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Properties of Pure
Substances
Dr. Rohit Singh Lather
• Simple System: A simple system is one in which the effects of motion, viscosity, fluid shear, capillarity,
anisotropic stress, and external force fields are absent
• Homogeneous Substance: A substance that has uniform thermodynamic properties throughout is said to be
homogeneous
• Pure Substance: A pure substance has a homogeneous and invariable chemical composition and may exist in
more than one phase
Examples:
1. Water (solid, liquid, and vapor phases)
2. Mixture of liquid water and water vapor
3. