• Home page
  • Publications

  • Comparison between HFC-134a and alternative ref...

Comparison between HFC-134a and alternative refrigerants in mobile air conditioners using the GREEN-MAC-LCCP© model.

Number: pap. 2410



The transition from CFC-12 (GWP=10,900) to HFC-134a (GWP=1,430) in the 1990’s in new vehicle air conditioners eliminated the contribution to ozone depletion potential (ODP) from new vehicles and reduced the direct Global Warming Potential (GWP) by over 80%. One proposed alternative is HFC-1234yf (GWP=4). Despite the phase-in success of HFC-134a as a zero ODP automotive refrigerant it is still a potent greenhouse gas and the European Union (EU) issued Directive 2006/40/EC that prohibits the use of automotive refrigerants with GWP greater than 150, starting from January 1st, 2011. Due to such regulations, the automotive Original Equipment Manufacturers (OEMs), chemical manufacturers and Mobile Air Conditioning (MAC) industry have evaluated several alternative refrigerants considering a range of selection criteria that include: refrigerant engineering performance, system design impact, MAC system changes to optimize the use of new refrigerants, cost, flammability, and environmental impacts including global warming, and human toxicity risks. There has been remarkable success in eliminating refrigerant fluids that deplete the ozone layer, but many of their replacements have high GWP. There is now a major international effort for a third generation refrigerant fluids that are safe both for ozone depletion and climate protection. During 2013, the United States and China proposed phasing out high GWP HFCs that have been introduced to replace ODP substances through the provisions of the Montreal Protocol. Europe is currently debating between two alternative fluids for vehicle air conditioners, and the outcome is being watched closely. This paper will compare the alternatives. New MAC systems that meet the low GWP requirements of the EU Directive refrigerants should also be equally or more efficient than HFC-134a designs. Life Cycle Analysis (LCA) adds a step in the understanding of the dynamics of the industrial activities as a system and not as individual components, with implications for better policy decisions at the technological and environmental levels. The MAC industry and government recognized this need, and Life Cycle Climate Performance (LCCP) was accepted as one of the methods for selecting among alternative refrigerants. We consider and implement LCA for developing the Global Refrigerants Energy & Environmental-Mobile Air Conditioning-Life Cycle Climate Performance (GREEN-MAC-LCCP)© model which is the tool that evaluates the full cycle of Greenhouse Gas emissions (GHG) of alternative refrigerant systems. The goal of this tool is to provide a superior basis for engineers and policy makers to make wise decisions of alternative competing technologies. In this paper, we summarize the evolution of refrigerant fluids and how the world has arrived at the present point. The interplay between the evolution of technology and the regulatory system that governs it, the economic drivers and the environmental health and safety implications will be elucidated. We also provide a short overview of the model and the results obtained by evaluating alternative refrigerant MAC systems and compare them with the HFC-134a production baseline. Using GREEN-MAC-LCCP© we estimate the energy consumption and GHG of MACs that operate with HFC-134a and compare these results with new systems that operate with alternative refrigerants.

Available documents

Format PDF

Pages: 10 p.


  • Public price

    20 €

  • Member price*

    15 €

* Best rate depending on membership category (see the detailed benefits of individual and corporate memberships).


  • Original title: Comparison between HFC-134a and alternative refrigerants in mobile air conditioners using the GREEN-MAC-LCCP© model.
  • Record ID : 30013306
  • Languages: English
  • Source: 2014 Purdue Conferences. 15th International Refrigeration and Air-Conditioning Conference at Purdue.
  • Publication date: 2014/07/14


See other articles from the proceedings (203)
See the conference proceedings