Composição:
100% 2,2-dicloro 1,1,1-trifluoroetano (CF3CHCl2)
Aplicativo:
Chillers centrífugos grandes e de baixa pressão
Desempenho:
Pode exigir a substituição de vedações, juntas e outros componentes para
obter as condições operacionais corretas e evitar vazamentos
Lubrificante:
Compatível com óleo mineral e alquilbenzeno
Propriedades Termodinâmicas
TEMP. (˚F) | Líquido de Pressão (psia) | Líquido de densidade (lb/ftˆ3) | Vapor de densidade (lb/ftˆ3) | Entalpia Líquida (Btu/lb) | Entalpia Vapor (Btu/lb) | Líquido de Entropia (Btu/R-lb) | Vapor de entropia (Btu/R-lb) |
|---|---|---|---|---|---|---|---|
-20 | 1.0 | 99.54 | 0.03413 | 4.558 | 87.35 | 0.01061 | 0.1989 |
-15 | 1.2 | 99.14 | 0.03978 | 5.706 | 88.05 | 0.01320 | 0.1984 |
-10 | 1.4 | 98.73 | 0.04618 | 6.857 | 88.75 | 0.01578 | 0.1979 |
-5 | 1.7 | 98.33 | 0.05339 | 8.012 | 89.46 | 0.01833 | 0.1975 |
0 | 2.0 | 97.92 | 0.06149 | 9.170 | 90.16 | 0.02086 | 0.1971 |
5 | 2.3 | 97.51 | 0.07055 | 10.33 | 90.87 | 0.02337 | 0.1967 |
10 | 2.6 | 97.10 | 0.08067 | 11.50 | 91.58 | 0.02587 | 0.1964 |
15 | 3.0 | 96.69 | 0.09192 | 12.67 | 92.29 | 0.02834 | 0.1961 |
20 | 3.5 | 96.28 | 0.1044 | 13.84 | 93.01 | 0.03080 | 0.1958 |
25 | 4.0 | 95.86 | 0.1182 | 15.02 | 93.72 | 0.03324 | 0.1956 |
30 | 4.5 | 95.44 | 0.1334 | 16.20 | 94.44 | 0.03566 | 0.1954 |
35 | 5.1 | 95.02 | 0.1502 | 17.38 | 95.16 | 0.03806 | 0.1953 |
40 | 5.8 | 94.60 | 0.1686 | 18.57 | 95.88 | 0.04045 | 0.1952 |
45 | 6.5 | 94.17 | 0.1887 | 19.76 | 96.60 | 0.04282 | 0.1951 |
50 | 7.3 | 93.74 | 0.2106 | 20.96 | 97.32 | 0.04518 | 0.1950 |
55 | 8.2 | 93.31 | 0.2346 | 22.16 | 98.04 | 0.04752 | 0.1950 |
60 | 9.2 | 92.88 | 0.2606 | 23.36 | 98.76 | 0.04984 | 0.1949 |
65 | 10.3 | 92.44 | 0.2889 | 24.57 | 99.48 | 0.05215 | 0.1949 |
70 | 11.4 | 92.01 | 0.3195 | 25.78 | 100.2 | 0.05444 | 0.1949 |
75 | 12.7 | 91.56 | 0.3526 | 27.00 | 100.9 | 0.05673 | 0.1950 |
80 | 14.1 | 91.12 | 0.3883 | 28.22 | 101.6 | 0.05899 | 0.1950 |
85 | 15.6 | 90.67 | 0.4268 | 29.44 | 102.4 | 0.06124 | 0.1951 |
90 | 17.2 | 90.22 | 0.4682 | 30.67 | 103.1 | 0.06348 | 0.1952 |
95 | 18.9 | 89.77 | 0.5128 | 31.90 | 103.8 | 0.06571 | 0.1953 |
100 | 20.8 | 89.31 | 0.5605 | 33.14 | 104.5 | 0.06792 | 0.1955 |
105 | 22.8 | 88.85 | 0.6117 | 34.38 | 105.2 | 0.07012 | 0.1956 |
110 | 25.0 | 88.39 | 0.6664 | 35.63 | 106.0 | 0.07231 | 0.1958 |
115 | 27.3 | 87.92 | 0.7249 | 36.88 | 106.7 | 0.07449 | 0.1959 |
120 | 29.8 | 87.45 | 0.7874 | 38.13 | 107.4 | 0.07665 | 0.1961 |
125 | 32.4 | 86.98 | 0.8540 | 39.39 | 108.1 | 0.07881 | 0.1963 |
130 | 35.3 | 86.50 | 0.9249 | 40.66 | 108.8 | 0.08095 | 0.1965 |
135 | 38.3 | 86.01 | 1.000 | 41.93 | 109.5 | 0.08308 | 0.1967 |
