Abstract
The use of hydrofluorocarbons (HFCs) as an alternative for refrigeration units has grown over the past decades as a replacement to chlorofluorocarbons (CFCs), banned by the Montreal’s Protocol because of their effect on the depletion of the ozone layer. However, HFCs are known to be greenhouse gases with considerable global warming potential (GWP), thousands of times higher than carbon dioxide. The Kigali Amendment to the Montreal Protocol has promoted an active area of research toward the development of low GWP refrigerants to replace the ones in current use, and it is expected to significantly contribute to the Paris Agreement by avoiding nearly half a degree Celsius of temperature increase by the end of this century. We present here a molecular-based evaluation tool aiming at finding optimal refrigerants with the requirements imposed by current environmental legislations in order to mitigate their impact on climate change. The proposed approach relies on the robust polar soft-SAFT equation of state to predict thermodynamic properties required for their technical evaluation at conditions relevant for cooling applications. Additionally, the thermodynamic model integrated with technical criteria enable the search for compatibility of currently used third generation compounds with more eco-friendly refrigerants as drop-in replacements. The criteria include volumetric cooling capacity, coefficient of performance, and other physicochemical properties with direct impact on the technical performance of the cooling cycle. As such, R1123, R1224yd(Z), R1234ze(E), and R1225ye(Z) demonstrate high aptitude toward replacing R134a, R32, R152a, and R245fa with minimal retrofitting to the existing system. The current modeling platform for the rapid screening of emerging refrigerants offers a guide for future efforts on the design of alternative working fluids.
Highlights
Within the context of sustainable development, climate action is one of the vital topics in the United Nations’ (UN) goals for sustainable future, focusing on increased awareness and mobilization to resist the adverse ecological effects of climate change.[1]
The optimized polar soft-statistical associating fluid theory (SAFT) parameters for the examined pure refrigerants are provided in Table 2, using the parametrization approach highlighted in the methodology section
This limitation is shared by all SAFT-based equations of state (EoSs) and can be solved through the addition of the crossover term,[88] which is outside the scope of this work
Summary
Within the context of sustainable development, climate action is one of the vital topics in the United Nations’ (UN) goals for sustainable future, focusing on increased awareness and mobilization to resist the adverse ecological effects of climate change.[1]. CleOg2isleamtioisnssio5−n9s were passed to gradually phase out and restrict the usage of third generation refrigerants in upcoming years, targeting replacements with low GWP. In lieu of the current targets of environmental legislations, the search for alternative refrigerants replacing HFCs for today’s market is solely dictated by eco-friendly properties such as zero ODP, low GWP, and moderate safety-related properties (i.e., flammability, and toxicity), examining a wide array of Received: September 1, 2021 Revised: November 23, 2021 Published: December 7, 2021
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