Mine Seismology: Seismic Response to the Caving Process
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Mine Seismology: Seismic Response to the Caving Process
A Case Study from Four Mines
Glazer, S.N.
Springer International Publishing AG
08/2018
242
Dura
Inglês
9783319955728
15 a 20 dias
649
Descrição não disponível.
Chapter 1 IntroductionReferences
Chapter 2 Seismic data assessment 2.1 Introduction 2.2 Magnitude definition for the book 2.3 Summary of the seismic data bases 2.4 Test of seismic data base quality 2.4.1 Example based on DOZ seismic data base 2.4.2 Example based on DR Sector, El Teniente 2.5 Radiated seismic energy 2.5.1 Analysis of the Northparkes Mine seismic energy release pattern 2.5.2 Average energy release rates of small size events 2.5.3 Energy release ranges for different magnitude sizes - comparison between mines 2.5.3.1 Low magnitude range 2.5.3.2 Higher magnitude range 2.5.3.3 Energy release ranges for all magnitude sizes 2.6 Comparison of Seismicity Induces by Cave Mining at Palabora Mining (South Africa) and at PT Freeport Indonesia Copper Mines (Glazer and Townsend 2006) 2.6.1 Introduction 2.6.2 The PMC Mine 2.6 3. The Deep Ore Zone Mine of PT Freeport Indonesia 2.6.4 Seismic monitoring systems and their applications to cave operations 2.6.5. Comparison of seismicity 2.6.6 Comparisons of seismic activity rates above and below the mine footprints 2.6.7 ConclusionsAcknowledgements 2.6.8 Eleven years later 2.7 ConclusionsReferences
Chapter 3 Seismic signature of the caving process 3.1 Introduction 3.2 PT Freeport Indonesia DOZ Mine 3.2.1 Analysis of the whole DOZ seismic data base 3.2.2 Analysis of seismicity recorded inside of the DOZ footprint 3.2.3 Comparison of seismicity recorded above the DOZ footprint with seismicity recorded in the whole mine 3.3 Diablo Regimento Sector, El Teniente Mine 3.3.1 Analysis of the whole Diablo Regimento seismic data base 3.3.2 Comparison of seismicity recorded above the DR foot print with seismicity recorded in the whole mine 3.4 Northparkes Mine, Lift 2 Mine 3.4.1 Analysis of the whole seismic data base 3.4.2 Analysis of seismicity recorded inside of the cave 3.4.3 Estimation of the cave back position 3.4.4 Comparison of seismicity recorded above the mine foot print with seismicity recorded in the whole mine 3.5 Summary 3.5.1 Initiation of the caving process 3.5.2 Pillar failure 3.5.3 Time period after the pillar failure and before the break through 3.5.4 Break through 3.5.5 Seismicity trends after the break through 3.5.6 Mature stage of the caving process 3.6 ConclusionsReference
Chapter 4 Comparison of seismicity induced while mining hydro-fractured and non-preconditioned rock mass volumes
4.1 Introduction 4.2 Diablo Regimento Sector, seismicity induced in the cave and in the surrounding volumes 4.3 Palabora Mining Company, seismicity induced in the cave and in the surrounding volumes 4.4 Deep Ore Zone Mine, seismicity induced in the cave and in the surrounding volumes 4.5 Comparison between the mines 4.6 Summary of observations 4.7 ConclusionsReferences
Chapter 5 Summary and ConclusionsReferences
Index
Chapter 2 Seismic data assessment 2.1 Introduction 2.2 Magnitude definition for the book 2.3 Summary of the seismic data bases 2.4 Test of seismic data base quality 2.4.1 Example based on DOZ seismic data base 2.4.2 Example based on DR Sector, El Teniente 2.5 Radiated seismic energy 2.5.1 Analysis of the Northparkes Mine seismic energy release pattern 2.5.2 Average energy release rates of small size events 2.5.3 Energy release ranges for different magnitude sizes - comparison between mines 2.5.3.1 Low magnitude range 2.5.3.2 Higher magnitude range 2.5.3.3 Energy release ranges for all magnitude sizes 2.6 Comparison of Seismicity Induces by Cave Mining at Palabora Mining (South Africa) and at PT Freeport Indonesia Copper Mines (Glazer and Townsend 2006) 2.6.1 Introduction 2.6.2 The PMC Mine 2.6 3. The Deep Ore Zone Mine of PT Freeport Indonesia 2.6.4 Seismic monitoring systems and their applications to cave operations 2.6.5. Comparison of seismicity 2.6.6 Comparisons of seismic activity rates above and below the mine footprints 2.6.7 ConclusionsAcknowledgements 2.6.8 Eleven years later 2.7 ConclusionsReferences
