• 11.3.9 Economic basis
• 11.4 The utah iron property
• 11.4.1 Background
• 11.4.2 Mining history of the district
• 11.4.3 Property topography and surface vegetation
• 11.4.4 Climate
• 11.4.5 General geology
• 11.4.6 Mineralization
• 11.4.7 Mineral Processing
• 11.4.8 Pit slopes
• 11.4.9 Initial cost estimates
• 11.4.10 Other considerations
• 11.5 The minnesota taconite property
• 11.5.1 Introduction
• 11.5.2 Location
• 11.5.3 History
• 11.5.4 Topography and surface conditions
• 11.5.5 General geology
• 11.5.6 Structural data
• 11.5.7 Mining data
• 11.5.8 Ore processing
• 11.6 The kennecott barneys canyon gold property
• 11.6.1 Introduction
• 11.6.2 Geologic setting
• 11.6.3 Resource definition
• 11.6.4 Geotechnical data
• 11.6.5 Topography and surface conditions
• 11.6.6 Climate
• 11.6.7 Ore processing
• 11.6.8 Mining data
• 11.7 The newmont gold property
• 11.7.1 Introduction
• 11.7.2 Property location
• 11.7.3 General geologic setting
• 11.7.4 Deposit mineralization
• 11.7.5 Topography and surface conditions
• 11.7.6 Local climatic conditions
• 11.7.7 Initial pit modeling parameters
• 11.8 The codelco andina copper property
• 11.8.1 Introduction
• 11.8.2 Background Information
• 11.8.3 Geology
• 11.8.4 Structural geology
• 11.8.5 Geotechnical slope analysis and design
• 11.8.6 Unit operations and initial costs for generating a pit
• 11.9 The codelco norte copper property
• 11.9.1 Introduction
• 11.9.2 Location and access
• 11.9.3 Geology
• 11.9.4 Geotechnical information
• 11.9.5 Open pit geometry
• 11.9.6 Material handling systems
• 11.9.7 Metallurgical testing/process development
• 11.9.8 Leach pad design and operation
• 11.9.9 Mine design and plan
• 11.9.10 Unit operations and manpower
• 11.9.11 Economic analysis
• References

Index