Book contents
- Frontmatter
- Contents
- Preface
- 1 Energy Transfers in Cyclic Heat Engines
- 2 Mechanism Effectiveness and Mechanical Efficiency
- 3 General Efficiency Limits
- 4 Compression Ratio and Shaft Work
- 5 Pressurization Effects
- 6 Charge Effects in Ideal Stirling Engines
- 7 Crossley–Stirling Engines
- 8 Generalized Engine Cycles and Variable Buffer Pressure
- 9 Multi-Workspace Engines and Heat Pumps
- 10 Optimum Stirling Engine Geometry
- 11 Heat Transfer Effects
- Appendix A General Theory of Machines, Effectiveness, and Efficiency
- Appendix B An Ultra Low Temperature Differential Stirling Engine
- Appendix C Derivation of Schmidt Gamma Equations
- References
- Index
2 - Mechanism Effectiveness and Mechanical Efficiency
Published online by Cambridge University Press: 15 October 2009
- Frontmatter
- Contents
- Preface
- 1 Energy Transfers in Cyclic Heat Engines
- 2 Mechanism Effectiveness and Mechanical Efficiency
- 3 General Efficiency Limits
- 4 Compression Ratio and Shaft Work
- 5 Pressurization Effects
- 6 Charge Effects in Ideal Stirling Engines
- 7 Crossley–Stirling Engines
- 8 Generalized Engine Cycles and Variable Buffer Pressure
- 9 Multi-Workspace Engines and Heat Pumps
- 10 Optimum Stirling Engine Geometry
- 11 Heat Transfer Effects
- Appendix A General Theory of Machines, Effectiveness, and Efficiency
- Appendix B An Ultra Low Temperature Differential Stirling Engine
- Appendix C Derivation of Schmidt Gamma Equations
- References
- Index
Summary
In a cyclic heat engine, the mechanism plays a key and complicated role. Its main objective is to transport energy from the working substance to the output shaft. But it also functions to constrain and effect the movement of the piston in order that it carry out a certain thermodynamic cycle. This requires that the mechanism work in a bidirectional fashion. It must transport work from the piston to the flywheel and output shaft during some parts of the cycle, and from the flywheel to the piston in other parts. In practice, it is sometimes even more complex. For example, just after dead center in some engines, both the piston and the flywheel supply work to the mechanism, which is consumed by friction.
For analytic treatment, a comprehensive model of machines that reflects in detail all of the modes in which a mechanism is called upon to function in an engine is the natural first thought. However, such a model quickly becomes exceedingly complex, as the development in Appendix A shows. Rather, the main text of this monograph employs only very basic principles and examines best possible cases. As will be seen as the chapters unfold, a surprising number of interesting and practical insights about ultimate engine performance can be easily deduced through this simple approach.
- Type
- Chapter
- Information
- Mechanical Efficiency of Heat Engines , pp. 12 - 19Publisher: Cambridge University PressPrint publication year: 2007