Chapter 3 Seismic signature of the caving process 3.1 Introduction 3.2 PT Freeport Indonesia DOZ Mine 3.2.1 Analysis of the whole DOZ seismic data base 3.2.2 Analysis of seismicity recorded inside of the DOZ footprint 3.2.3 Comparison of seismicity recorded above the DOZ footprint with seismicity recorded in the whole mine 3.3 Diablo Regimento Sector, El Teniente Mine 3.3.1 Analysis of the whole Diablo Regimento seismic data base 3.3.2 Comparison of seismicity recorded above the DR foot print with seismicity recorded in the whole mine 3.4 Northparkes Mine, Lift 2 Mine 3.4.1 Analysis of the whole seismic data base 3.4.2 Analysis of seismicity recorded inside of the cave 3.4.3 Estimation of the cave back position 3.4.4 Comparison of seismicity recorded above the mine foot print with seismicity recorded in the whole mine 3.5 Summary 3.5.1 Initiation of the caving process 3.5.2 Pillar failure 3.5.3 Time period after the pillar failure and before the break through 3.5.4 Break through 3.5.5 Seismicity trends after the break through 3.5.6 Mature stage of the caving process 3.6 ConclusionsReference
Chapter 4 Comparison of seismicity induced while mining hydro-fractured and non-preconditioned rock mass volumes
4.1 Introduction 4.2 Diablo Regimento Sector, seismicity induced in the cave and in the surrounding volumes 4.3 Palabora Mining Company, seismicity induced in the cave and in the surrounding volumes 4.4 Deep Ore Zone Mine, seismicity induced in the cave and in the surrounding volumes 4.5 Comparison between the mines 4.6 Summary of observations 4.7 ConclusionsReferences
Chapter 5 Summary and ConclusionsReferences
Index
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
Mine seismology;Cave mining;Caving process;Hydrofracturing;Seismic data interpretation;Northparkes Lift 2 Mine;El Teniente Diablo Regimento Sector Mine;El Teniente Esmeralda Sector Mine;PT Freeport DOZ Mine
Chapter 1 IntroductionReferences
Chapter 2 Seismic data assessment 2.1 Introduction 2.2 Magnitude definition for the book 2.3 Summary of the seismic data bases 2.4 Test of seismic data base quality 2.4.1 Example based on DOZ seismic data base 2.4.2 Example based on DR Sector, El Teniente 2.5 Radiated seismic energy 2.5.1 Analysis of the Northparkes Mine seismic energy release pattern 2.5.2 Average energy release rates of small size events 2.5.3 Energy release ranges for different magnitude sizes - comparison between mines 2.5.3.1 Low magnitude range 2.5.3.2 Higher magnitude range 2.5.3.3 Energy release ranges for all magnitude sizes 2.6 Comparison of Seismicity Induces by Cave Mining at Palabora Mining (South Africa) and at PT Freeport Indonesia Copper Mines (Glazer and Townsend 2006) 2.6.1 Introduction 2.6.2 The PMC Mine 2.6 3. The Deep Ore Zone Mine of PT Freeport Indonesia 2.6.4 Seismic monitoring systems and their applications to cave operations 2.6.5. Comparison of seismicity 2.6.6 Comparisons of seismic activity rates above and below the mine footprints 2.6.7 ConclusionsAcknowledgements 2.6.8 Eleven years later 2.7 ConclusionsReferences
