Construction Dewatering and Groundwater Control: New Methods and Applications

The most up-to-date guide to construction dewatering and groundwater control

In the past dozen years, the methods of analyzing and treating groundwater conditions have vastly improved. The Third Edition of Construction Dewatering and Groundwater Control, reflecting the most current technology and practices, is a timely and much-needed overview of this rapidly changing field.

Illustrated with hundreds of new figures and photographs and including numerous detailed case histories, the Third Edition of Construction Dewatering and Groundwater Control is a comprehensive and valuable reference for both students and practicing engineers alike.

Drawing on real-world experience, the authors lead the reader through all facets of the theory and practice of this fascinating and often complex engineering discipline. Discussion includes:

• Dozens of case histories demonstrating various groundwater control practices and lessons learned in groundwater control and work performed
• Detailed methods of controlling groundwater by use of conventional dewatering methods as well as vertical barrier, grouted cutoff, and frozen ground techniques
• Contracting practices and conflict resolution methods that will help minimize disputes
• Alternatives and effective practices for handling and treating contaminated groundwater
• Innovations in equipment and materials that improve the performance and efficiency of groundwater control systems
• Practices and procedures for success in artificial recharge
• Groundwater modeling to simulate and plan dewatering projects
• Inclusion of dual U.S. customary and metric units throughout

Construction Dewatering and Groundwater Control is an indispensable tool for all engineering and construction professionals searching for the most up-to-date coverage of groundwater control for various purposes, the modern ways to identify and analyze site-specific situations, and the modern tools available to control them.

