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Experimental study of zeotropic refrigerant mixture HFC-407C as a replacement for HCFC-22 in refrigeration and air-conditioning systems

HCFC-22 is the world�s most widely used refrigerant. It serves in both residential and
commercial applications, from small window units to large water chillers, and
everything in between. Its particular combination of efficiency, capacity and pressure
has made it a popular choice for equipment designers. Nevertheless, it does have some
ODP, so international law set forth in the Montreal Protocol and its Copenhagen and
Vienna amendments have put HCFC-22 on a phase out schedule. In developed
countries, production of HCFC-22 will end no later than the year 2030.
Zeotropic blend HFC-407C has been established as a drop-in alternative for HCFC-22
in the industry due to their zero Ozone Depletion Potential (ODP) and similarities in
thermodynamic properties and performance. However, when a system is charged with a
zeotropic mixture, it raises concerns about temperature glide at two-phase state,
differential oil solubility and internal composition shift.
Not enough research has been done to cover all aspects of alternative refrigerants
applications in the systems. This research intended to explore behavior of this
alternative refrigerants compare to HCFC-22 and challenges facing the industry in
design, operation service and maintenance of these equipments.
The purpose of this research is to investigate behavior of R407C refrigerant in chiller
systems. This includes performance and efficiency variations when it replaces R22 in an
existing system as well as challenges involved maintaining the system charged with
R407C. It is a common practice in the industry these days to evacuate and completely
recharge when part of the new refrigerant blend was leaked from the system. This has
proved to be extremely costly exercise with grave environmental ramifications.
This research is intended to address challenges faced in the real world and practical
terms.
Theoretical and experimental approaches used as a methodology in this work. The
system mathematically modeled to predict detailed system performance and effect of
the leak at various conditions. To make this feasible and accurate enough, two separate
approaches made, first system performance for pure R22 and R407C, and second
system subjected to range of leak fractions. The earlier model was relatively straight
forward when compared to the latter. Modeling a system charged with R407C ternary
mixture and subjected to range of leaks posed enormous challenges.
A sophisticated experimental test apparatus was also designed and built. Comprehensive
and detailed tests at various conditions were conducted with special attention on
instrumental accuracy and correct methodology.
The first part has been successfully modeled and predicted all the factors and
performance with excellent accuracy when compared to the test results. In these
approaches pure refrigerants R22 and R407C were used and simulated the system
behavior at range of conditions.
However, the second part was the most challenging ever. Comprehensive leak process
simulations produced trends of R32/R125/R134a composition change as function of rate
of leak. Starting from this point, equations have been created to represent the
composition change as function of percentage of the leak. The system thermodynamic
cycle was also modeled to calculate capacity, power input and COP at the range of the
conditions. Despite many affecting parameters and complexity of the model, the
mathematical model successfully predicted the test outcome with a very reasonable
accuracy, averaging around 3% with some times reaching to 5 to 6%.
On the experimental stage the system charged with the new HFC-407C was deliberately
subjected to refrigerant leak at various leak stages. The aim was to objectively
determine to what extend the gas leak can be still acceptable without going through the
expensive complete gas charge. The effect of leak was tested and verified at 10% steps,
from 10% up to 50% mass fraction for the total charge.
It has been observed that at the leaks beyond 30%, the adverse effect on the capacity
becomes more significant, from 8 to about 15% decrease. While the power input
decreased at slower pace, from 3% up to about 8% depending on the test conditions.
This translated to COP decrease ranging from 4 to about 7%. This capacity loss and
efficiency decrease are significant figures which suggests that the system, here chiller,
can not be allowed to degrade the performance to that extend and still continue
operating.

Identiferoai:union.ndltd.org:ADTP/216628
Date January 2006
CreatorsMirza-Tolouee, Changiz M., n/a
PublisherSwinburne University of Technology.
Source SetsAustraliasian Digital Theses Program
LanguageEnglish
Detected LanguageEnglish
Rightshttp://www.swin.edu.au/), Copyright Changiz M. Mirza-Tolouee

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