Table 3. Compressed Water and Superheated Steam

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Milo David Simon
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1 Table 3. Compressed Water and Superheated Steam 0.01 MPa (t s = C) 0.02 MPa (t s = C) 0.03 MPa (t s = C) t s(l) t s(l) t s(v) t s(v) * *Values in italics indicate points where the thermodynamic equilibrium state would be a solid; the computed values are for the metastable liquid. 16

2 0.01 MPa (t s = C) 0.02 MPa (t s = C) 0.03 MPa (t s = C)

3 0.04 MPa (t s = C) 0.05 MPa (t s = C) 0.06 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

4 0.04 MPa (t s = C) 0.05 MPa (t s = C) 0.06 MPa (t s = C)

5 0.07 MPa (t s = C) 0.08 MPa (t s = C) 0.09 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

6 0.07 MPa (t s = C) 0.08 MPa (t s = C) 0.09 MPa (t s = C)

7 0.10 MPa (t s = C) 0.11 MPa (t s = C) 0.12 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

8 0.10 MPa (t s = C) 0.11 MPa (t s = C) 0.12 MPa (t s = C)

9 0.13 MPa (t s = C) 0.14 MPa (t s = C) 0.15 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

10 0.13 MPa (t s = C) 0.14 MPa (t s = C) 0.15 MPa (t s = C)

11 0.16 MPa (t s = C) 0.18 MPa (t s = C) 0.20 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

12 0.16 MPa (t s = C) 0.18 MPa (t s = C) 0.20 MPa (t s = C)

13 0.22 MPa (t s = C) 0.24 MPa (t s = C) 0.26 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

14 0.22 MPa (t s = C) 0.24 MPa (t s = C) 0.26 MPa (t s = C)

15 0.28 MPa (t s = C) 0.30 MPa (t s = C) 0.35 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

16 0.28 MPa (t s = C) 0.30 MPa (t s = C) 0.35 MPa (t s = C)

17 0.40 MPa (t s = C) 0.45 MPa (t s = C) 0.50 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

18 0.40 MPa (t s = C) 0.45 MPa (t s = C) 0.50 MPa (t s = C)

19 0.55 MPa (t s = C) 0.60 MPa (t s = C) 0.65 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

20 0.55 MPa (t s = C) 0.60 MPa (t s = C) 0.65 MPa (t s = C)

21 0.70 MPa (t s = C) 0.75 MPa (t s = C) 0.80 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

22 0.70 MPa (t s = C) 0.75 MPa (t s = C) 0.80 MPa (t s = C)

23 0.9 MPa (t s = C) 1.0 MPa (t s = C) 1.1 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

24 0.9 MPa (t s = C) 1.0 MPa (t s = C) 1.1 MPa (t s = C)

25 1.2 MPa (t s = C) 1.3 MPa (t s = C) 1.4 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

26 1.2 MPa (t s = C) 1.3 MPa (t s = C) 1.4 MPa (t s = C)

27 1.5 MPa (t s = C) 1.6 MPa (t s = C) 1.8 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

28 1.5 MPa (t s = C) 1.6 MPa (t s = C) 1.8 MPa (t s = C)

29 2.0 MPa (t s = C) 2.2 MPa (t s = C) 2.5 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

30 2.0 MPa (t s = C) 2.2 MPa (t s = C) 2.5 MPa (t s = C)

31 3.0 MPa (t s = C) 3.5 MPa (t s = C) 4.0 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

32 3.0 MPa (t s = C) 3.5 MPa (t s = C) 4.0 MPa (t s = C)

33 4.5 MPa (t s = C) 5.0 MPa (t s = C) 5.5 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

34 4.5 MPa (t s = C) 5.0 MPa (t s = C) 5.5 MPa (t s = C)

35 6.0 MPa (t s = C) 6.5 MPa (t s = C) 7.0 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

36 6.0 MPa (t s = C) 6.5 MPa (t s = C) 7.0 MPa (t s = C)

37 7.5 MPa (t s = C) 8.0 MPa (t s = C) 9.0 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

38 7.5 MPa (t s = C) 8.0 MPa (t s = C) 9.0 MPa (t s = C)

39 10 MPa (t s = C) 11 MPa (t s = C) 12 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

40 10 MPa (t s = C) 11 MPa (t s = C) 12 MPa (t s = C)

41 13 MPa (t s = C) 14 MPa (t s = C) 15 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

42 13 MPa (t s = C) 14 MPa (t s = C) 15 MPa (t s = C)

43 16 MPa (t s = C) 17 MPa (t s = C) 18 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

44 16 MPa (t s = C) 17 MPa (t s = C) 18 MPa (t s = C)

45 19 MPa (t s = C) 20 MPa (t s = C) 22 MPa (t s = C) t s(l) t s(l) t s(v) t s(v)

46 19 MPa (t s = C) 20 MPa (t s = C) 22 MPa (t s = C)

47 25 MPa 30 MPa 35 MPa

48 25 MPa 30 MPa 35 MPa

49 40 MPa 45 MPa 50 MPa

50 40 MPa 45 MPa 50 MPa

51 60 MPa 70 MPa 80 MPa

52 60 MPa 70 MPa 80 MPa

53 90 MPa 100 MPa 120 MPa

54 90 MPa 100 MPa 120 MPa

55 140 MPa 160 MPa 180 MPa

56 140 MPa 160 MPa 180 MPa

57 200 MPa 250 MPa 300 MPa

58 350 MPa 400 MPa 450 MPa

59 500 MPa 600 MPa 700 MPa

60 800 MPa 900 MPa 1000 MPa

FUNDAMENTALS OF ENGINEERING THERMODYNAMICS

FUNDAMENTALS OF ENGINEERING THERMODYNAMICS System: Quantity of matter (constant mass) or region in space (constant volume) chosen for study. Closed system: Can exchange energy but not mass; mass is constant