Chapter 3 Seismic signature of the caving process 3.1 Introduction 3.2 PT Freeport Indonesia DOZ Mine 3.2.1 Analysis of the whole DOZ seismic data base 3.2.2 Analysis of seismicity recorded inside of the DOZ footprint 3.2.3 Comparison of seismicity recorded above the DOZ footprint with seismicity recorded in the whole mine 3.3 Diablo Regimento Sector, El Teniente Mine 3.3.1 Analysis of the whole Diablo Regimento seismic data base 3.3.2 Comparison of seismicity recorded above the DR foot print with seismicity recorded in the whole mine 3.4 Northparkes Mine, Lift 2 Mine 3.4.1 Analysis of the whole seismic data base 3.4.2 Analysis of seismicity recorded inside of the cave 3.4.3 Estimation of the cave back position 3.4.4 Comparison of seismicity recorded above the mine foot print with seismicity recorded in the whole mine 3.5 Summary 3.5.1 Initiation of the caving process 3.5.2 Pillar failure 3.5.3 Time period after the pillar failure and before the break through 3.5.4 Break through 3.5.5 Seismicity trends after the break through 3.5.6 Mature stage of the caving process 3.6 ConclusionsReference
Chapter 4 Comparison of seismicity induced while mining hydro-fractured and non-preconditioned rock mass volumes
4.1 Introduction 4.2 Diablo Regimento Sector, seismicity induced in the cave and in the surrounding volumes 4.3 Palabora Mining Company, seismicity induced in the cave and in the surrounding volumes 4.4 Deep Ore Zone Mine, seismicity induced in the cave and in the surrounding volumes 4.5 Comparison between the mines 4.6 Summary of observations 4.7 ConclusionsReferences
Chapter 5 Summary and ConclusionsReferences
Index
Chapter 2 Seismic data assessment 2.1 Introduction 2.2 Magnitude definition for the book 2.3 Summary of the seismic data bases 2.4 Test of seismic data base quality 2.4.1 Example based on DOZ seismic data base 2.4.2 Example based on DR Sector, El Teniente 2.5 Radiated seismic energy 2.5.1 Analysis of the Northparkes Mine seismic energy release pattern 2.5.2 Average energy release rates of small size events 2.5.3 Energy release ranges for different magnitude sizes - comparison between mines 2.5.3.1 Low magnitude range 2.5.3.2 Higher magnitude range 2.5.3.3 Energy release ranges for all magnitude sizes 2.6 Comparison of Seismicity Induces by Cave Mining at Palabora Mining (South Africa) and at PT Freeport Indonesia Copper Mines (Glazer and Townsend 2006) 2.6.1 Introduction 2.6.2 The PMC Mine 2.6 3. The Deep Ore Zone Mine of PT Freeport Indonesia 2.6.4 Seismic monitoring systems and their applications to cave operations 2.6.5. Comparison of seismicity 2.6.6 Comparisons of seismic activity rates above and below the mine footprints 2.6.7 ConclusionsAcknowledgements 2.6.8 Eleven years later 2.7 ConclusionsReferences
Chapter 3 Seismic signature of the caving process 3.1 Introduction 3.2 PT Freeport Indonesia DOZ Mine 3.2.1 Analysis of the whole DOZ seismic data base 3.2.2 Analysis of seismicity recorded inside of the DOZ footprint 3.2.3 Comparison of seismicity recorded above the DOZ footprint with seismicity recorded in the whole mine 3.3 Diablo Regimento Sector, El Teniente Mine 3.3.1 Analysis of the whole Diablo Regimento seismic data base 3.3.2 Comparison of seismicity recorded above the DR foot print with seismicity recorded in the whole mine 3.4 Northparkes Mine, Lift 2 Mine 3.4.1 Analysis of the whole seismic data base 3.4.2 Analysis of seismicity recorded inside of the cave 3.4.3 Estimation of the cave back position 3.4.4 Comparison of seismicity recorded above the mine foot print with seismicity recorded in the whole mine 3.5 Summary 3.5.1 Initiation of the caving process 3.5.2 Pillar failure 3.5.3 Time period after the pillar failure and before the break through 3.5.4 Break through 3.5.5 Seismicity trends after the break through 3.5.6 Mature stage of the caving process 3.6 ConclusionsReference
Chapter 4 Comparison of seismicity induced while mining hydro-fractured and non-preconditioned rock mass volumes
4.1 Introduction 4.2 Diablo Regimento Sector, seismicity induced in the cave and in the surrounding volumes 4.3 Palabora Mining Company, seismicity induced in the cave and in the surrounding volumes 4.4 Deep Ore Zone Mine, seismicity induced in the cave and in the surrounding volumes 4.5 Comparison between the mines 4.6 Summary of observations 4.7 ConclusionsReferences
Chapter 5 Summary and ConclusionsReferences
Index
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