Energy Efficient Manufacturing (eBook, PDF)
Theory and Applications
Redaktion: Sutherland, John W.; Linke, Barbara S.; Dornfeld, David A.
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Energy Efficient Manufacturing (eBook, PDF)
Theory and Applications
Redaktion: Sutherland, John W.; Linke, Barbara S.; Dornfeld, David A.
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Over the last several years, manufacturers have expressed increasing interest in reducing their energy consumption and have begun to search for opportunities to reduce their energy usage. In this book, the authors explore a variety of opportunities to reduce the energy footprint of manufacturing. These opportunities cover the entire spatial scale of the manufacturing enterprise: from unit process-oriented approaches to enterprise-level strategies. Each chapter examines some aspect of this spatial scale, and discusses and describes the opportunities that exist at that level. Case studies…mehr
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Over the last several years, manufacturers have expressed increasing interest in reducing their energy consumption and have begun to search for opportunities to reduce their energy usage. In this book, the authors explore a variety of opportunities to reduce the energy footprint of manufacturing. These opportunities cover the entire spatial scale of the manufacturing enterprise: from unit process-oriented approaches to enterprise-level strategies. Each chapter examines some aspect of this spatial scale, and discusses and describes the opportunities that exist at that level. Case studies demonstrate how the opportunity may be acted on with practical guidance on how to respond to these opportunities.
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Produktdetails
- Produktdetails
- Verlag: John Wiley & Sons
- Seitenzahl: 400
- Erscheinungstermin: 4. Juli 2018
- Englisch
- ISBN-13: 9781119519812
- Artikelnr.: 53433693
- Verlag: John Wiley & Sons
- Seitenzahl: 400
- Erscheinungstermin: 4. Juli 2018
- Englisch
- ISBN-13: 9781119519812
- Artikelnr.: 53433693
John W. Sutherland received his PhD from the University of Illinois at Urbana-Champaign and is a Professor and holds the Fehsenfeld Family Headship of Environmental and Ecological Engineering (EEE) at Purdue University. He is one of the world's leading authorities on the application of sustainability principles to design, manufacturing, and other industrial issues. He has published more than 300 papers in various journals and conference proceedings, authored several book chapters, and is co-author of the text "Statistical Quality Design and Control: Contemporary Concepts and Methods". He is a Fellow of the Society of Manufacturing Engineers, American Society of Mechanical Engineers, and CIRP (International Academy for Production Engineering). His honors and recognitions include the SME Outstanding Young Manufacturing Engineer Award, Presidential Early Career Award for Scientists and Engineers, SAE Ralph R. Teetor Award, SME Education Award, SAE International John Connor Environmental Award, and ASME William T. Ennor Manufacturing Technology Award. David A. Dornfeld received his Ph.D. in Mechanical Engineering from UW-Madison in 1976 and was Will C. Hall Family Professor and Chair of Mechanical Engineering at University of California Berkeley. He led the Laboratory for Manufacturing and Sustainability (LMAS) and the Sustainable Manufacturing Partnership studying green/sustainable manufacturing; manufacturing processes; precision manufacturing; process monitoring and optimization. He published over 400 papers, authored three research monographs, contributed chapters to several books and had seven patents. He was a Member of the National Academy of Engineering (NAE), a Fellow of American Society of Mechanical Engineers (ASME), recipient of ASME/SME M. Eugene Merchant Manufacturing Medal, 2015, Ennor Award, 2010 and Blackall Machine Tool and Gage Award, 1986, Fellow of Society of Manufacturing Engineers (SME), recipient of 2004 SME Fredrick W. Taylor Research Medal, member Japan Society of Precision Engineering (JSPE) and recipient of 2005 JSPE Takagi Prize, Fellow of University of Tokyo Engineering and Fellow of CIRP (International Academy for Production Engineering). He passed away in March 2016. Barbara S. Linke obtained her diploma and doctoral degree in Mechanical Engineering from the RWTH Aachen University, Germany. She worked at the Laboratory for Machine Tools and Production Engineering WZL from 2002 - 2010 on grinding technology and tooling engineering. From 2010 - 2012, Barbara was a research fellow at the University of California Berkeley. Since November 2012, Barbara Linke has been an assistant professor at the University of California Davis.
1 Introduction to Energy Efficient Manufacturing 1 Barbara S. Linke and
John W. Sutherland 1.1 Energy Use Implications 2 1.2 Drivers and Solutions
for Energy Efficiency 3 References 9 2 Operation Planning & Monitoring 11
Y.B. Guo 2.1 Unit Manufacturing Processes 11 2.2 Life Cycle Inventory (LCI)
of Unit Manufacturing Process 13 2.3 Energy Consumption in Unit
Manufacturing Process 16 2.3.1 Basic Concepts of Energy, Power, and Work 16
2.3.2 Framework of Energy Consumption 17 2.4 Operation Plan Relevance to
Energy Consumption 19 2.5 Energy Accounting in Unit Manufacturing Processes
20 2.6 Processing Energy in Unit Manufacturing Process 21 2.6.1 Cases of
Processing Energy Modeling 21 2.6.1.1 Forging 21 2.6.1.2 Orthogonal Cutting
22 2.6.1.3 Grinding 24 2.6.1.4 Specific Energy vs. MRR 25 2.6.2 Energy
Measurement 26 2.7 Energy Reduction Opportunities 26 2.7.1 Shortening
Process Chain by Hard Machining 28 2.7.2 Substitution of Process Steps 28
2.7.3 Hybrid processes 29 2.7.4 Adaptation of Cooling and Flushing
Strategies 29 2.7.5 Remanufacturing 30 References 30 3 Materials Processing
33 Karl R. Haapala, Sundar V. Atre, Ravi Enneti, Ian C. Garretson and Hao
Zhang 3.1 Steel 34 3.1.1 Steelmaking Technology 35 3.2 Aluminum 36 3.2.1
Aluminum Alloying 37 3.2.2 History of Aluminum Processing 37 3.2.3 Aluminum
in Commerce 38 3.2.4 Aluminum Processing 41 3.2.5 Bayer Process 42 3.2.6
Preparation of Carbon 44 3.2.7 Hall-Heroult Electrolytic Process 44 3.3
Titanium 45 3.3.1 Titanium Alloying 46 3.3.2 History of Titanium Processing
47 3.3.3 Titanium in Commerce 48 3.3.4 Titanium Processing Methods 49 3.3.5
