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Mechanical engineers handbook Energy and Power 4th Edition by Myer Kutz ISBN 1118956370 9781118956373

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Author(s): Myer Kutz
ISBN(s): 9781118112854, 1118112857
Edition: 4
File Details: PDF, 16.46 MB
Year: 2015
Language: english
SKU: EB-5252736 Category: Tag:

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ISBN 10:    1118956370
ISBN 13: 978-1118956373
Author:        Myer Kutz

The original concept behind publishing the Mechanical Engineers’ Handbook was to provide a single source for all critical information needed by mechanical engineers in the diverse industries and job functions they find themselves. No single engineer can be a specialist in all areas that they are called on to work and the handbook provides a quick guide to specialized areas so that the engineer can know the basics and where to go for further reading. Kutz’s handbook was positioned to provide discussion, examples, and analysis of the topics covered as opposed to the straight data, formulas and calculations provided by other handbooks. Because of the widening breadth of subjects covered and specialization required from engineers we have divided the content beyond the single book to four separate, but related books.  This first book covers Materials and Mechanical Design. Other books cover; Electronics/MEMS/Instrumentation Manufacturing and Energy & Power. Each book is sold separately or in combination with other volumes as the market requires.
 

Mechanical engineers handbook Energy and Power 4th Table of contents:

Part 1: Energy

Chapter 1: Thermophysical Properties of Fluids

Chapter 2: Mechanics of Incompressible Fluids

  1. Introduction

  2. Fluid Properties

  3. Fluid Statics

  4. Ideal (Inviscid) Fluid Dynamics

  5. Viscous Fluid Dynamics

  6. Similitude and Dimensional Analysis

  7. Flow in Closed Conduits

  8. Flow in Open Channels

  9. Flow About Immersed Objects

  10. Fluid Measurements

  • References

  • Bibliography

Chapter 3: Thermodynamics Fundamentals

  1. Introduction

  2. First Law of Thermodynamics for Closed Systems

  3. Second Law of Thermodynamics for Closed Systems

  4. Energy Minimum Principle

  5. Laws of Thermodynamics for Open Systems

  6. Relations Among Thermodynamic Properties

  7. Analysis of Engineering System Components

  • References

Chapter 4: Exergy Analysis, Entropy Generation Minimization, and the Constructal Law