Preface to the Third Edition xiii

About the Authors xv

Acknowledgements xvii

Part One: Theory 1

1 Groundwater in Construction 3

1.1 Groundwater in the Hydrologic Cycle 3

1.2 Origins of Dewatering 6

1.3 Development of Modern Dewatering Technology 6

2 The Geology of Soils 10

2.1 Geologic Time Frame 11

2.2 Formation of Soils 11

2.3 Mineral Composition of Soils 11

2.4 Rivers 12

2.5 Lakes 12

2.6 Estuaries 14

2.7 Beaches 14

2.8 Wind Deposits 14

2.9 Glaciers—The Pleistocene Epoch 14

2.10 Rock 16

2.11 Limestone and Coral 17

2.12 Tectonic Movements 19

2.13 Man-made Ground 19

3 Soils and Water 22

3.1 Soil Structure 22

3.2 Gradation of Soils 22

3.3 Porosity, Void Ratio, and Water Content 26

3.4 Relative Density, Specific Gravity, and Unit Weight 26

3.5 Capillarity and Unsaturated Flow 27

3.6 Specific Yield and Specific Retention 27

3.7 Hydraulic Conductivity 29

3.8 Plasticity and Cohesion of Silts and Clays 35

3.9 Unified Soil Classification System (ASTM D-2487) 35

3.10 Soil Descriptions 39

3.11 Visual and Manual Classification of Soils 40

3.12 Seepage Forces and Soil Stress 42

3.13 Gravity Drainage of Granular Soils 43

3.14 Drainage of Fine-grained Soils: Pore Pressure Control 44

3.15 Settlement as a Result of Dewatering 46

3.16 Preconsolidation 48

3.17 Other Side Effects of Dewatering 50

4 Hydrology of the Ideal Aquifer 52

4.1 Definition of the Ideal Aquifer 52

4.2 Transmissivity T 53

4.3 Storage Coefficient C s and Specific Yield 53

4.4 Pumping from a Confined Aquifer 55

4.5 Recovery Calculations 56

4.6 The Unconfined or Water Table Aquifer 57

4.7 Specific Capacity 58

5 Characteristics of Natural Aquifers 61

5.1 Anisotropy: Stratified Soils 61

5.2 Horizontal Variability 64

5.3 Recharge Boundaries: Radius of Influence R 0 64

5.4 Barrier Boundaries 65

5.5 Delayed Release from Storage 65

6 Dewatering Design Using Analytical Methods 66

6.1 Radial Flow to a Well in a Confined Aquifer 66

6.2 Radial Flow to a Well in a Water Table Aquifer 68

6.3 Radial Flow to a Well in a Mixed Aquifer 69

6.4 Flow to a Drainage Trench from a Line Source 69

6.5 The System as a Well: Equivalent Radius r s 70

6.6 Radius of Influence R 0 71

6.7 Hydraulic Conductivity K and Transmissivity T 71

6.8 Initial Head H and Final Head h 72

6.9 Partial Penetration 72

6.10 Storage Depletion 73

6.11 Specific Capacity of the Aquifer 75

6.12 Cumulative Drawdown or Superposition 76

6.13 Capacity of the Well Q w 77

6.14 Flow Net Analysis and the Method of Fragments 79

6.15 Concentric Dewatering Systems 80

6.16 Vertical Flow 81

6.17 Gravel Tremie 82

7 Groundwater Modeling Using Numerical Methods 84

7.1 Models in Dewatering Practice 84

7.2 When to Consider a Numerical Model 87

7.3 Principal Steps in Model Design and Application 90

7.4 The Conceptual Model: Defining the Problem to Be Modeled 90

7.5 Selecting the Program 91

7.6 Introduction to MODFLOW 91

7.7 Verification 94

7.8 Calibration 94

7.9 Prediction and Parametric Analyses 95

7.10 Some Practical Modeling Problems 95

7.11 2-D Model: Well System in a Water Table Aquifer 95

7.12 Calibrating the Model 97

7.13 3-D Model: Partial Penetration 98

7.14 3-D Model: Vertical Flow 101

7.15 3-D Model: Transient Analysis of a Progressive Trench Excavation 102

8 Piezometers for Groundwater Measurement and Monitoring 111

8.1 Subsurface Conditions 111

8.2 Ordinary Piezometers and True Piezometers 111

8.3 Piezometer Construction 113

8.4 Verification of Piezometer Performance 115

8.5 Obtaining Data from Piezometers 115

8.6 Pore Pressure Piezometers in Fine-grained Soils 117

8.7 Direct Push Technologies for Piezometer Installation 118

9 Pumping Tests 121

9.1 When a Pumping Test Is Advisable 121

9.2 Planning the Pumping Test 122

9.3 Design of the Pumping Well 122

9.4 Piezometer Array 125

9.5 Duration of Drawdown and Recovery 126

9.6 Pumping Rate 128

9.7 Monitoring the Pumping Test 128

9.8 Analysis of Pumping Test Data 129

9.9 Tidal Corrections 132

9.10 Well Loss 134

9.11 Step Drawdown Tests 136

9.12 Testing of Low-yield Wells 137

9.13 Delayed Storage Release: Boulton Analysis 138

10 Surface Hydrology 141

10.1 Lakes and Reservoirs 141

10.2 Bays and Ocean Beaches 141

10.3 Rivers 141

10.4 Precipitation 144

10.5 Disposal of Dewatering Discharge 145

10.6 Water from Existing Structures 150

11 Geotechnical Investigation for Dewatering 152

11.1 Investigation Approach and Objectives 152

11.2 Preliminary Studies and Investigations 153

11.3 Borings 154

11.4 In Situ Test Methods 164

11.5 Piezometers and Observation Wells 167

11.6 Borehole Seepage Tests for Evaluation of Hydraulic Conductivity 169

11.7 Laboratory Analysis of Samples 178

11.8 Chemical Testing of Groundwater 180

11.9 Geophysical Methods 180

11.10 Pumping Tests 181

11.11 Permanent Effect of Structures on the Groundwater Body 181

11.12 Investigation of the Potential Side Effects of Dewatering 182

11.13 Presentation in the Bidding Documents 183

12 Pump Theory 185

12.1 Types of Pumps Used in Dewatering 185

12.2 Total Dynamic Head 189

12.3 Pump Performance Curves 189

12.4 Vacuum Pumps 190

12.5 Air Lift Pumping 192

12.6 Testing of Pumps 193

13 Groundwater Chemistry, Bacteriology, and Fouling of Dewatering Systems 195

13.1 Types of Corrosion 195

13.2 Corrosive Groundwater Conditions 196

13.3 Dewatering in Corrosive Groundwater Conditions 198

13.4 Incrustation 198

13.5 Mineral Incrustation 199

13.6 Biological Incrustation 200

13.7 Dewatering Systems and Incrustation 205

13.8 Field Evaluation of Well Fouling 208

13.9 Rehabilitation and Maintenance 209

13.10 Analysis of Groundwater 215