Sulfate Process 50 3.3.6 Chloride Process 51 3.3.7 Hunter Process and Kroll
Process 51 3.3.8 Remelting Processes 52 3.3.9 Emerging Titanium Processing
Technologies 52 3.4 Polymers 54 3.4.1 Life Cycle Environmental and Cost
Assessment 59 3.4.2 An Application of Polymer-Powder Processes 59
References 61 4 Energy Reduction in Manufacturing via Incremental Forming
and Surface Microtexturing 65 Jian Cao and Rajiv Malhotra 4.1 Incremental
Forming 66 4.1.1 Conventional Forming Processes 66 4.1.2 Energy Reduction
via Incremental Forming 72 4.1.3 Challenges in Incremental Forming 75
4.1.3.1 Toolpath Planning for Enhanced Geometric Accuracy and Process
Flexibility 76 4.1.3.2 Formability Prediction and Deformation Mechanics 85
4.1.3.3 Process Innovation and Materials Capability in DSIF 92 4.1.3.4
Future Challenges in Incremental Forming 95 4.2 Surface Microtexturing 97
4.2.1 Energy Based Applications of Surface Microtexturing 97 4.2.1.1
Microtexturing for Friction Reduction 97 4.2.1.2 Microtexturing Methods 101
4.2.1.3 Future Work in Microtexturing 114 4.3 Summary 115 4.4
Acknowledgement 116 References 116 5 An Analysis of Energy Consumption and
Energy Efficiency in Material Removal Processes 123 Tao Lu and I.S. Jawahir
5.1 Overview 123 5.2 Plant and Workstation Levels 126 5.3 Operation Level
129 5.4 Process Optimization for Energy Consumption 134 5.4.1 Plant Level
and Workstation Level 134 5.4.2 Operation Level 137 5.4.2.1 Turning
Operation 137 5.4.2.2 Milling Operation 145 5.4.2.3 Drilling Operation 148
5.4.2.4 Grinding Operation 150 5.5 Conclusions 152 Reference 154 6
Nontraditional Removal Processes 159 Murali Sundaram and K.P. Rajurkar 6.1
Introduction 159 6.1.2 Working Principle 160 6.1.2.1 Electrical Discharge
Machining 160 6.1.2.2 Electrochemical Machining 161 6.1.2.3 Electrochemical
Discharge Machining 163 6.1.2.4 Electrochemical Grinding 164 6.2 Energy
Efficiency 165 Acknowledgments 167 References 167 7 Surface Treatment and
Tribological Considerations 169 S.R. Schmid and J. Jeswiet 7.1 Introduction
170 7.2 Surface Treatment Techniques 173 7.2.1 Surface Geometry
Modification 174 7.2.2 Microstructural Modification 175 7.2.3 Chemical
Approaches 179 7.3 Coating Operations 179 7.3.1 Hard Facing 179 7.3.2 Vapor
Deposition 183 7.3.3 Miscellaneous Coating Operations 185 7.4 Tribology 189
7.5 Evolving Technologies 191 7.5.1 Biomimetics - Biologically Inspired
Design 191 7.6 Micro Manufacturing 192 7.7 Conclusions 194 References 194 8
Joining Processes 197 Amber Shrivastava, Manuela Krones and Frank E.
Pfefferkorn 8.1 Introduction 198 8.2 Sustainability in Joining 200 8.3
Taxonomy 203 8.4 Data Sources 205 8.5 Efficiency of Joining Equipment 208
8.6 Efficiency of Joining Processes 210 8.6.1 Fusion Welding 211 8.6.2
Chemical Joining Methods 214 8.6.3 Solid-State Welding 216 8.6.4 Mechanical
Joining Methods 218 8.6.4.1 Mechanical Fastening 218 8.6.4.2 Adhesive
Bonding 219 8.7 Process Selection 220 8.8 Efficiency of Joining Facilities
221 8.9 Case Studies 224 8.9.1 Submerged Arc Welding (SAW) 224 8.9.2
Friction Stir Welding (FSW) 228 Reference 235 9 Manufacturing Equipment 239
M. Helu, N. Diaz-Elsayed and D. Dornfeld 9.1 Introduction 239 9.2 Power
Measurement 240 9.3 Characterizing the Power Demand 242 9.3.1 Constant
Power 242 9.3.2 Variable Power 244 9.3.3 Processing Power 244 9.4 Energy
Model 244 9.5 Life Cycle Energy Analysis of Production Equipment 246 9.6
Energy Reduction Strategies 247 9.6.1 Strategies for Equipment with High
Processing Power 248 9.6.2 Strategies for Equipment with High Tare Power
249 9.6.2.1 Process Time 249 9.6.2.2 Machine Design 251 9.7 Additional Life
Cycle Impacts of Energy Reduction Strategies 252 9.8 Summary 254 References
256 10 Energy Considerations in Assembly Operations 261 Camelio, J.A.,
McCullough, D., Prosch, S. and Rickli, J.L. 10.1 Introduction to Assembly
Systems & Operations 262 10.2 Fundamentals of Assembly Operations 263 10.3
Characterizing Assembly System Energy Consumption 264 10.3.1 Indirect
Energy 265 10.3.2 Direct Energy 266 10.4 Direct Energy Considerations of
Assembly Joining Processes 268 10.4.1 Mechanical Assembly 268 10.4.2
Adhesive Bonding 269 10.4.3 Welding, Brazing, and Soldering 272 10.5
Assembly System Energy Metrics 275 10.6 Case Study: Heavy Duty Truck
Assembly 280 10.6.1 Case Study Energy Consumption Analysis Approach 280
10.6.2 Assembly Process Categorization 281 10.6.3 Case Study Energy
Analysis Results 285 10.6.4 Discussion and Recommendations 292 10.7 Future
of Energy Efficient Assembly Operations 293 References 294 Appendix 10.A
296 11 Manufacturing Facility Energy Improvement 299 Chris Yuan, Junling
Xie and John Nicol 11.1 Introduction 300 11.2 Auxiliary Industrial Energy
Consumptions 303 11.2.1 Lighting 303 11.2.1.1 Lighting Technologies 304
11.2.1.2 Opportunities for Improving Energy Efficiency of Industrial
Lighting 305 11.2.2 HVAC 307 11.2.2.1 HVAC Systems 308 11.2.2.2 HVAC Energy
Efficiency Opportunities 310 11.2.3 Compressed Air 315 11.2.3.1 Compressed
Air Technologies 316 11.2.3.2 Improving Energy Efficiency of Air
Compressors 317 11.3 Industrial Practices on Energy Assessment and Energy
Efficiency Improvement 321 11.3.1 Types of Energy Assessments 321 11.3.2
Energy Assessment Procedures 322 11.4 Energy Management and its Enhancement
Approaches 323 11.4.1 Energy Management Description and Benefits 324 11.4.2
Establishing an Energy Management Approach 326 11.4.2.1 ISO 50001 336 11.5
Conclusions 337 References 338 12 Energy Efficient Manufacturing Process
Planning 339 RuixueYin, Fu Zhao and John W. Sutherland 12.1 Introduction
339 12.2 The Basics of Process Planning 341 12.2.1 Types of Production 342
12.2.2 Process Planning Procedure 344 12.2.3 Process Planning Methods 346
12.3 Energy Efficient Process Planning 350 12.3.1 Energy Consumption and
Carbon Footprint Models of Manufacturing Processes 350 12.3.2 A
Semi-Generative Process Planning Approach for Energy Efficiency 351 12.4
Case Study 353 12.5 Conclusions 357 Reference 358 13 Scheduling for Energy
Efficient Manufacturing 359 Nelson A. Uhan, Andrew Liu and Fu Zhao 13.1
Introduction 359 13.2 A Brief Introduction to Scheduling 360 13.2.1 Machine
Environments 360 13.2.2 Job Characteristics 362 13.3.3 Feasible Schedules
and Gantt Charts 362 13.2.4 Objective Functions: Classic Time-Based
