Description

Book Synopsis
Earthquakes are a way of life on Earth, and, whether you live in an area that is often affected by earthquakes or not, every building, every road, every bridge, and, in fact, almost everything constructed by humans in which we walk, sleep, live, sit, or visit, has to be constructed to withstand an earthquake, by following local, regional, or national codes, laws, and regulations. Further to this, the science and engineering behind these constructions go further than what is mandated by government as a part of their practice. All construction, and, in general, all life on Earth, has some risk of seismic impacts. A comprehensive description of any seismic action may be given only on a probabilistic basis and, in general, is very bulky and quite uncertain. However, for a variety of structures or systems that meet fairly simple models of behavior during earthquakes, a general description of the seismic action is not required, for prediction of the status of such facilities or systems ma

Table of Contents

Contents

Preface vii

1 Statement of the Problem 1

1.1 General Scheme of Estimation of Seismic Stability 3

1.2 Seismic Hazard 11

1.3 Variation of Seismic Hazard 15

1.4 Seismic Loads 20

2 The Definition of Seismic Actions 29

2.1 The Probability of Loads During the Earthquake of a Given Intensity 32

2.2 Recognition of Earthquake Foci 53

2.3 The Calculation of Seism Caused by Movement in the Earthquake Focus 61

2.4 Physics of Focus and Control of Seismicity 82

2.5 Seismic Forces for a Fixed Position and Energy of the Earthquake Source 99

3 The Influence of Topography and Soil Conditions

Secondary Processes 113

3.1 Influence of the Canyons 113

3.2 Dynamics of Water-Saturated Soil Equivalent Single-Phase Environment 117

3.3 Dynamics of Water-Saturated Soil as Multiphase Medium 121

3.4 The Real Estimates of the Property of Soils 145

3.4.1 Mathematical Formulation of the Problem 147

3.4.2 Examples of Calculations 152

3.5 Landslides and Mudflows 158

3.6 Waves on the Water 162

4 Example of Determination of Seismic Loads on the Object in an Area of High Seismicity 167

4.1 Assessment of Seismotectonics and Choice of Calculation of Seismicity 167

4.2 The Parameters of Impacts 171

4.3 Selection of Unique 179

4.4 Numerical Models of the Focus 183

4.5 The Influence of the Shape of the Canyon 189

5 Examples of Determination of Seismic Effects on Objects in Areas of Low Seismicity 195

5.1 Preliminary Analysis 195

5.2 Assessment of Seismic Risk on Seismological Data 201

5.3 Tectonic Structure of the Area 205

5.4 Recognition of Seismically Active Nodes’ Morphostructure 212

5.5 The Types of Computational Seismic Effects 225

5.6 Analog Modeling of Seismic Effects 233

5.7 Mathematical Modeling of Seismic Effects 237

6 Stability of Structures During Earthquakes 247

6.1 Stability of Concrete Dams 248

6.2 Vibration and Strength Reserves of the High Dams 278

6.2.1 Stability and Final Displacements of the Dam 282

6.2.2 Stress and Strain of the Dam 287

6.2.3 Character and Form of Dam Failure 292

6.3 The Reliability of Groundwater Dams 296

6.4 The Stability of Underground Structures 333

6.5 Seismic Effects Caused by Missing Floods Through the Waterworks 340

6.5.1 The Vibration of the Dam 345

6.5.2 Soil Vibration Outside of the Dam 352

6.5.3 Vibration Houses 356

6.5.4 Results and Recomendation 360

Conclusion 362

References 365

Index 375

Seismic Loads

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      Publisher: John Wiley & Sons Inc
      Publication Date: Publication Date: 09/02/2016
      ISBN13: 9781118946244, 978-1118946244
      ISBN10: 1118946243
      Also in:
      The environment

      Description

      Book Synopsis
      Earthquakes are a way of life on Earth, and, whether you live in an area that is often affected by earthquakes or not, every building, every road, every bridge, and, in fact, almost everything constructed by humans in which we walk, sleep, live, sit, or visit, has to be constructed to withstand an earthquake, by following local, regional, or national codes, laws, and regulations. Further to this, the science and engineering behind these constructions go further than what is mandated by government as a part of their practice. All construction, and, in general, all life on Earth, has some risk of seismic impacts. A comprehensive description of any seismic action may be given only on a probabilistic basis and, in general, is very bulky and quite uncertain. However, for a variety of structures or systems that meet fairly simple models of behavior during earthquakes, a general description of the seismic action is not required, for prediction of the status of such facilities or systems ma

      Table of Contents

      Contents

      Preface vii

      1 Statement of the Problem 1

      1.1 General Scheme of Estimation of Seismic Stability 3

      1.2 Seismic Hazard 11

      1.3 Variation of Seismic Hazard 15

      1.4 Seismic Loads 20

      2 The Definition of Seismic Actions 29

      2.1 The Probability of Loads During the Earthquake of a Given Intensity 32

      2.2 Recognition of Earthquake Foci 53

      2.3 The Calculation of Seism Caused by Movement in the Earthquake Focus 61

      2.4 Physics of Focus and Control of Seismicity 82

      2.5 Seismic Forces for a Fixed Position and Energy of the Earthquake Source 99

      3 The Influence of Topography and Soil Conditions

      Secondary Processes 113

      3.1 Influence of the Canyons 113

      3.2 Dynamics of Water-Saturated Soil Equivalent Single-Phase Environment 117

      3.3 Dynamics of Water-Saturated Soil as Multiphase Medium 121

      3.4 The Real Estimates of the Property of Soils 145

      3.4.1 Mathematical Formulation of the Problem 147

      3.4.2 Examples of Calculations 152

      3.5 Landslides and Mudflows 158

      3.6 Waves on the Water 162

      4 Example of Determination of Seismic Loads on the Object in an Area of High Seismicity 167

      4.1 Assessment of Seismotectonics and Choice of Calculation of Seismicity 167

      4.2 The Parameters of Impacts 171

      4.3 Selection of Unique 179

      4.4 Numerical Models of the Focus 183

      4.5 The Influence of the Shape of the Canyon 189

      5 Examples of Determination of Seismic Effects on Objects in Areas of Low Seismicity 195

      5.1 Preliminary Analysis 195

      5.2 Assessment of Seismic Risk on Seismological Data 201

      5.3 Tectonic Structure of the Area 205

      5.4 Recognition of Seismically Active Nodes’ Morphostructure 212

      5.5 The Types of Computational Seismic Effects 225

      5.6 Analog Modeling of Seismic Effects 233

      5.7 Mathematical Modeling of Seismic Effects 237

      6 Stability of Structures During Earthquakes 247

      6.1 Stability of Concrete Dams 248

      6.2 Vibration and Strength Reserves of the High Dams 278

      6.2.1 Stability and Final Displacements of the Dam 282

      6.2.2 Stress and Strain of the Dam 287

      6.2.3 Character and Form of Dam Failure 292

      6.3 The Reliability of Groundwater Dams 296

      6.4 The Stability of Underground Structures 333

      6.5 Seismic Effects Caused by Missing Floods Through the Waterworks 340

      6.5.1 The Vibration of the Dam 345

      6.5.2 Soil Vibration Outside of the Dam 352

      6.5.3 Vibration Houses 356

      6.5.4 Results and Recomendation 360

      Conclusion 362

      References 365

      Index 375

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