作者:周健主编
页数:254页
出版社:中南大学出版社
出版日期:2024
ISBN:9787548758235
电子书格式:PDF
PDF下载地址
内容简介
本书总结了国内近年来地下采矿新方法实践效果良好的方法,尤其是融入了中南大学及国内知名矿山近30年金属矿山成功开采理论、技术与经验。
目录
Chapter 1 Underground Mine Development and Mining Method
1.1 Underground mine development
1.2 Underground mining method
1.2.1 Open stope method
1.2.2 Backfilling method
1.2.3 Caving method
References
Chapter 2 Underground Mining Method Selection
2.1 Introduction
2.2 Essential criteria for mining method selection
2.3 Factors influencing the decision
2.3.1 Geology of the deposit
2.3.2 Economic considerations
2.3.3 Technological factors
2.3.4 Safety, health, environmental concerns
2.3.5 Political and social conditions
2.4 Underground mining method selection and evaluation methods
2.4.1 Qualitative methods
2.4.2 Numerical scoring methods
2.4.3 Decision-making models
2.5 Conclusions
References
Chapter 3 Empirical Methods in Mining Geomechanics
3.1 Introduction
3.2 Rock mass evaluation systems
3.2.1 Rock mass rating system (RMR)
3.2.2 Q-system
3.2.3 Rock mass index (RMi)
3.2.4 Geological strength index (GSI)
3.3 Open stope stability graph
3.3.1 Main ideas
3.3.2 Limitations
3.4 Excavatability classification systems
3.5 Blastability assessment systems
3.5.1 Blastability assessment factors
3.5.2 Blastability assessment indexes
3.6 Rockburst classification criteria
3.6.1 Single indicator criteria
3.6.2 Multi-index indicators criteria
3.6.3 Rockburst chart
3.7 Orepass design in hard rock mines
3.7.1 Orepass diameter
3.7.2 Orepass longevity
3.7.3 Orepass wall stability
3.8 Conclusions
References
Chapter 4 Design of Hard Rock Pillar in Underground Space
4. 1 Introduction
4.2 Design methods
4.2.1 Empirical method
4.2.2 Numerical simulation method
4.2.3 Statistical assessment method
4.2.4 Artificial intelligence method
4.3 Hard rock pillar design by examples
4.3.1 Example 1
4.3.2 Example 2
4.3.3 Example 3
4.3.4 Example 4
4.3.5 Example 5
4.3.6 Example 6
4.3.7 Example 7
4.3.8 Example 8
4.4 Conclusions
References
Chapter 5 Criteria for Underground Mine Damage
5.1 Introduction
5.1.1 Damage-failure in underground excavations
5.1.2 Overview of the main types of damage criteria
5.2 Failure criteria for underground mines in numerical analysis
5.2.1 Stress-based failure criteria
5.2.2 Strain-based failure criteria
5.3 Vibration energy as damage criteria
5.4 Peak Particle Velocity (PPV) criteria and damage assessment
5.4.1 Peak Particle Velocity (PPV) criteria
5.4.2 Peak particle velocity and frequency as damage criteria
References
Chapter 6 Drilling and Blasting in Hard Rock
6.1 Introduction
6.2 Rock drills classification
6.2.1 Mounting type
6.2.2 Motive power of rock drills
6.2.3 Mechanics of rock penetration efficiency
6.3 Blasting design
6.3.1 Blasting design process
6.3.2 Methodology
6.4 Blast damage criteria
6.5 Suggested damage threshold levels for rock damage
6.6 Underground mine blasting design
6.6.1 Tunnel blasting
6.6.2 Shaft sinking
6.6.3 Production ring blasts
6.6.4 Underground mining large-diameter long hole blasting
References
Chapter 7 Rockburst Prediction and Prevention in Underground Excavation
7.1 Introduction
7.2 Rockburst statistical analysis
7.2.1 Disaster statistics analysis
7.2.2 Rockburst characteristics analysis
7.3 Rockburst prediction
7.3.1 Empirical criteria method
7.3.2 Simulation technology
7.3.3 Mathematical modeling method
7.3.4 Microseismic monitoring technology
7.3.5 Comments for different forecasting methods
7.4 Rockburst prevention
7.4.1 Rockburst support design principles and control strategies