Objectives 364 13.3 Machine Environments 365 13.4 Job Characteristics 367
13.4.1 A Very Brief Introduction to Mathematical Optimization 368 13.4.2 A
Time-Indexed Integer Linear Program for the Energy-Efficient Flow Shop
Problem 370 13.4.3 Algorithms for Solving Integer Linear Programs 376 13.5
Conclusion and Additional Reading 377 References 379 14 Energy Efficiency
in the Supply Chain 381 Thomas J. Goldsby and Fazleena Badurdeen 14.1
Supply Chain Management 381 14.2 Supply Chain Structure 382 14.3 Supply
Chain Processes 385 14.3.1 Customer Relationship Management 387 14.3.2
Supplier Relationship Management 388 14.3.3 Customer Service Management 389
14.3.4 Demand Management 390 14.3.5 Manufacturing Flow Management 391
14.3.6 Order Fulfillment 392 14.3.7 Product Development and
Commercialization 393 14.3.8 Returns Management 394 14.4 Supply Chain
Management Components 395 14.5 Conclusion 396 References 396 Endnotes 400
15 Business Models and Organizational Strategies 401 Omar Romero-Hernandez,
David Hirsch, Sergio Romero and Sara Beckman 15.1 Introduction 402 15.2
Reference Framework for Selection of Energy Efficiency Projects 404 15.2.1
Mission and Drivers 405 15.2.2 Set Level of Assessment 405 15.2.3 Recognize
Opportunities and Risk 406 15.2.4 Select Projects 406 15.2.5 Implementation
and Communication 407 15.3 Common Energy Efficiency Opportunities 408
15.3.1 Building Envelope 408 15.3.2 Heating, Ventilation and Air
Conditioning (HVAC) 409 15.3.3 Efficient Lighting 410 15.3.4 Efficient
Motors and Systems 411 15.3.5 Building Management Systems 412 15.4
Stakeholders 413 15.4.1 Tenants and Owners 413 15.4.2 Regulators 414 15.4.3
Banks/Lenders 414 15.4.4 Energy Service Companies (ESCOs) 415 15.4.5
Business Models 415 15.5 Conclusions 417 References 417 16 Energy Efficient
or Energy Effective Manufacturing? 421 S. A. Shade and J. W. Sutherland
16.1 Energy Efficiency: A Macro Perspective 422 16.1.1 Government
Perspective 422 16.1.2 Company Perspective 423 16.2 The Basics of Energy
Efficiency 425 16.3 Limitations of Energy Efficiency 433 16.4 Energy
Effectiveness 436 16.4.1 Effectiveness - It's Up to the Decision Maker 438
16.4.2 Effectiveness - A Choice on Where to Invest 439 16.4.3 Effectiveness
- Is An Action Really Worthwhile? 439 16.5 Summary 442 16.6 Acknowledgments
443 References 443 Index 445
John W. Sutherland 1.1 Energy Use Implications 2 1.2 Drivers and Solutions
for Energy Efficiency 3 References 9 2 Operation Planning & Monitoring 11
Y.B. Guo 2.1 Unit Manufacturing Processes 11 2.2 Life Cycle Inventory (LCI)
of Unit Manufacturing Process 13 2.3 Energy Consumption in Unit
Manufacturing Process 16 2.3.1 Basic Concepts of Energy, Power, and Work 16
2.3.2 Framework of Energy Consumption 17 2.4 Operation Plan Relevance to
Energy Consumption 19 2.5 Energy Accounting in Unit Manufacturing Processes
20 2.6 Processing Energy in Unit Manufacturing Process 21 2.6.1 Cases of
Processing Energy Modeling 21 2.6.1.1 Forging 21 2.6.1.2 Orthogonal Cutting
22 2.6.1.3 Grinding 24 2.6.1.4 Specific Energy vs. MRR 25 2.6.2 Energy
Measurement 26 2.7 Energy Reduction Opportunities 26 2.7.1 Shortening
Process Chain by Hard Machining 28 2.7.2 Substitution of Process Steps 28
2.7.3 Hybrid processes 29 2.7.4 Adaptation of Cooling and Flushing
Strategies 29 2.7.5 Remanufacturing 30 References 30 3 Materials Processing
33 Karl R. Haapala, Sundar V. Atre, Ravi Enneti, Ian C. Garretson and Hao
Zhang 3.1 Steel 34 3.1.1 Steelmaking Technology 35 3.2 Aluminum 36 3.2.1
Aluminum Alloying 37 3.2.2 History of Aluminum Processing 37 3.2.3 Aluminum
in Commerce 38 3.2.4 Aluminum Processing 41 3.2.5 Bayer Process 42 3.2.6
Preparation of Carbon 44 3.2.7 Hall-Heroult Electrolytic Process 44 3.3
Titanium 45 3.3.1 Titanium Alloying 46 3.3.2 History of Titanium Processing
47 3.3.3 Titanium in Commerce 48 3.3.4 Titanium Processing Methods 49 3.3.5
Sulfate Process 50 3.3.6 Chloride Process 51 3.3.7 Hunter Process and Kroll
Process 51 3.3.8 Remelting Processes 52 3.3.9 Emerging Titanium Processing
Technologies 52 3.4 Polymers 54 3.4.1 Life Cycle Environmental and Cost
Assessment 59 3.4.2 An Application of Polymer-Powder Processes 59
References 61 4 Energy Reduction in Manufacturing via Incremental Forming
and Surface Microtexturing 65 Jian Cao and Rajiv Malhotra 4.1 Incremental
Forming 66 4.1.1 Conventional Forming Processes 66 4.1.2 Energy Reduction
via Incremental Forming 72 4.1.3 Challenges in Incremental Forming 75
4.1.3.1 Toolpath Planning for Enhanced Geometric Accuracy and Process
Flexibility 76 4.1.3.2 Formability Prediction and Deformation Mechanics 85
4.1.3.3 Process Innovation and Materials Capability in DSIF 92 4.1.3.4
Future Challenges in Incremental Forming 95 4.2 Surface Microtexturing 97
4.2.1 Energy Based Applications of Surface Microtexturing 97 4.2.1.1
Microtexturing for Friction Reduction 97 4.2.1.2 Microtexturing Methods 101
4.2.1.3 Future Work in Microtexturing 114 4.3 Summary 115 4.4
Acknowledgement 116 References 116 5 An Analysis of Energy Consumption and
Energy Efficiency in Material Removal Processes 123 Tao Lu and I.S. Jawahir
5.1 Overview 123 5.2 Plant and Workstation Levels 126 5.3 Operation Level
129 5.4 Process Optimization for Energy Consumption 134 5.4.1 Plant Level
and Workstation Level 134 5.4.2 Operation Level 137 5.4.2.1 Turning
Operation 137 5.4.2.2 Milling Operation 145 5.4.2.3 Drilling Operation 148
5.4.2.4 Grinding Operation 150 5.5 Conclusions 152 Reference 154 6
Nontraditional Removal Processes 159 Murali Sundaram and K.P. Rajurkar 6.1
Introduction 159 6.1.2 Working Principle 160 6.1.2.1 Electrical Discharge
Machining 160 6.1.2.2 Electrochemical Machining 161 6.1.2.3 Electrochemical
Discharge Machining 163 6.1.2.4 Electrochemical Grinding 164 6.2 Energy
Efficiency 165 Acknowledgments 167 References 167 7 Surface Treatment and
Tribological Considerations 169 S.R. Schmid and J. Jeswiet 7.1 Introduction
170 7.2 Surface Treatment Techniques 173 7.2.1 Surface Geometry
Modification 174 7.2.2 Microstructural Modification 175 7.2.3 Chemical
Approaches 179 7.3 Coating Operations 179 7.3.1 Hard Facing 179 7.3.2 Vapor
Deposition 183 7.3.3 Miscellaneous Coating Operations 185 7.4 Tribology 189
7.5 Evolving Technologies 191 7.5.1 Biomimetics - Biologically Inspired
Design 191 7.6 Micro Manufacturing 192 7.7 Conclusions 194 References 194 8
Joining Processes 197 Amber Shrivastava, Manuela Krones and Frank E.
