A universal mass flowrate correlation for refrigerants and refrigerant/oil mixtures flowing through short tube orifices /

Data taken at the Energy Systems Laboratory for the flow of

Bibliographic Details
Main Author: Payne, William Vance, 1968-
Format: Thesis Book
Language:English
Published: [Place of publication not identified] : [publisher not identified] ; 1997.
Subjects:
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Description
Summary:Data taken at the Energy Systems Laboratory for the flow of
pure refrigerants and refrigerant/oil mixtures through short
tube orifices were combined with additional data taken during
this work to produce a universal correlation capable of
predicting the critical mass flowrate. This correlation
included two-phase and single-phase flow of both pure and oil
mixed refrigerants through sharp edged short tubes with
length to diameter ratios ranging from 6.55 to 23.15. The
data represented flow conditions that are typically seen in
air-conditioning and heat pump applications. The
refrigerants used in the correlation included R- 12, R- 134a,
R-502, R-22, R-407c, and R-410a. The correlation was
developed using the Buckingham Pi theorem to generate several
non-dimensional parameters. Necessary refrigerant properties
were saturated liquid and vapor densities, saturated liquid
viscosity, enthalpy of vaporization, critical pressure,
critical temperature, and saturation pressure as a function
of temperature. The length and diameter of the sharp edged
orifice were also necessary for the correlation. Necessary
quantities for the oil effects correlation included the mass
fraction of oil, mole fraction of oil, molecular weight of
the refrigerant, molecular weight of the oil, short tube
length, and short tube diameter. Using this information
and knowledge of the orifice upstream pressure,
upstream temperature, and/or quality allows the prediction of
mass flowrate. The main advantage of this correlation was
that it provided a closed form equation capable of predicting
mass flowrate for both two-phase and single-phase flow with
the inclusion of oil mixture effects. For single-phase
conditions at the short tube entrance, the correlation
predicted the flowrate with an average percent difference of
4.3% of the reading with a maximum difference of 24% and chi-
squared of 9.09. Two-phase short tube conditions produced
predictions with an average percent difference of 4.5% of the
measured value with a maximum difference of 23% and chi-
squared of 5.96. The smaller amount of oil mixture data
limited the scope of the oil effects model, but data was
correlated to produce an average percent difference of 3.9%
with a maximum difference of 26% and chi-squared of 8.45.
Item Description:Vita.
"Major Subject: Mechanical Engineering".
Physical Description:xx, 222 leaves : illustrations ; 28 cm.
Issued also on microfiche from University Microfilms Inc.
Bibliography:Includes bibliographical references: pages 209-214.