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Technology and Energy Sources Monitoring

Book Description

As energy technology has emerged as an essential way to provide efficiency and environmental safety, monitoring these energy sources is a way of measuring the effectiveness of the applications and the fundamentals of each design.Technology and Energy Sources Monitoring: Control, Efficiency, and Optimization provides an overall understanding of the technology and energy processes of renewable energy sources, biomaterials and more. By outlining the primary intent of the applications of energy technology and sustainable energy systems development, this book aims to bring a deeper understanding of the innovations and measures taken towards the monitoring of energy sources. 

Table of Contents

  1. Cover
  2. Title Page
  3. Copyright Page
  4. Preface
  5. Acknowledgment
  6. Chapter 1: Introduction
    1. ABSTRACT
    2. 1.1. ORIGINS (PRELIMINARY REMARKS)
    3. 1.2. DEVELOPMENT (INNOVATION PROGRESS)
    4. 1.3. CONTROL (OFFSET ADJUSTMENT, OPTIMIZATION, MELIORATION, THEORY)
    5. 1.4. OPTIMIZING (TECHNICAL SYSTEM, STRUCTURE, PROCESS)
    6. 1.5. MELIORATION (ENVIRONMENT, NATURAL ENVIRONMENT, TECHNOLOGICAL, AND CULTURAL DEVELOPMENT OF THE THEORY)
    7. 1.6. MONITORING (THE STATES AND THE TRANSFORMATION OF OPTIMIZATION, WATER MELIORATION, THEORY)
    8. 1.7. SOURCES OF ENERGY (NON-RENEWABLE, RENEWABLE, SOLAR)
    9. 1.8. TECHNOLOGIES (ENERGY, MASS, PROCESSING, TRANSFORMATION, TRANSPORTATION, STORAGE)
  7. Chapter 2: Technologies
    1. ABSTRACT
    2. 2.1. OPERATION STATE VARIABLES
    3. 2.2. PROCESSING VARIABLES
    4. 2.3. MACHINE DESIGN VARIABLES
    5. 2.4. OPERATION VARIABLES
    6. 2.5. PRODUCT QUALITY
    7. 2.6. PROCESS EFFICIENCY
    8. 2.7. PRODUCT AND PROCESS DESTRUCTIVENESS
    9. 2.8. RESEARCH METHODOLOGY
    10. 2.9. METHODOLOGY OF OPTIMIZATION
    11. 2.10. ENERGY PARAMETER H
    12. 2.11. EXAMPLE: GRINDER DESIGN SOLUTION
    13. 2.12. CONCLUSION
  8. Chapter 3: The Environment of Energy Goods
    1. ABSTRACT
    2. 3.1. INTRODUCTORY REMARKS
    3. 3.2. CONVENTIONAL ENERGY SOURCES
    4. 3.3. BIO-ENERGY PROCESSORS
    5. 3.4. RANKING LIST OF ENERGY PROCESSORS FOR THE YEARS UP TO 2020
    6. 3.5. WATER ENERGY PROCESSOR
    7. 3.6. INNOVATION OF TECHNICAL ENERGY SYSTEM
    8. 3.7. TOXICITY AND THE SAFETY OF ENERGY PRODUCTS
    9. 3.8. SPUTTERING OF ENERGETIC WIRES
    10. 3.9. DUST-FREE ENERGY MACHINES
    11. 3.10. POLLUTION OF ENERGY DEVICE MATERIALS ORIGIN
    12. 3.11. SPECIAL TECHNOLOGIES
  9. Chapter 4: Energy Efficient Acting Systems
    1. ABSTRACT
    2. 4.1. CONCEPT OF ENERGY AND EFFECTIVENESS
    3. 4.2. ENERGY SYSTEM ANALYSIS
    4. 4.3. HUMAN POTENTIAL
    5. 4.4. TECHNOLOGY POTENTIAL
    6. 4.5. ENERGY: MATERIAL POTENTIAL
    7. 4.6. CONTROLLING AND MONITORING POTENTIAL
    8. 4.7. WASTE POTENTIAL