7.4.2 Rockburst support methods
7.5 Conclusions
References
Chapter 8 Backfill Technology and
1.1 Underground mine development
1.2 Underground mining method
1.2.1 Open stope method
1.2.2 Backfilling method
1.2.3 Caving method
References
Chapter 2 Underground Mining Method Selection
2.1 Introduction
2.2 Essential criteria for mining method selection
2.3 Factors influencing the decision
2.3.1 Geology of the deposit
2.3.2 Economic considerations
2.3.3 Technological factors
2.3.4 Safety, health, environmental concerns
2.3.5 Political and social conditions
2.4 Underground mining method selection and evaluation methods
2.4.1 Qualitative methods
2.4.2 Numerical scoring methods
2.4.3 Decision-making models
2.5 Conclusions
References
Chapter 3 Empirical Methods in Mining Geomechanics
3.1 Introduction
3.2 Rock mass evaluation systems
3.2.1 Rock mass rating system (RMR)
3.2.2 Q-system
3.2.3 Rock mass index (RMi)
3.2.4 Geological strength index (GSI)
3.3 Open stope stability graph
3.3.1 Main ideas
3.3.2 Limitations
3.4 Excavatability classification systems
3.5 Blastability assessment systems
3.5.1 Blastability assessment factors
3.5.2 Blastability assessment indexes
3.6 Rockburst classification criteria
3.6.1 Single indicator criteria
3.6.2 Multi-index indicators criteria
3.6.3 Rockburst chart
3.7 Orepass design in hard rock mines
3.7.1 Orepass diameter
3.7.2 Orepass longevity
3.7.3 Orepass wall stability
3.8 Conclusions
References
Chapter 4 Design of Hard Rock Pillar in Underground Space
4. 1 Introduction
4.2 Design methods
4.2.1 Empirical method
4.2.2 Numerical simulation method
4.2.3 Statistical assessment method
4.2.4 Artificial intelligence method
4.3 Hard rock pillar design by examples
4.3.1 Example 1
4.3.2 Example 2
4.3.3 Example 3
4.3.4 Example 4
4.3.5 Example 5
4.3.6 Example 6
4.3.7 Example 7
4.3.8 Example 8
4.4 Conclusions
References
Chapter 5 Criteria for Underground Mine Damage
5.1 Introduction
5.1.1 Damage-failure in underground excavations
5.1.2 Overview of the main types of damage criteria
5.2 Failure criteria for underground mines in numerical analysis
5.2.1 Stress-based failure criteria
5.2.2 Strain-based failure criteria
5.3 Vibration energy as damage criteria
5.4 Peak Particle Velocity (PPV) criteria and damage assessment
5.4.1 Peak Particle Velocity (PPV) criteria
5.4.2 Peak particle velocity and frequency as damage criteria
References
Chapter 6 Drilling and Blasting in Hard Rock
6.1 Introduction
6.2 Rock drills classification
6.2.1 Mounting type
6.2.2 Motive power of rock drills
6.2.3 Mechanics of rock penetration efficiency
6.3 Blasting design
6.3.1 Blasting design process
6.3.2 Methodology
6.4 Blast damage criteria
6.5 Suggested damage threshold levels for rock damage
6.6 Underground mine blasting design
6.6.1 Tunnel blasting
6.6.2 Shaft sinking
6.6.3 Production ring blasts
6.6.4 Underground mining large-diameter long hole blasting
References
Chapter 7 Rockburst Prediction and Prevention in Underground Excavation
7.1 Introduction
7.2 Rockburst statistical analysis
7.2.1 Disaster statistics analysis
7.2.2 Rockburst characteristics analysis
7.3 Rockburst prediction
7.3.1 Empirical criteria method
7.3.2 Simulation technology
7.3.3 Mathematical modeling method
7.3.4 Microseismic monitoring technology
7.3.5 Comments for different forecasting methods
7.4 Rockburst prevention
7.4.1 Rockburst support design principles and control strategies
7.4.2 Rockburst support methods
7.5 Conclusions
References
Chapter 8 Backfill Technology and