Pfefferkorn 8.1 Introduction 198 8.2 Sustainability in Joining 200 8.3
Taxonomy 203 8.4 Data Sources 205 8.5 Efficiency of Joining Equipment 208
8.6 Efficiency of Joining Processes 210 8.6.1 Fusion Welding 211 8.6.2
Chemical Joining Methods 214 8.6.3 Solid-State Welding 216 8.6.4 Mechanical
Joining Methods 218 8.6.4.1 Mechanical Fastening 218 8.6.4.2 Adhesive
Bonding 219 8.7 Process Selection 220 8.8 Efficiency of Joining Facilities
221 8.9 Case Studies 224 8.9.1 Submerged Arc Welding (SAW) 224 8.9.2
Friction Stir Welding (FSW) 228 Reference 235 9 Manufacturing Equipment 239
M. Helu, N. Diaz-Elsayed and D. Dornfeld 9.1 Introduction 239 9.2 Power
Measurement 240 9.3 Characterizing the Power Demand 242 9.3.1 Constant
Power 242 9.3.2 Variable Power 244 9.3.3 Processing Power 244 9.4 Energy
Model 244 9.5 Life Cycle Energy Analysis of Production Equipment 246 9.6
Energy Reduction Strategies 247 9.6.1 Strategies for Equipment with High
Processing Power 248 9.6.2 Strategies for Equipment with High Tare Power
249 9.6.2.1 Process Time 249 9.6.2.2 Machine Design 251 9.7 Additional Life
Cycle Impacts of Energy Reduction Strategies 252 9.8 Summary 254 References
256 10 Energy Considerations in Assembly Operations 261 Camelio, J.A.,
McCullough, D., Prosch, S. and Rickli, J.L. 10.1 Introduction to Assembly
Systems & Operations 262 10.2 Fundamentals of Assembly Operations 263 10.3
Characterizing Assembly System Energy Consumption 264 10.3.1 Indirect
Energy 265 10.3.2 Direct Energy 266 10.4 Direct Energy Considerations of
Assembly Joining Processes 268 10.4.1 Mechanical Assembly 268 10.4.2
Adhesive Bonding 269 10.4.3 Welding, Brazing, and Soldering 272 10.5
Assembly System Energy Metrics 275 10.6 Case Study: Heavy Duty Truck
Assembly 280 10.6.1 Case Study Energy Consumption Analysis Approach 280
10.6.2 Assembly Process Categorization 281 10.6.3 Case Study Energy
Analysis Results 285 10.6.4 Discussion and Recommendations 292 10.7 Future
of Energy Efficient Assembly Operations 293 References 294 Appendix 10.A
296 11 Manufacturing Facility Energy Improvement 299 Chris Yuan, Junling
Xie and John Nicol 11.1 Introduction 300 11.2 Auxiliary Industrial Energy
Consumptions 303 11.2.1 Lighting 303 11.2.1.1 Lighting Technologies 304
11.2.1.2 Opportunities for Improving Energy Efficiency of Industrial
Lighting 305 11.2.2 HVAC 307 11.2.2.1 HVAC Systems 308 11.2.2.2 HVAC Energy
Efficiency Opportunities 310 11.2.3 Compressed Air 315 11.2.3.1 Compressed
Air Technologies 316 11.2.3.2 Improving Energy Efficiency of Air
Compressors 317 11.3 Industrial Practices on Energy Assessment and Energy
Efficiency Improvement 321 11.3.1 Types of Energy Assessments 321 11.3.2
Energy Assessment Procedures 322 11.4 Energy Management and its Enhancement
Approaches 323 11.4.1 Energy Management Description and Benefits 324 11.4.2
Establishing an Energy Management Approach 326 11.4.2.1 ISO 50001 336 11.5
Conclusions 337 References 338 12 Energy Efficient Manufacturing Process
Planning 339 RuixueYin, Fu Zhao and John W. Sutherland 12.1 Introduction
339 12.2 The Basics of Process Planning 341 12.2.1 Types of Production 342
12.2.2 Process Planning Procedure 344 12.2.3 Process Planning Methods 346
12.3 Energy Efficient Process Planning 350 12.3.1 Energy Consumption and
Carbon Footprint Models of Manufacturing Processes 350 12.3.2 A
Semi-Generative Process Planning Approach for Energy Efficiency 351 12.4
Case Study 353 12.5 Conclusions 357 Reference 358 13 Scheduling for Energy
Efficient Manufacturing 359 Nelson A. Uhan, Andrew Liu and Fu Zhao 13.1
Introduction 359 13.2 A Brief Introduction to Scheduling 360 13.2.1 Machine
Environments 360 13.2.2 Job Characteristics 362 13.3.3 Feasible Schedules
and Gantt Charts 362 13.2.4 Objective Functions: Classic Time-Based
Objectives 364 13.3 Machine Environments 365 13.4 Job Characteristics 367
13.4.1 A Very Brief Introduction to Mathematical Optimization 368 13.4.2 A
Time-Indexed Integer Linear Program for the Energy-Efficient Flow Shop
Problem 370 13.4.3 Algorithms for Solving Integer Linear Programs 376 13.5
Conclusion and Additional Reading 377 References 379 14 Energy Efficiency
in the Supply Chain 381 Thomas J. Goldsby and Fazleena Badurdeen 14.1
Supply Chain Management 381 14.2 Supply Chain Structure 382 14.3 Supply
Chain Processes 385 14.3.1 Customer Relationship Management 387 14.3.2
Supplier Relationship Management 388 14.3.3 Customer Service Management 389
14.3.4 Demand Management 390 14.3.5 Manufacturing Flow Management 391
14.3.6 Order Fulfillment 392 14.3.7 Product Development and
Commercialization 393 14.3.8 Returns Management 394 14.4 Supply Chain
Management Components 395 14.5 Conclusion 396 References 396 Endnotes 400
15 Business Models and Organizational Strategies 401 Omar Romero-Hernandez,
David Hirsch, Sergio Romero and Sara Beckman 15.1 Introduction 402 15.2
Reference Framework for Selection of Energy Efficiency Projects 404 15.2.1
Mission and Drivers 405 15.2.2 Set Level of Assessment 405 15.2.3 Recognize
Opportunities and Risk 406 15.2.4 Select Projects 406 15.2.5 Implementation
and Communication 407 15.3 Common Energy Efficiency Opportunities 408
