Hot air engine

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Illustration of a low temperature differential (LTD) hot air engine. 1. Power piston, 2. Cold end of cylinder, 3.Displacer piston 4. Hot end of cylinder Q1. Heat in , Q2. Heat out.

Hot air engine (historically simply 'air engine' or 'caloric engine'^[1]) is a catch-all term for any heat engine which uses the expansion and contraction of air under the influence of a temperature change to convert thermal energy into mechanical work. These engines may be based on a number of thermodynamic cycles encompassing both open cycle devices such as those of Sir George Cayley and John Ericsson and the closed cycle engine of Robert Stirling.

In a typical implementation, air is repeatedly heated and cooled in a cylinder and the resulting expansion and contraction is used to move a piston and produce useful mechanical work. ^[2]

1 Exclusions
2 History
3 Thermodynamic cycles
4 See also
5 References
- 5.1 More references
6 External links

[edit] Exclusions

Though, as noted above, the term hot air engine may refer to many different devices, it specifically excludes any engine performing a thermodynamic cycle such as the Rankine cycle, in which the working fluid undergoes a phase change. Also excluded are conventional internal combustion engines in which heat is added to the working fluid by combustion of fuel within the working cylinder. Continuous combustion types such as George Brayton's Ready Motor and the related gas turbine could be seen as borderline cases.

[edit] History

The expansive property of heated air was known to the ancients and Hero of Alexandria's Pneumatica contains descriptions of devices which might be used to automatically open temple doors when a fire was lit on a sacrificial altar. Devices called hot air engines, or simply 'air engines', have been recorded from as early as 1699^{[citation needed]}, around the time when the laws of gasses were first set out, and early patents include those of Henry Wood, Vicar of High Ercall near Coalbrookdale Shropshire (English patent 739 of 1759) and Thomas Mead, an engineer from Sculcoats Yorkshire (English patent 979 of 1791) ^[3], the latter in particular containing the essential elements of a displacer type engine (Mead termed it the transferrer). It is unlikely that either of these patents resulted in an actual engine and the earliest workable example was probably the open cycle furnace gas engine of the English inventor Sir George Cayley c.1807 ^[4] ^[5]

It is likely that Robert Stirling's air engine of 1818 which incorporated his innovative Economiser patented in 1816 was the first to be put to practical work^[6]. The economiser, now known as the regenerator, stored heat from the hot portion of the engine as the air passed to the cold side, and released heat to the cooled air as it returned to the hot side. This innovation improved the efficiency of Stirling's engine and should be present in any air engine that is properly called a Stirling engine.

[edit] Thermodynamic cycles

Main article: Thermodynamic cycle

A hot air engine thermodynamic cycle can (ideally) be made out of 3 or more processes (typical 4). The processes can be any of these:

isothermal process (at constant temperature, maintained with heat added or removed from a heat source or sink)
isobaric process (at constant pressure)
isometric / isochoric process (at constant volume)
adiabatic process (no heat is added or removed from the working fluid)
- isentropic process, reversible adiabatic process (no heat is added or removed from the working fluid - and the entropy is constant)
isenthalpic process (the enthalpy is constant)

Some examples are as follows:

Cycle\Process	Compression	Heat Addition	Expansion	Heat Rejection
Power cycles with external combustion - or heat pump cycles
Brayton	adiabatic	isobaric	adiabatic	isobaric
Bell Coleman (Reverse Brayton)	adiabatic	isobaric	adiabatic	isobaric
Carnot	isentropic	isothermal	isentropic	isothermal
Stoddard	adiabatic	isometric	adiabatic	isometric
Stirling	isothermal	isometric	isothermal	isometric
Ericsson	isothermal	isobaric	isothermal	isobaric

Yet another example is Vuilleumier refrigeration. ^[7]

[edit] See also

[edit] References

^ Robert Sier (1999). Hot air caloric and stirling engines. Vol.1, A history, 1st Edition (Revised), L.A. Mair. ISBN 0-9526417-0-4.
^ Stirling (or Hot air) engine
^ Robert Sier (1999). Hot air caloric and stirling engines. Vol.1, A history, page 56, 1st Edition (Revised), L.A. Mair. ISBN 0-9526417-0-4.
^ Stirling engine history
^ Detailed contents of the book Hot air caloric and stirling engines. Vol.1, A history
^ Finkelstein, T and Organ, A.J (2001). Chapter 2.2 Air Engines. Professional Engineering Publishing. ISBN 1 86058 338 5.
^ Wurm, Jaroslav (1991). Stirling and Vuilleumier heat pumps: design and applications. McGraw-Hill. ISBN 0-07-053567-1.

[edit] More references

v • d • e

Thermodynamic cycles

Cycles normally with
external combustion

Gas cycles without phasechange - hot air engine cycles	Bell Coleman cycle · Brayton/Joule cycle; (Externally heated) · Carnot cycle · Ericsson cycle · Ported constant volume cycle[1] · Stirling cycle · Pseudo Stirling cycle (same as Adiabatic Stirling cycle) · Stoddard cycle · Vuilleumier cycle

Cycles with phasechange	Kalina cycle · Rankine cycle (encompasses Organic Rankine Cycle) · Regenerative cycle · Two phased Stirling cycle[2]

Cycles normally with
internal combustion

Atkinson cycle · Brayton/Joule cycle · Diesel cycle · Homogeneous Charge Compression Ignition · Lenoir cycle · Miller cycle · Otto cycle

Cycle mixing

Combined cycle · HEHC cycle · Mixed/Dual Cycle

Not categorized

Claude cycle [3] · Fickett-Jacobs cycle · Gifford-McMahon cycle [4] · Hirn cycle · Humphrey cycle · Linde-Hampson cycle

v • d • e

Heat engines

Stroke cycles

One · Two · Four · Six

Engine types

Gas turbine · Piston · Jet · Rocket engine · Steam engine · Stirling engine

Tschudi · Twingle

Rotary · Wankel · Free-piston · Britalus · Coomber · Swing-piston · Orbital · Quasiturbine