    9. 4.8. POTENTIALS FOR THE FUTURE
    10. 4.9. POTENTIALS FOR THE SECURE LIFE
    11. 4.10. CONCLUSION
  10. Chapter 5: Special Systems of Technology
    1. ABSTRACT
    2. 5.1. COMPLEXITY OF THE SPECIAL SYSTEM
    3. 5.2. SPECIAL SYSTEMS
    4. 5.3. ENERGY SAFETY
    5. 5.4. RELIABLE PROCESSING
    6. 5.5. CONTROLLABILITY
    7. 5.6. INFORMATION ORDER
    8. 5.7. LOGISTICS CHALLENGES
    9. 5.8. CONTROL SYSTEM EXAMPLE
    10. 5.9. INFORMATION SYSTEM EXAMPLE
    11. 5.10. LOGISTICS SYSTEM EXAMPLE
  11. Chapter 6: System and Environment Design
    1. ABSTRACT
    2. 6.1. DESIGN BASICS
    3. 6.2. CHARACTERISTICS
    4. 6.3. THE INTEGRITY OF CREATION
    5. 6.4. THE SUBJECT MATTER AND SCOPE
    6. 6.5. THE DISTINCTIVENESS
    7. 6.6. DESIGNING CONDITIONS OR OBJECTIVES?
    8. 6.7. DESIGNING MELIORATION OR TECHNICAL SYSTEM?
    9. 6.8. WASTE
    10. 6.9. POWER STATIONS
    11. 6.10. ENVIRONMENTAL IMPROVEMENT
    12. 6.11. PERSISTENCE IN THE ENVIRONMENT
    13. 6.12. ENVIRONMENTAL RECOVERY
  12. Chapter 7: Beauty of the Environment, Knowledge, and Systems
    1. ABSTRACT
    2. 7.1. BEAUTY INSPIRING TO WORK
    3. 7.2. EPISTEMOLOGY AND ONTOLOGY OF THE TECHNICAL SYSTEM
    4. 7.3. INTEGRON: CONTROL, MELIORATION, AND OPTIMIZATION MODEL
    5. 7.4. INTEGRATION OF MONITORING
    6. 7.5. DETERMINATION OF MONITORING
    7. 7.6. MONITORING LIFE
    8. 7.7. CELL PHONE-AIDED TECHNICAL SYSTEMS MONITORING
    9. 7.8. COORDINATION OF OPTIMAL SOLUTIONS
    10. 7.9. ENVIRONMENTAL LIFE CYCLE OF TECHNICAL SYSTEM
    11. 7.10. CONCLUSION
  13. Chapter 8: Innovative Monitoring
    1. ABSTRACT
    2. 8.1. ACTIVE MONITORING STRUCTURE
    3. 8.2. INTEGRATING THE STRUCTURE OF TECHNOLOGY AND ENERGY SOURCES MONITOR
    4. 8.3. ENERGY PROCESS MONITORING
    5. 8.4. PHOTOVOLTAIC SYSTEM MONITOR
    6. 8.5. GRINDING PROCESS MONITOR
    7. 8.6. NEW INFORMATION STRUCTURE
    8. 8.7. ENERGY QUALITY
    9. 8.8. SMART GRID
    10. 8.9. POLYMODAL SOLUTION OF CAR SYSTEMS
    11. 8.10. WATER MELIORATION
  14. Chapter 9: Optimization and Sustainable Development
    1. ABSTRACT
    2. 9.1. CONDITIONS FOR OPTIMIZATION
    3. 9.2. PRINCIPLE OF OPTIMIZATION
    4. 9.3. SYSTEMS AND ENVIRONMENTS MODEL
    5. 9.4. VARIABLE OF SYSTEMS
    6. 9.5. CONDITIONS AND MATHEMATICAL MODEL
    7. 9.6. SYSTEM SIMULATION
    8. 9.7. INNOVATION OF DESIGN
    9. 9.8. OPTIMAL NOVELTY
    10. 9.9. NEW SOLUTIONS
  15. Chapter 10: Active Monitoring, Machinery Example
    1. ABSTRACT
    2. 10.1. MOTIONAL CHARACTERISTICS
    3. 10.2. ASSUMPTIONS
    4. 10.3. CREATION OF THE GRINDING BOUNDARY ZONE
    5. 10.4. THE MELIORATION OF TECHNOLOGY ENVIRONMENT
    6. 10.5. OPTIMIZATION (COMPENSATION) OF THE TECHNICAL SYSTEM
    7. 10.6. SOLUTIONS OF ACTIVE MONITORING
    8. 10.7. SOLUTIONS AND RESULTS ANALYSIS
    9. CONCLUSION
  16. Glossary of Symbols
  17. Glossary of Terms
  18. Compilation of References
  19. About the Authors