15.3.1 Building Envelope 408 15.3.2 Heating, Ventilation and Air
Conditioning (HVAC) 409 15.3.3 Efficient Lighting 410 15.3.4 Efficient
Motors and Systems 411 15.3.5 Building Management Systems 412 15.4
Stakeholders 413 15.4.1 Tenants and Owners 413 15.4.2 Regulators 414 15.4.3
Banks/Lenders 414 15.4.4 Energy Service Companies (ESCOs) 415 15.4.5
Business Models 415 15.5 Conclusions 417 References 417 16 Energy Efficient
or Energy Effective Manufacturing? 421 S. A. Shade and J. W. Sutherland
16.1 Energy Efficiency: A Macro Perspective 422 16.1.1 Government
Perspective 422 16.1.2 Company Perspective 423 16.2 The Basics of Energy
Efficiency 425 16.3 Limitations of Energy Efficiency 433 16.4 Energy
Effectiveness 436 16.4.1 Effectiveness - It's Up to the Decision Maker 438
16.4.2 Effectiveness - A Choice on Where to Invest 439 16.4.3 Effectiveness
- Is An Action Really Worthwhile? 439 16.5 Summary 442 16.6 Acknowledgments
443 References 443 Index 445
1 Introduction to Energy Efficient Manufacturing 1 Barbara S. Linke and
John W. Sutherland 1.1 Energy Use Implications 2 1.2 Drivers and Solutions
for Energy Efficiency 3 References 9 2 Operation Planning & Monitoring 11
Y.B. Guo 2.1 Unit Manufacturing Processes 11 2.2 Life Cycle Inventory (LCI)
of Unit Manufacturing Process 13 2.3 Energy Consumption in Unit
Manufacturing Process 16 2.3.1 Basic Concepts of Energy, Power, and Work 16
2.3.2 Framework of Energy Consumption 17 2.4 Operation Plan Relevance to
Energy Consumption 19 2.5 Energy Accounting in Unit Manufacturing Processes
20 2.6 Processing Energy in Unit Manufacturing Process 21 2.6.1 Cases of
Processing Energy Modeling 21 2.6.1.1 Forging 21 2.6.1.2 Orthogonal Cutting
22 2.6.1.3 Grinding 24 2.6.1.4 Specific Energy vs. MRR 25 2.6.2 Energy
Measurement 26 2.7 Energy Reduction Opportunities 26 2.7.1 Shortening
Process Chain by Hard Machining 28 2.7.2 Substitution of Process Steps 28
2.7.3 Hybrid processes 29 2.7.4 Adaptation of Cooling and Flushing
Strategies 29 2.7.5 Remanufacturing 30 References 30 3 Materials Processing
33 Karl R. Haapala, Sundar V. Atre, Ravi Enneti, Ian C. Garretson and Hao
Zhang 3.1 Steel 34 3.1.1 Steelmaking Technology 35 3.2 Aluminum 36 3.2.1
Aluminum Alloying 37 3.2.2 History of Aluminum Processing 37 3.2.3 Aluminum
in Commerce 38 3.2.4 Aluminum Processing 41 3.2.5 Bayer Process 42 3.2.6
Preparation of Carbon 44 3.2.7 Hall-Heroult Electrolytic Process 44 3.3
Titanium 45 3.3.1 Titanium Alloying 46 3.3.2 History of Titanium Processing
47 3.3.3 Titanium in Commerce 48 3.3.4 Titanium Processing Methods 49 3.3.5
Sulfate Process 50 3.3.6 Chloride Process 51 3.3.7 Hunter Process and Kroll
Process 51 3.3.8 Remelting Processes 52 3.3.9 Emerging Titanium Processing
Technologies 52 3.4 Polymers 54 3.4.1 Life Cycle Environmental and Cost
Assessment 59 3.4.2 An Application of Polymer-Powder Processes 59
References 61 4 Energy Reduction in Manufacturing via Incremental Forming
and Surface Microtexturing 65 Jian Cao and Rajiv Malhotra 4.1 Incremental
Forming 66 4.1.1 Conventional Forming Processes 66 4.1.2 Energy Reduction
via Incremental Forming 72 4.1.3 Challenges in Incremental Forming 75
4.1.3.1 Toolpath Planning for Enhanced Geometric Accuracy and Process
Flexibility 76 4.1.3.2 Formability Prediction and Deformation Mechanics 85
4.1.3.3 Process Innovation and Materials Capability in DSIF 92 4.1.3.4
Future Challenges in Incremental Forming 95 4.2 Surface Microtexturing 97
4.2.1 Energy Based Applications of Surface Microtexturing 97 4.2.1.1
Microtexturing for Friction Reduction 97 4.2.1.2 Microtexturing Methods 101
4.2.1.3 Future Work in Microtexturing 114 4.3 Summary 115 4.4
Acknowledgement 116 References 116 5 An Analysis of Energy Consumption and
Energy Efficiency in Material Removal Processes 123 Tao Lu and I.S. Jawahir
5.1 Overview 123 5.2 Plant and Workstation Levels 126 5.3 Operation Level
129 5.4 Process Optimization for Energy Consumption 134 5.4.1 Plant Level
and Workstation Level 134 5.4.2 Operation Level 137 5.4.2.1 Turning
Operation 137 5.4.2.2 Milling Operation 145 5.4.2.3 Drilling Operation 148
5.4.2.4 Grinding Operation 150 5.5 Conclusions 152 Reference 154 6
Nontraditional Removal Processes 159 Murali Sundaram and K.P. Rajurkar 6.1
Introduction 159 6.1.2 Working Principle 160 6.1.2.1 Electrical Discharge
Machining 160 6.1.2.2 Electrochemical Machining 161 6.1.2.3 Electrochemical
Discharge Machining 163 6.1.2.4 Electrochemical Grinding 164 6.2 Energy
Efficiency 165 Acknowledgments 167 References 167 7 Surface Treatment and
Tribological Considerations 169 S.R. Schmid and J. Jeswiet 7.1 Introduction
170 7.2 Surface Treatment Techniques 173 7.2.1 Surface Geometry
Modification 174 7.2.2 Microstructural Modification 175 7.2.3 Chemical
Approaches 179 7.3 Coating Operations 179 7.3.1 Hard Facing 179 7.3.2 Vapor
Deposition 183 7.3.3 Miscellaneous Coating Operations 185 7.4 Tribology 189
7.5 Evolving Technologies 191 7.5.1 Biomimetics - Biologically Inspired
Design 191 7.6 Micro Manufacturing 192 7.7 Conclusions 194 References 194 8
Joining Processes 197 Amber Shrivastava, Manuela Krones and Frank E.