14 Contaminated Groundwater 222

14.1 Contaminants Frequently Encountered 222

14.2 Design Options at a Contaminated Site 223

14.3 Estimating Water Quantity to Be Treated 225

14.4 Other Considerations in Treatment Design 225

14.5 Elements of Groundwater Treatment 226

14.6 Recovery of Contaminated Water with Dewatering Techniques 229

14.7 Dynamic Barriers 232

14.8 Wellpoint Systems and Multiphase Contaminants 232

14.9 Reinjection 233

14.10 Health and Safety 234

14.11 Regulating Authorities 234

15 Piping Systems 238

15.1 Dewatering Pipe and Fittings 238

15.2 Losses in Discharge Piping 241

15.3 Losses in Wellpoint Header Lines 241

15.4 Losses in Ejector Headers 243

15.5 Water Hammer 243

Part Two: Practice 245

16 Choosing a Method of Groundwater Control 247

16.1 To Pump or Not to Pump 247

16.2 Open Pumping Versus Predrainage 247

16.3 Methods of Predrainage 250

16.4 Methods of Cutoff and Exclusion 253

16.5 Methods in Combination 253

17 Sumps, Drains, and Open Pumping 259

17.1 Soil and Water Conditions 259

17.2 Boils and Blows 259

17.3 Construction of Sumps 260

17.4 Ditches and Drains 261

17.5 Gravel Bedding 261

17.6 Slope Stabilization with Sandbags, Gravel, and Geotextiles 262

17.7 Use of Geotextiles 262

17.8 Soldier Piles and Lagging: Standup Time 263

17.9 Longterm Effect of Buried Drains 264

17.10 Leaking Utilities 264

17.11 Battered Wellpoints 265

17.12 Horizontal Wellpoints 265

18 Deep Well Systems 267

18.1 Testing During Well Construction 267

18.2 Well Installation and Construction Methods 267

18.3 Wellscreen and Casing 279

18.4 Filter Packs 285

18.5 Development of Wells 291

18.6 Well Construction Details 295

18.7 Pressure Relief Wells, Vacuum Wells 300

18.8 Wells That Pump Sand 300

18.9 Systems of Low-capacity Wells 304

19 Wellpoint Systems 307

19.1 Suction Lifts 307

19.2 Single and Multistage Systems 310

19.3 Wellpoint Design 310

19.4 Wellpoint Spacing 313

19.5 Wellpoint Depth 315

19.6 Installation of Wellpoints 318

19.7 Filter Sands 320

19.8 Wellpoint Pumps, Header, and Discharge Piping 321

19.9 Tuning Wellpoint Systems 323

19.10 Air/Water Separation 326

19.11 Automatic Mops 326

19.12 Vertical Wellpoint Pumps 326

19.13 Wellpoints for Stabilization of Fine-grained Soils 329

19.14 Wellpoint Systems for Trench Work 331

20 Ejector Systems and Other Methods 336

20.1 Two-pipe and Single-pipe Ejectors 336

20.2 Ejector Pumping Stations 338

20.3 Ejector Efficiency 339

20.4 Design of Nozzles and Venturis 340

20.5 Ejector Risers and Swings 344

20.6 Ejector Headers 344

20.7 Ejector Installation 345

20.8 Ejectors and Groundwater Quality 345

20.9 Ejectors and Soil Stabilization 349

20.10 Drilled Horizontal Wells 349

20.11 Trencher Drains 355

21 Groundwater Cutoff Structures 358

21.1 Cutoff Terminology and Efficiency 358

21.2 Steel Sheet Piling 358

21.3 Slurry Trenches 367

21.4 Slurry Diaphragm Walls 379

21.5 Secant Piles 390

21.6 Deep Soil Mixing 398

21.7 Tremie Seals 405

22 Grouting Methods 410

22.1 Permeation Grouting 410

22.2 Jet Grouting 439

22.3 Rock Curtain Grouting 456

22.4 Grouting of Structures and Flowpaths 474

23 Dewatering and Groundwater Control for Soft Ground Tunneling 491

23.1 Soft Ground Tunneling Methods with Conventional Dewatering 491

23.2 Ground Behavior 495

23.3 Mixed-face Ground Conditions 497

23.4 Dewatering Design for Tunnels 497

23.5 Methods of Tunnel Predrainage 499

23.6 Tunneling Techniques with Built-in Groundwater Control 500

23.7 Compressed Air Tunneling 504

23.8 Dewatering of Access Shafts, Penetrations, and Starter Tunnels 505

24 Ground Freezing 508

24.1 General Principles 508

24.2 Freezing Applications 509

24.3 Freezing Methods and Equipment 515

24.4 Ground Freezing and Soils 528

24.5 Design 533

24.6 Effect of Groundwater Movement 534

24.7 Ground Movement Potential as a Result of Artificial Freezing 534

25 Artificial Recharge 539

25.1 Recharge Applications 539

25.2 Design Objectives 540

25.3 Potential Problems with Recharge Water and Plugging of Wells 541

25.4 Sources of Recharge Water 543

25.5 Treatment of Recharge Water 544

25.6 Construction of Recharge Systems 545

25.7 Operation and Maintenance of Recharge Systems 550

25.8 Permits for Recharge Operations 550

26 Electrical Design for Dewatering Systems 556

26.1 Electrical Motors 556

26.2 Motor Controls 561

26.3 Power Factor 564

26.4 Electric Generators 564

26.5 Switchgear and Distribution Systems 566

26.6 Grounding of Electrical Circuits 570

26.7 Cost of Electrical Energy 570

27 Long-term Dewatering Systems 572

27.1 Types of Long-term Systems 572

27.2 Access for Maintenance 572

27.3 Instrumentation and Controls 575

28 Dewatering Costs 577

28.1 Format of the Estimate 577

28.2 Basic Cost Data 577

28.3 Mobilization 578

28.4 Installation and Removal 578

28.5 Operation and Maintenance 579

28.6 Summary 581

28.7 Specialty Dewatering Subcontractor Quotations 581

29 Dewatering Specifications, Allocation of Risk, Dispute Avoidance, and Resolution of Disputes 584

29.1 Performance Specifications 585

29.2 Owner-designed Dewatering Systems 586

29.3 Specified Minimum Systems 586

29.4 Dewatering Submittals 586

29.5 Third-party Damage Caused by Dewatering 587

29.6 Differing Site Conditions 588

29.7 Disputes Review Board 595

Appendix A 597

Appendix B 603

Appendix c 620

Index 623

J. Patrick Powers is a consultant with Mueser Rutledge Consulting Engineers in New York, New York. Arthur B. Corwin is President of Moretrench in Rockaway, New Jersey. Paul C. Schmall is Vice President and Chief Engineer of Moretrench. Walter E. Kaeck is a Senior Associate with Mueser Rutledge Consulting Engineers.