Novel reduced GWP refrigerant compositions for stationary air conditioning.

Number: pap. 2505

Author(s) : LECK T., HUGHES J., NAICKER P., et al.

Summary

The working fluids most widely used for small and mid-sized air conditioning systems globally are R-410A and R-22. While these fluids have many positive attributes for cooling and heating, they are the subject of valid criticisms regarding their high direct global warming potential (GWP) and, in the case of R-22, ozone depletion potential (ODP) also. In the interest of improved environmental sustainability, a new class of refrigerant molecule has been developed, the hydrofluoroolefin, or HFO. While the very low direct GWP values of these molecules are attractive, none of the HFOs by themselves are fully satisfactory for use in conventional stationary AC system designs, for reasons of concern about low capacity and flammability. Blended refrigerant candidates have been developed to provide better overall safety and performance, while retaining significant environmental sustainability properties versus the legacy refrigerants. This paper discusses the considerations for designing viable refrigerant blends and the process for developing useful refrigerant compositions. There is as yet no universal agreement on what are the most critical properties for air conditioning fluids. Proposed legislation and industry discussions are proposing such features as high energy efficiency, low Life Cycle Climate Performance (LCCP), low direct GWP, performance to match current commercial fluids, non flammability, and more. No single candidate has yet been identified that meets every proposed requirement for a refrigerant fluid. This paper discusses three candidate fluids that have been developed to meet three of the most often cited sets of environmental, physical and performance properties for air conditioning (AC). Each of these candidate fluids possesses desirable, but different sets of properties. The trade-offs and relative performance and environmental merits of each will be discussed. The three fluids vary in direct GWP values, flammability, capacity, and critical temperature. As these fluids are not yet commercial, they will be designated by laboratory identification DR codes that are being used in the AHRI (American Heating and Refrigeration Institute) AREP (Alternative Refrigerant Evaluation Program). One is a 2L flammable gas that gives capacity performance near that of R-410A, designated DR-5A. One is a nonflammable composition for use to replace R-22 in high ambient temperature environments, designated DR-91. The third is a 2L flammable replacement for R-22 with a direct GWP of less than 150, designated DR-3. In designing and evaluating these new compositions, the trade-offs that exist between refrigeration capacity, efficiency (COP), temperature glide, GWP value, and flammability have been explored and assessed. We report on some comparisons of these compositions in AC measurement and modeling work. The new compositions have been evaluated with thermodynamic refrigeration cycle models at standard AC conditions, and at high ambient temperature operating conditions, and show good performance. Testing is underway to evaluate performance of these new compositions in laboratory equipment and in actual operating systems, as compared to R-410A or R-22 performance in the same or similar systems. The status of the testing will be reported in this paper. These new.compositions should provide useful options to help maintain the quality of life and health benefits that accrue from air conditioning and refrigeration, but in an energy efficient and environmentally sustainable manner.

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Pages: 9 p.

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Details

  • Original title: Novel reduced GWP refrigerant compositions for stationary air conditioning.
  • Record ID : 30012967
  • Languages: English
  • Source: 2014 Purdue Conferences. 15th International Refrigeration and Air-Conditioning Conference at Purdue.
  • Publication date: 2014/07/14

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