Pfefferkorn 8.1 Introduction 198 8.2 Sustainability in Joining 200 8.3
Taxonomy 203 8.4 Data Sources 205 8.5 Efficiency of Joining Equipment 208
8.6 Efficiency of Joining Processes 210 8.6.1 Fusion Welding 211 8.6.2
Chemical Joining Methods 214 8.6.3 Solid-State Welding 216 8.6.4 Mechanical
Joining Methods 218 8.6.4.1 Mechanical Fastening 218 8.6.4.2 Adhesive
Bonding 219 8.7 Process Selection 220 8.8 Efficiency of Joining Facilities
221 8.9 Case Studies 224 8.9.1 Submerged Arc Welding (SAW) 224 8.9.2
Friction Stir Welding (FSW) 228 Reference 235 9 Manufacturing Equipment 239
M. Helu, N. Diaz-Elsayed and D. Dornfeld 9.1 Introduction 239 9.2 Power
Measurement 240 9.3 Characterizing the Power Demand 242 9.3.1 Constant
Power 242 9.3.2 Variable Power 244 9.3.3 Processing Power 244 9.4 Energy
Model 244 9.5 Life Cycle Energy Analysis of Production Equipment 246 9.6
Energy Reduction Strategies 247 9.6.1 Strategies for Equipment with High
Processing Power 248 9.6.2 Strategies for Equipment with High Tare Power
249 9.6.2.1 Process Time 249 9.6.2.2 Machine Design 251 9.7 Additional Life
Cycle Impacts of Energy Reduction Strategies 252 9.8 Summary 254 References
256 10 Energy Considerations in Assembly Operations 261 Camelio, J.A.,
McCullough, D., Prosch, S. and Rickli, J.L. 10.1 Introduction to Assembly
Systems & Operations 262 10.2 Fundamentals of Assembly Operations 263 10.3
Characterizing Assembly System Energy Consumption 264 10.3.1 Indirect
Energy 265 10.3.2 Direct Energy 266 10.4 Direct Energy Considerations of
Assembly Joining Processes 268 10.4.1 Mechanical Assembly 268 10.4.2
Adhesive Bonding 269 10.4.3 Welding, Brazing, and Soldering 272 10.5
Assembly System Energy Metrics 275 10.6 Case Study: Heavy Duty Truck
Assembly 280 10.6.1 Case Study Energy Consumption Analysis Approach 280
10.6.2 Assembly Process Categorization 281 10.6.3 Case Study Energy
Analysis Results 285 10.6.4 Discussion and Recommendations 292 10.7 Future
of Energy Efficient Assembly Operations 293 References 294 Appendix 10.A
296 11 Manufacturing Facility Energy Improvement 299 Chris Yuan, Junling
Xie and John Nicol 11.1 Introduction 300 11.2 Auxiliary Industrial Energy
Consumptions 303 11.2.1 Lighting 303 11.2.1.1 Lighting Technologies 304
11.2.1.2 Opportunities for Improving Energy Efficiency of Industrial
Lighting 305 11.2.2 HVAC 307 11.2.2.1 HVAC Systems 308 11.2.2.2 HVAC Energy
Efficiency Opportunities 310 11.2.3 Compressed Air 315 11.2.3.1 Compressed
Air Technologies 316 11.2.3.2 Improving Energy Efficiency of Air
Compressors 317 11.3 Industrial Practices on Energy Assessment and Energy
Efficiency Improvement 321 11.3.1 Types of Energy Assessments 321 11.3.2
Energy Assessment Procedures 322 11.4 Energy Management and its Enhancement
Approaches 323 11.4.1 Energy Management Description and Benefits 324 11.4.2
Establishing an Energy Management Approach 326 11.4.2.1 ISO 50001 336 11.5
Conclusions 337 References 338 12 Energy Efficient Manufacturing Process
Planning 339 RuixueYin, Fu Zhao and John W. Sutherland 12.1 Introduction
339 12.2 The Basics of Process Planning 341 12.2.1 Types of Production 342
12.2.2 Process Planning Procedure 344 12.2.3 Process Planning Methods 346
12.3 Energy Efficient Process Planning 350 12.3.1 Energy Consumption and
Carbon Footprint Models of Manufacturing Processes 350 12.3.2 A
Semi-Generative Process Planning Approach for Energy Efficiency 351 12.4
Case Study 353 12.5 Conclusions 357 Reference 358 13 Scheduling for Energy
Efficient Manufacturing 359 Nelson A. Uhan, Andrew Liu and Fu Zhao 13.1
Introduction 359 13.2 A Brief Introduction to Scheduling 360 13.2.1 Machine
Environments 360 13.2.2 Job Characteristics 362 13.3.3 Feasible Schedules
and Gantt Charts 362 13.2.4 Objective Functions: Classic Time-Based
Objectives 364 13.3 Machine Environments 365 13.4 Job Characteristics 367
13.4.1 A Very Brief Introduction to Mathematical Optimization 368 13.4.2 A
Time-Indexed Integer Linear Program for the Energy-Efficient Flow Shop
Problem 370 13.4.3 Algorithms for Solving Integer Linear Programs 376 13.5
Conclusion and Additional Reading 377 References 379 14 Energy Efficiency
in the Supply Chain 381 Thomas J. Goldsby and Fazleena Badurdeen 14.1
Supply Chain Management 381 14.2 Supply Chain Structure 382 14.3 Supply
Chain Processes 385 14.3.1 Customer Relationship Management 387 14.3.2
Supplier Relationship Management 388 14.3.3 Customer Service Management 389
14.3.4 Demand Management 390 14.3.5 Manufacturing Flow Management 391
14.3.6 Order Fulfillment 392 14.3.7 Product Development and
Commercialization 393 14.3.8 Returns Management 394 14.4 Supply Chain
Management Components 395 14.5 Conclusion 396 References 396 Endnotes 400
15 Business Models and Organizational Strategies 401 Omar Romero-Hernandez,
David Hirsch, Sergio Romero and Sara Beckman 15.1 Introduction 402 15.2
Reference Framework for Selection of Energy Efficiency Projects 404 15.2.1
Mission and Drivers 405 15.2.2 Set Level of Assessment 405 15.2.3 Recognize
Opportunities and Risk 406 15.2.4 Select Projects 406 15.2.5 Implementation
