The Stirling cycle has been used very effectively in cryocoolers; but efficiencies relative to the Carnot limit are typically observed to peak for absolute temperature rations of about two, which makes it less suitable for low-lift refrigeration. The adiabatic loss appears to be responsible for poor performance at small temperature differences. In this paper, adiabatic losses are evaluated, for a temperature ratio of 2/3, taking into account the effect of phase angle between pistons, of volume ratio, of the distribution of the dead volume necessary of reduce the volume ration, and of the distribution of displacement between expansion and compression spaces. The study is carried out numerically, using an adiabatic stirling engine model in which cylinder flow is assumed to be stratified. Results show that the best location for the cylinder dead volume is on the compression side. Otherwise, all strategies used to trade off refrigeration for coefficient of performance are found to be roughly equivalent.

Issue Section:
Technical Papers
Topics:
Compression, Cycles, Cylinders, Displacement, Flow (Dynamics), Pistons, Refrigeration, Space, Stirling engines, Temperature, Tradeoffs
1.
Batchelor, G. K., 1967, Introduction to Fluid Dynamics, Cambridge University Press, Cambridge, U.K.
2.
Bauwens, L., 1993, “Stirling Engine Modeling: The MS*2 Code,” Proceedings, ISEC-93, pp. 371–376.
3.
Bauwens
L.
,
1995
a, “
Stirling Cryocooler Model with Stratified Cylinders and Quasisteady Heat Exchangers
,”
Journal of Thermophysics and Heat Transfer
, Vol.
9
, No.
1
, pp.
129
135
.
4.
Bauwens
L.
,
1995
b, “
A Stratified Flow Model for Adiabatic Losses in Regenerative Thermal Devices
,”
ASME JOURNAL OF ENERGY RESOURCES TECHNOLOGY
, Vol.
117
, pp.
150
155
.
5.
Bauwens
L.
,
1995
c, “
The Near-Isothermal Regenerator: A Perturbation Analysis
,”
Journal of Thermophysics and Heat Transfer
, Vol.
9
, No.
4
, pp.
749
756
.
6.
Bauwens, L., 1996, “Oscillating Flow of a Heat-Conducting Fluid in a Narrow Tube,” submitted to Journal of Fluid Mechanics.
7.
Berchowitz, D. M., 1986, “Stirling Cycle Engine Design and Optimization,” Ph.D. dissertation, University of Witwatersrand.
8.
Finkelstein, T., 1960, “Generalized Thermodynamic Analysis of Stirling Engines,” SAE Paper No. 118C.
9.
Gedeon, D. R., 1986, “A Globally Implicit Stirling Cycle Simulation,” Proceedings, 21st IECEC, pp. 550–56.
10.
Ko¨hler, J., 1965, “The Stirling Refrigeration Cycle,” Scientific American, Apr.
11.
Kornhauser
A. A.
, and
Smith
J. L.
,
1994
, “
Application of a Complex Nusselt Number to Heat Transfer during Compression and Expansion
,”
ASME Journal of Heat Transfer
, V
116
, pp.
536
542
.
12.
Reader, G. T., and Hooper, C., 1983, Stirling Engines, E & F.N. Spon, London.
13.
Romm
M. J.
, and
Smith
J. L.
,
1993
, “
Stirling Engine Loss in Dead Volumes Between Components
,”
Proceedings, 28th IECEC
, Vol.
2
, pp.
751
758
.
14.
Smith
J. L.
, and
Romm
M. J.
,
1992
, “
Thermodynamic Loss at Component Interfaces in Stirling Cycles
,”
Proceedings, 27th IECEC
, Vol.
5
, pp.
529
532
.
15.
Walker, G., 1973, Stirling Cycle Machines, Clarendon Press, Oxford, U.K.
16.
Walker, G., 1980, Stirling Engines, Clarendon Press, Oxford, U.K.
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