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Summary
Summary
Publisher's Note: Products purchased from Third Party sellers are not guaranteed by the publisher for quality, authenticity, or access to any online entitlements included with the product. A practical, illustrated guide to thermal science
A practical, illustrated guide to thermal scienceWritten by a subject-matter expert with many years of academic and industrial experience, Thermal Science provides detailed yet concise coverage of thermodynamics, fluid mechanics, and heat transfer. The laws of thermodynamics are discussed with emphasis on their real-world applications.
This comprehensive resource clearly presents the flow-governing equations of fluid mechanics, including those of mass, linear momentum, and energy conservation. Flow behavior through turbomachinery components is also addressed. The three modes of heat transfer--conduction, convection, and radiation--are described along with practical applications of each.
Thermal Science covers:
Properties of pure substances and ideal gases First and second laws of thermodynamics Energy conversion by cycles Power-absorbing cycles Gas power cycles Flow-governing equations External and internal flow structures Rotating machinery fluid mechanics Variable-geometry turbomachinery stages Prandtl-Meyer flow Internal flow, friction, and pressure drop Fanno flow process for a viscous flow field Rayleigh flow Heat conduction and convection Heat exchangers Transfer by radiationInstructor material available for download fromcompanion website
Author Notes
Erian A. Baskharone, Ph.D., is a Professor Emeritus of Mechanical and Aerospace Engineering at Texas A&M University, and a member of the Rotordynamics/Turbomachinery Laboratory Faculty. He is a member of the ASME Turbomachinery Executive Committee. After receiving his Ph.D. degree from the University of Cincinnati, Dr. Baskharone became a Senior Engineer with Allied-Signal Corporation (currently Honeywell Aerospace Corporation), responsible for the aerodynamic design of various turbofan and turboprop engines. His research covered a wide spectrum of turbomachinery topics, including unsteady stator/rotor flow interaction, and the fluid-induced vibration problem in the Space Shuttle Main Engine. Dr. Baskharone's perturbation approach to the problem of turbomachinery fluid-induced vibration was a significant breakthrough. He is the recipient of the General Dynamics Award of Excellence in Engineering Teaching (1991) and the Amoco Foundation Award for Distinguished Teaching (1992).
Table of Contents
| Part 1 Thermodynamics |
| Ch 1 Foreword |
| Ch 2 Definitions |
| Ch 3 Properties of Pure Substances |
| Ch 4 Properties of Ideal Gases |
| Ch 6 Energy Conversion By Cycles |
| Ch 7 Gas Power Cycles |
| Part II Fluid Mechanics |
| Ch 8 Flow-Governing Equations |
| Ch 9 Sonic Speed in Ideal Gases |
| Ch 10 Introduction of the Critical Mach Number |
| Ch 11 Continuity in Terms of the Critical Mach Number |
| Ch 12 Isentropic Flow Through Varying-Area Passages |
| Ch 13 Rotating Machinery Fluid Mechanics |
| Ch 14 Velocity Diagrams |
| Ch 15 Cross-Flow Area Variation |
| Ch 16 Supersonic Stator Cascade |
| Ch 17 Normal Shocks |
| Ch 18 Fanno Flow Process for a Viscous Flow Field |
| Ch 19 Rayleigh Flow |
| Ch 20 Dynamic Similarity (Similitude) Theory |
| Ch 21 Radial Equilibrium Theory |
| Part III heat transfer |
| Ch 22 Introduction |
| Ch 23 Heat Conduction |
| Ch 24 Heat Convection |
| Ch 25 Lumped Parameter Analysis |
| Ch 26 Heat Transfer By Radiation |
| Appendix A Analysis |
| Appendix B Charts and Tables |
