Thermoeconomic performance optimization of an orifice pulse tube refrigerator

Abstract

The thermodynamic process parameters such as cooling capacity and percentage Carnot efficiency of an orifice pulse tube refrigerator are maximized using a novel hybrid statistical simulation approach. With the help of a one-dimensional numerical model, the inside gas flow and thermal processes responsible for the production of cooling effect inside the tube have been solved. Subsequently, the thermodynamic process parameters are calculated as a function of input geometrical parameters of the regenerator, pulse tube, and orifice valve. Response surface methodology is thereupon applied to investigate the influence of input factors on outputs. Desirability method is finally adopted to maximize both cooling capacity and percentage Carnot efficiency. A sensitivity investigation has been undertaken to find out the degree of influence of each input on the output. An experimental investigation has been conducted at the optimal set of parameters so as to validate the proposed methodology. The investigation shows that, there exists an almost linear relationship among the geometrical parameters of the pulse tube on outputs, and a nonlinear quadratic relationship among the geometrical parameters of regenerator on outputs. Finally, possible combination of input parameters have been generated by the model at which both the outputs are maximum.

Nomenclature
A	=	fluid flow area, m2
As	=	solid/matrix area, m2
AL	=	wetted perimeter, m
Cf	=	friction factor
cv	=	specific heat at constant volume, J/kg-K
CV	=	orifice valve opening coefficient
cp	=	specific heat at constant pressure, J/kg-K
cs	=	specific heat of solid/matrix, J/kg-K
dh	=	characteristic diameter, m
f	=	cold head frequency, Hz
h	=	heat transfer coefficient, W/m2-K
$H$	=	cycle average enthalpy flow, J/sec
k	=	fluid thermal conductivity, W/m-K
ks	=	solid/matrix thermal conductivity, W/m-K
$\dot{m}$	=	mass flow rate, kg/s
P	=	pressure, Pa
t	=	time, s
T	=	fluid temperature, K
TS	=	solid/matrix temperature, K
u	=	fluid velocity, m/s
V	=	volume, m3
Wc	=	compressor input work, W
x	=	axial co-ordinate

Greek symbol
$\rho$	=	density of gas, kg/m3
τ	=	period, s

Subscript
c	=	compressor
o	=	orifice valve
res	=	reservoir

Acronyms
ANOVA	=	analysis of variance
BBD	=	Box–Benhken design
CHX	=	cold heat exchanger
COP	=	coefficient of performance
DIPTR	=	double inlet pulse tube refrigerator
DV	=	double inlet valve
GM	=	Gifford–McMahon
HHX	=	hot heat exchanger
HPV	=	high pressure valve
LPV	=	low pressure valve
OPTR	=	orifice pulse tube refrigerator
OV	=	orifice valve
PT	=	pulse tube
PTR	=	pulse tube refrigerator
REGN	=	regenerator
RES	=	reservoir
RSM	=	response surface methodology
RV	=	rotary valve

Acknowledgments

Authors are thankful to Mr. Somnath Das for providing some useful suggestions during fabrication of components and leak detection. Mr. Tiga is also acknowledged for providing constructive suggestions during brazing and TIG welding process of components. Mr. S. Pani is acknowledged for his help during assembly.

Additional information

Funding

Financial assistance received from MHRD, Govt. of India to Mr. Debashis Panda is gratefully acknowledged.