evaluation of alternatives to r404 · 2017. 6. 2. · alternatives to r404 –the most common...
TRANSCRIPT
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Research Institutes of Sweden
EVALUATION OF ALTERNATIVES TO R404– THE MOST COMMON REFRIGERANT IN SWEDISH GROCERY STORES
Markus Lindahl
May 2017
Built EnvironmentEnergy and Circular Economy
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§ Background§ Scope§ Method§ Results§ Conclusions
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Presentation outline
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§ Today R404A is the most commonly used refrigerant in Swedish grocery stores.
§ R404A is an HFC refrigerant with a high GWP and is covered by EU’s F-Gas Regulation, § The F-Gas Regulation entered into force on 1 January 2015.
§ The aim of the new F-Gas Regulation is to reduce the climate impact of refrigerants § Guide the market towards refrigerants and system solutions with
lower Global Warming Potential (GWP).
§ There are refrigerants that are not covered by the F-Gas Regulation and therefore suitable alternatives to R404A§ Some of these are: HFO, carbon dioxide, ammonia and
hydrocarbons
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Background
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The scope of this study was to define:
§ The investment cost§ Assuming an existing R404A-system today
§ The operating cost
of a few types of freezing systems with other refrigerants than R404A.
§ Make an economic evaluation of the different alternatives
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Scope of the study
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§ Only freezing systems were analyzed.
§ Energy consumption was estimated using a theoretical model based on other models and experiences of the project participants, as well as expertise in the area.
§ The annual cost was only based on the energy consumption of refrigeration systems and not on maintenance costs etc.
§ Optimized condensing and evaporating temperatures were assumed which resulted in optimized operation of the freezer system.
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Limitations
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Investigated alternatives to R404A
HFC HFC HFC-HFO Hydro-carbonCarbon Dioxide
R404A R407F R448A Propane R290 R744
GWP 3922 1824 1273 3 1
Flammability Non flammableNon
flammableNon
flammable FlammableNon
flammableCan replace R404A in existing systems
- Yes (Yes) No No
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Construction of theoretical model:§ Grocery store (Reference store in Borås, Sweden)
§ Climate data (Meteonorm)§ Indoor climate is based on outdoor temperature and humidity
§ Freezers (with and without lids), maximum cooling load: 23kW
§ Auxiliary systems in the freezers (fans, defrost function, lighting and anti-fog function)
§ Refrigerant choice§ Compressor set up and dimensioning (Bitzer software)§ Indirect/direct system (dependent on refrigerant)
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Method- Annual energy use of the freezer system
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Costs:
§ Assumed electricity cost: 1 SEK/kWh ≈ 0.1 Euro/kWh
§ Installation costs based on information from supplier of relevant equipment
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Method- Annual energy use of the freezer system
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50000
100000
150000
200000
250000
R404ADX(reference)
R407FDX R448ADX R290 CO2DX
(kWh/yr)
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Result- Energy Use (kWh/yr)
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20000
40000
60000
80000
100000
120000
R407FDX R448ADX R290 CO2DX
Euro
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Result- Cost of installation (Euro)
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§ Deprecation time 10 yr
§ Cost of capital 3%
Result- Present value - Deprecation time 10yr (Euro)
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50000
100000
150000
200000
250000
300000
R404ADX(reference)
R407FDX R448ADX R290 CO2DX
Euro
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§ Energy use will be reduced with all alternative refrigerant systems compared to R404A.
§ R407F and R448A are on short turn basis the best alternatives.§ However they are likely to be phased out just as with R404A, just
a few years later.
§ For newer facilities where you want to keep the existing cooling system, drop-in refrigerants may be economic feasible alternatives.
§ R290 (propane) and R774 (CO2) will thanks to their low GWP not be affected by the F-Gas Regulation§ They are the most viable long-term options.§ A larger investment is needed compared to the other two options.
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Conclusions
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Research Institutes of Sweden
THANK YOU!Markus Lindahl
+46 (0)1o-516 5529
Ola Gustafsson
+46 (0)1o-516 5120
Built EnvironmentEnergy and Circular Economy