140 | 41.5 | 85.52 | 1.081 | 43.20 | 110.2 | 0.08520 | 0.1969 |
145 | 44.9 | 85.03 | 1.166 | 44.48 | 110.9 | 0.08732 | 0.1972 |
150 | 48.5 | 84.53 | 1.256 | 45.76 | 111.6 | 0.08942 | 0.1974 |
155 | 52.3 | 84.03 | 1.353 | 47.05 | 112.3 | 0.09151 | 0.1976 |
160 | 56.4 | 83.52 | 1.454 | 48.35 | 113.0 | 0.09359 | 0.1979 |
165 | 60.7 | 83.01 | 1.562 | 49.65 | 113.7 | 0.09567 | 0.1981 |
170 | 65.2 | 82.49 | 1.676 | 50.95 | 114.3 | 0.09773 | 0.1984 |
175 | 70.0 | 81.96 | 1.797 | 52.27 | 115.0 | 0.09979 | 0.1987 |
180 | 75.0 | 81.43 | 1.925 | 53.58 | 115.7 | 0.1018 | 0.1989 |
185 | 80.3 | 80.89 | 2.060 | 54.91 | 116.3 | 0.1039 | 0.1992 |
190 | 85.9 | 80.34 | 2.203 | 56.24 | 117.0 | 0.1059 | 0.1995 |
195 | 91.7 | 79.79 | 2.354 | 57.57 | 117.7 | 0.1079 | 0.1997 |
200 | 97.9 | 79.23 | 2.513 | 58.92 | 118.3 | 0.1100 | 0.2000 |
FREQUENTLY ASKED QUESTIONS
R123 refrigerant is commonly used in large, low-pressure centrifugal chillers. These chillers are often found in industrial and commercial applications where high cooling capacities are required. The use of R123 in these chillers allows for efficient and reliable cooling performance.
When replacing components in an R123 chiller system, it is essential to ensure that the correct operating conditions are maintained to prevent leakage and ensure optimal performance. This may involve replacing seals, gaskets, and other components that are compatible with R123 refrigerant. Proper installation and maintenance are critical to prevent system failures and reduce downtime.
Yes, R123 refrigerant is compatible with mineral oil and alkylbenzene lubricants. This compatibility is important to ensure that the lubricant does not react with the refrigerant and cause system failures or degradation over time. The use of compatible lubricants helps to maintain the integrity and performance of the chiller system.
The thermodynamic properties of R123 refrigerant include its temperature, pressure, and enthalpy values at various states. These properties are essential in designing and operating chiller systems that use R123 refrigerant. The table provided in the blog post lists the thermodynamic properties of R123 refrigerant at different temperatures and pressures.
The thermodynamic properties of R123 refrigerant directly impact its performance in chiller systems. For example, the refrigerant’s temperature and pressure values influence its ability to absorb and release heat, which affects the chiller’s cooling capacity and efficiency. Understanding the thermodynamic properties of R123 refrigerant is crucial for designing and operating chiller systems that meet specific cooling requirements.