  1. Introduction

  2. Exergy Analysis

  3. Entropy Generation Minimization

  4. Cryogenics

  5. Heat Transfer

  6. Storage Systems

  7. Solar Energy Conversion

  8. Power Plants

  9. Constructal Law

  • References

Chapter 5: Heat Transfer Fundamentals

  1. Conduction Heat Transfer

  2. Convection Heat Transfer

  3. Radiation Heat Transfer

  4. Boiling and Condensation Heat Transfer

  • References

  • Bibliography

Chapter 6: Temperature Measurement

  1. Introduction

  2. Selection

  3. Invasive Temperature Measurement

  4. Semi-Invasive Methods

  5. Noninvasive Methods

  6. Conclusions

  • References

Chapter 7: Heat Flux Measurement

  1. Introduction

  2. Important Issues

  3. Gauges Based on Spatial Temperature Difference

  4. Gauges Based on Temperature Change with Time

  5. Gauges Based on Active Heating Methods

  6. Calibration and Errors

  • References

Chapter 8: Furnaces

  1. Scope and Intent

  2. Standard Conditions

  3. Furnace Types

  4. Furnace Construction

  5. Fuels and Combustion

  6. Oxygen Enrichment of Combustion Air

  7. Thermal Properties of Materials

  8. Heat Transfer

  9. Fluid Flow

  10. Burner and Control Equipment

  11. Waste Heat Recovery Systems

  12. Furnace Components in Complex Thermal Processes

  13. Furnace Capacity

  14. Furnace Temperature Profiles

  15. Representative Heating Rates

  16. Selecting Number of Furnace Modules

  17. Furnace Economics

  • Reference

Chapter 9: Heat Exchangers, Vaporizers, and Condensers

  1. Heat Exchanger Types and Construction

  2. Estimation of Size and Cost

  3. Rating Methods

  4. Common Operational Problems

  5. Use of Computers in Thermal Design of Process Heat Exchangers

  • Nomenclature

  • References

Chapter 10: Heat Pipes

  1. Introduction

  2. Fundamentals

  3. Heat Transport Limitations

  4. Heat Pipe Fabrication Processes

  5. Other Types of Heat Pipes

  • Nomenclature

  • References

Chapter 11: Air Heating

  1. Air-Heating Processes

  2. Costs

  3. Warnings

  4. Benefits

  • References

Chapter 12: Cooling Electric Equipment

  1. Thermal Modeling

  2. Heat Transfer Correlations for Electronic Equipment Cooling

  3. Thermal Control Techniques

  • References

Chapter 13: Refrigeration

  1. Introduction

  2. Basic Principles

  3. Refrigeration Cycles and System Overview

  4. Refrigerants

  5. Absorption Systems

  6. Indirect Refrigeration

  7. System Components

  8. Defrost Methods

  9. System Design Considerations

  10. Refrigeration System Specification

  • References

Chapter 14: Cryogenic Engineering

  1. Introduction

  2. Properties of Cryogenic Fluids

  3. Cryogenic Properties of Materials

  4. Refrigeration and Liquefaction

  5. Cryocoolers

  6. Cryostat Design and Insulation

  7. Instrumentation

  8. Air Separation

  9. Safety

  10. Helium II

  11. Sub-Kelvin Cooling

  • References

Chapter 15: Indoor Environmental Control

  1. Indoor Environment Parameters

  2. Air-Handling Processes

  3. Thermal Comfort

  4. Indoor Air Quality

  5. Building Thermal Loads

  6. Computer Programs

  7. Equipment for Environmental Control

  • References

Chapter 16: Thermal Systems Optimization

  1. Introduction

  2. Optimization Toolbox

  3. Methodology

  4. Approximation-Assisted Optimization

  • References

  • Bibliography

Part 2: Power

Chapter 17: Combustion

  1. Fundamentals of Combustion

  2. Thermal Aspects of Combustion

  3. Flame Aerodynamics

  4. Firing Systems

  5. Pollutant Emissions

  6. Safety Considerations

  7. Oxy-Fuel Firing

  • Acknowledgments

  • References

Chapter 18: Gaseous Fuels

  1. Introduction

  2. Natural Gas

  3. Liquefied Petroleum Gases

  • References

Chapter 19: Liquid Fossil Fuels from Petroleum

  1. Introduction

  2. Fuel Oils

  3. Shale Oils

  4. Oils from Tar Sands

  5. Oil-Water Emulsions

  • References

Chapter 20: Coals, Lignite, and Peat

  1. Introduction

  2. Current Uses: Heat, Power, Steelmaking, Other

  3. Types

  4. Physical and Chemical Properties: Description and Tables of Selected Values

  5. Burning Characteristics

  6. Ash Characteristics

  7. Sampling

  8. Coal Cleaning

  • References

Chapter 21: Clean Power Generation from Coal

  1. Introduction

  2. Preconversion

  3. Coal Conversion and In Situ Pollution Control

  4. Postconversion Clean-Up

  5. Carbon Dioxide

  6. Conclusion

  • References

Chapter 22: Biofuels for Transportation

  1. Introduction

  2. Ethanol

  3. Biodiesel and Vegetable Oil

  4. Hydrogen

  5. Other Biofuels

  6. Closing Remarks

  • References

Chapter 23: Solar Energy Measurements

  1. Introduction

  2. Measurement Equipment

  3. Equipment Error and Uncertainty

  4. Operational Errors

  5. Diffuse Radiation Data Measurement Errors

  6. Types of Sensors and Their Accuracy

  7. Modern Developments

  8. Data Quality Assessment

  9. Statistical Evaluation of Models

  10. Outlier Analysis

  • References

Chapter 24: Geothermal Resources and Technology: Introduction

  1. Introduction

  2. Geothermal Resources

  3. Geothermal Energy Conversion

  • References

Chapter 25: Pumps, Fans, Blowers, and Compressors

  1. Liquid Movers: Pumps

  2. Gas Movers

  3. Thermodynamics of Gas Compression

  • References

  • Bibliography

Chapter 26: Gas Turbines

  1. Introduction

  2. Gas Turbine Performance

  3. Applications

  4. Evaluation and Selection

  • References

Chapter 27: Wind Power Generation

  1. Market and Economics

  2. Configurations

  3. Power Production and Energy Yield

  4. Rotor and Drive Train Design

  5. Site Selection

  • References

Chapter 28: Cogeneration

  1. Introduction

  2. Basic Cogeneration Systems

  3. Descriptions of Prime Movers

  4. Description of Other Equipment and Components

  5. Technical Design Issues

  6. Regulatory Considerations

  7. Economic Evaluations

  8. Ownership and Financial Arrangements

  9. Summary and Conclusions

  • References

Chapter 29: Hydrogen Energy

  1. Introduction

  2. Hydrogen Production

  3. Hydrogen Storage

  4. Hydrogen Utilization

  5. Hydrogen Safety

  6. Conclusions

  • References

Chapter 30: Steam Turbines

  1. Introduction

  2. Historical Evolution of Steam Turbines

  3. Turbine Stages

  4. Classification of Steam Turbines

  5. Steam Turbine Parameters and Performance

  6. Cogeneration and Combined-Cycle Plants

  7. Applications

  8. Other Related Topics

  • References

Chapter 31: Fuel Cells

  1. Introduction

  2. Basic Operating Principles, Efficiency, and Performance

  3. The Solid Oxide Fuel Cell

  • References

Chapter 32: Fluid Power Systems

  1. Introduction

  2. Symbols and Terminology

  3. System Components

  4. System Dynamic Behavior

  5. Common Nonlinearities

 

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