and Communication 407 15.3 Common Energy Efficiency Opportunities 408
15.3.1 Building Envelope 408 15.3.2 Heating, Ventilation and Air
Conditioning (HVAC) 409 15.3.3 Efficient Lighting 410 15.3.4 Efficient
Motors and Systems 411 15.3.5 Building Management Systems 412 15.4
Stakeholders 413 15.4.1 Tenants and Owners 413 15.4.2 Regulators 414 15.4.3
Banks/Lenders 414 15.4.4 Energy Service Companies (ESCOs) 415 15.4.5
Business Models 415 15.5 Conclusions 417 References 417 16 Energy Efficient
or Energy Effective Manufacturing? 421 S. A. Shade and J. W. Sutherland
16.1 Energy Efficiency: A Macro Perspective 422 16.1.1 Government
Perspective 422 16.1.2 Company Perspective 423 16.2 The Basics of Energy
Efficiency 425 16.3 Limitations of Energy Efficiency 433 16.4 Energy
Effectiveness 436 16.4.1 Effectiveness - It's Up to the Decision Maker 438
16.4.2 Effectiveness - A Choice on Where to Invest 439 16.4.3 Effectiveness
- Is An Action Really Worthwhile? 439 16.5 Summary 442 16.6 Acknowledgments
443 References 443 Index 445
John W. Sutherland 1.1 Energy Use Implications 2 1.2 Drivers and Solutions
for Energy Efficiency 3 References 9 2 Operation Planning & Monitoring 11
Y.B. Guo 2.1 Unit Manufacturing Processes 11 2.2 Life Cycle Inventory (LCI)
of Unit Manufacturing Process 13 2.3 Energy Consumption in Unit
Manufacturing Process 16 2.3.1 Basic Concepts of Energy, Power, and Work 16
2.3.2 Framework of Energy Consumption 17 2.4 Operation Plan Relevance to
Energy Consumption 19 2.5 Energy Accounting in Unit Manufacturing Processes
20 2.6 Processing Energy in Unit Manufacturing Process 21 2.6.1 Cases of
Processing Energy Modeling 21 2.6.1.1 Forging 21 2.6.1.2 Orthogonal Cutting
22 2.6.1.3 Grinding 24 2.6.1.4 Specific Energy vs. MRR 25 2.6.2 Energy
Measurement 26 2.7 Energy Reduction Opportunities 26 2.7.1 Shortening
Process Chain by Hard Machining 28 2.7.2 Substitution of Process Steps 28
2.7.3 Hybrid processes 29 2.7.4 Adaptation of Cooling and Flushing
Strategies 29 2.7.5 Remanufacturing 30 References 30 3 Materials Processing
33 Karl R. Haapala, Sundar V. Atre, Ravi Enneti, Ian C. Garretson and Hao
Zhang 3.1 Steel 34 3.1.1 Steelmaking Technology 35 3.2 Aluminum 36 3.2.1
Aluminum Alloying 37 3.2.2 History of Aluminum Processing 37 3.2.3 Aluminum
in Commerce 38 3.2.4 Aluminum Processing 41 3.2.5 Bayer Process 42 3.2.6
Preparation of Carbon 44 3.2.7 Hall-Heroult Electrolytic Process 44 3.3
Titanium 45 3.3.1 Titanium Alloying 46 3.3.2 History of Titanium Processing
47 3.3.3 Titanium in Commerce 48 3.3.4 Titanium Processing Methods 49 3.3.5
Sulfate Process 50 3.3.6 Chloride Process 51 3.3.7 Hunter Process and Kroll
Process 51 3.3.8 Remelting Processes 52 3.3.9 Emerging Titanium Processing
Technologies 52 3.4 Polymers 54 3.4.1 Life Cycle Environmental and Cost
Assessment 59 3.4.2 An Application of Polymer-Powder Processes 59
References 61 4 Energy Reduction in Manufacturing via Incremental Forming
and Surface Microtexturing 65 Jian Cao and Rajiv Malhotra 4.1 Incremental
Forming 66 4.1.1 Conventional Forming Processes 66 4.1.2 Energy Reduction
via Incremental Forming 72 4.1.3 Challenges in Incremental Forming 75
4.1.3.1 Toolpath Planning for Enhanced Geometric Accuracy and Process
Flexibility 76 4.1.3.2 Formability Prediction and Deformation Mechanics 85
4.1.3.3 Process Innovation and Materials Capability in DSIF 92 4.1.3.4
Future Challenges in Incremental Forming 95 4.2 Surface Microtexturing 97
4.2.1 Energy Based Applications of Surface Microtexturing 97 4.2.1.1
Microtexturing for Friction Reduction 97 4.2.1.2 Microtexturing Methods 101
4.2.1.3 Future Work in Microtexturing 114 4.3 Summary 115 4.4
Acknowledgement 116 References 116 5 An Analysis of Energy Consumption and
Energy Efficiency in Material Removal Processes 123 Tao Lu and I.S. Jawahir
5.1 Overview 123 5.2 Plant and Workstation Levels 126 5.3 Operation Level
129 5.4 Process Optimization for Energy Consumption 134 5.4.1 Plant Level
and Workstation Level 134 5.4.2 Operation Level 137 5.4.2.1 Turning
Operation 137 5.4.2.2 Milling Operation 145 5.4.2.3 Drilling Operation 148
5.4.2.4 Grinding Operation 150 5.5 Conclusions 152 Reference 154 6
Nontraditional Removal Processes 159 Murali Sundaram and K.P. Rajurkar 6.1
Introduction 159 6.1.2 Working Principle 160 6.1.2.1 Electrical Discharge
Machining 160 6.1.2.2 Electrochemical Machining 161 6.1.2.3 Electrochemical
Discharge Machining 163 6.1.2.4 Electrochemical Grinding 164 6.2 Energy
Efficiency 165 Acknowledgments 167 References 167 7 Surface Treatment and
Tribological Considerations 169 S.R. Schmid and J. Jeswiet 7.1 Introduction
170 7.2 Surface Treatment Techniques 173 7.2.1 Surface Geometry
Modification 174 7.2.2 Microstructural Modification 175 7.2.3 Chemical
Approaches 179 7.3 Coating Operations 179 7.3.1 Hard Facing 179 7.3.2 Vapor
Deposition 183 7.3.3 Miscellaneous Coating Operations 185 7.4 Tribology 189
7.5 Evolving Technologies 191 7.5.1 Biomimetics - Biologically Inspired
Design 191 7.6 Micro Manufacturing 192 7.7 Conclusions 194 References 194 8
Joining Processes 197 Amber Shrivastava, Manuela Krones and Frank E.
Pfefferkorn 8.1 Introduction 198 8.2 Sustainability in Joining 200 8.3
Taxonomy 203 8.4 Data Sources 205 8.5 Efficiency of Joining Equipment 208
8.6 Efficiency of Joining Processes 210 8.6.1 Fusion Welding 211 8.6.2
Chemical Joining Methods 214 8.6.3 Solid-State Welding 216 8.6.4 Mechanical
Joining Methods 218 8.6.4.1 Mechanical Fastening 218 8.6.4.2 Adhesive
Bonding 219 8.7 Process Selection 220 8.8 Efficiency of Joining Facilities
221 8.9 Case Studies 224 8.9.1 Submerged Arc Welding (SAW) 224 8.9.2
Friction Stir Welding (FSW) 228 Reference 235 9 Manufacturing Equipment 239
M. Helu, N. Diaz-Elsayed and D. Dornfeld 9.1 Introduction 239 9.2 Power
Measurement 240 9.3 Characterizing the Power Demand 242 9.3.1 Constant
Power 242 9.3.2 Variable Power 244 9.3.3 Processing Power 244 9.4 Energy
Model 244 9.5 Life Cycle Energy Analysis of Production Equipment 246 9.6
Energy Reduction Strategies 247 9.6.1 Strategies for Equipment with High
Processing Power 248 9.6.2 Strategies for Equipment with High Tare Power
249 9.6.2.1 Process Time 249 9.6.2.2 Machine Design 251 9.7 Additional Life
Cycle Impacts of Energy Reduction Strategies 252 9.8 Summary 254 References
256 10 Energy Considerations in Assembly Operations 261 Camelio, J.A.,
McCullough, D., Prosch, S. and Rickli, J.L. 10.1 Introduction to Assembly
Systems & Operations 262 10.2 Fundamentals of Assembly Operations 263 10.3
Characterizing Assembly System Energy Consumption 264 10.3.1 Indirect
Energy 265 10.3.2 Direct Energy 266 10.4 Direct Energy Considerations of
Assembly Joining Processes 268 10.4.1 Mechanical Assembly 268 10.4.2
Adhesive Bonding 269 10.4.3 Welding, Brazing, and Soldering 272 10.5
Assembly System Energy Metrics 275 10.6 Case Study: Heavy Duty Truck
Assembly 280 10.6.1 Case Study Energy Consumption Analysis Approach 280
10.6.2 Assembly Process Categorization 281 10.6.3 Case Study Energy
Analysis Results 285 10.6.4 Discussion and Recommendations 292 10.7 Future
of Energy Efficient Assembly Operations 293 References 294 Appendix 10.A
296 11 Manufacturing Facility Energy Improvement 299 Chris Yuan, Junling
Xie and John Nicol 11.1 Introduction 300 11.2 Auxiliary Industrial Energy
Consumptions 303 11.2.1 Lighting 303 11.2.1.1 Lighting Technologies 304
11.2.1.2 Opportunities for Improving Energy Efficiency of Industrial
Lighting 305 11.2.2 HVAC 307 11.2.2.1 HVAC Systems 308 11.2.2.2 HVAC Energy
Efficiency Opportunities 310 11.2.3 Compressed Air 315 11.2.3.1 Compressed
Air Technologies 316 11.2.3.2 Improving Energy Efficiency of Air
Compressors 317 11.3 Industrial Practices on Energy Assessment and Energy
Efficiency Improvement 321 11.3.1 Types of Energy Assessments 321 11.3.2
Energy Assessment Procedures 322 11.4 Energy Management and its Enhancement
Approaches 323 11.4.1 Energy Management Description and Benefits 324 11.4.2
Establishing an Energy Management Approach 326 11.4.2.1 ISO 50001 336 11.5
Conclusions 337 References 338 12 Energy Efficient Manufacturing Process
Planning 339 RuixueYin, Fu Zhao and John W. Sutherland 12.1 Introduction
339 12.2 The Basics of Process Planning 341 12.2.1 Types of Production 342
12.2.2 Process Planning Procedure 344 12.2.3 Process Planning Methods 346
12.3 Energy Efficient Process Planning 350 12.3.1 Energy Consumption and
Carbon Footprint Models of Manufacturing Processes 350 12.3.2 A
Semi-Generative Process Planning Approach for Energy Efficiency 351 12.4
Case Study 353 12.5 Conclusions 357 Reference 358 13 Scheduling for Energy
Efficient Manufacturing 359 Nelson A. Uhan, Andrew Liu and Fu Zhao 13.1
Introduction 359 13.2 A Brief Introduction to Scheduling 360 13.2.1 Machine
Environments 360 13.2.2 Job Characteristics 362 13.3.3 Feasible Schedules
and Gantt Charts 362 13.2.4 Objective Functions: Classic Time-Based
Objectives 364 13.3 Machine Environments 365 13.4 Job Characteristics 367
13.4.1 A Very Brief Introduction to Mathematical Optimization 368 13.4.2 A
Time-Indexed Integer Linear Program for the Energy-Efficient Flow Shop
Problem 370 13.4.3 Algorithms for Solving Integer Linear Programs 376 13.5
Conclusion and Additional Reading 377 References 379 14 Energy Efficiency
in the Supply Chain 381 Thomas J. Goldsby and Fazleena Badurdeen 14.1
Supply Chain Management 381 14.2 Supply Chain Structure 382 14.3 Supply
Chain Processes 385 14.3.1 Customer Relationship Management 387 14.3.2
Supplier Relationship Management 388 14.3.3 Customer Service Management 389
14.3.4 Demand Management 390 14.3.5 Manufacturing Flow Management 391
14.3.6 Order Fulfillment 392 14.3.7 Product Development and
Commercialization 393 14.3.8 Returns Management 394 14.4 Supply Chain
Management Components 395 14.5 Conclusion 396 References 396 Endnotes 400
15 Business Models and Organizational Strategies 401 Omar Romero-Hernandez,
David Hirsch, Sergio Romero and Sara Beckman 15.1 Introduction 402 15.2
Reference Framework for Selection of Energy Efficiency Projects 404 15.2.1
Mission and Drivers 405 15.2.2 Set Level of Assessment 405 15.2.3 Recognize
Opportunities and Risk 406 15.2.4 Select Projects 406 15.2.5 Implementation
and Communication 407 15.3 Common Energy Efficiency Opportunities 408
15.3.1 Building Envelope 408 15.3.2 Heating, Ventilation and Air
Conditioning (HVAC) 409 15.3.3 Efficient Lighting 410 15.3.4 Efficient
Motors and Systems 411 15.3.5 Building Management Systems 412 15.4
Stakeholders 413 15.4.1 Tenants and Owners 413 15.4.2 Regulators 414 15.4.3
Banks/Lenders 414 15.4.4 Energy Service Companies (ESCOs) 415 15.4.5
Business Models 415 15.5 Conclusions 417 References 417 16 Energy Efficient
or Energy Effective Manufacturing? 421 S. A. Shade and J. W. Sutherland
16.1 Energy Efficiency: A Macro Perspective 422 16.1.1 Government
Perspective 422 16.1.2 Company Perspective 423 16.2 The Basics of Energy
Efficiency 425 16.3 Limitations of Energy Efficiency 433 16.4 Energy
Effectiveness 436 16.4.1 Effectiveness - It's Up to the Decision Maker 438
16.4.2 Effectiveness - A Choice on Where to Invest 439 16.4.3 Effectiveness
- Is An Action Really Worthwhile? 439 16.5 Summary 442 16.6 Acknowledgments
443 References 443 Index 445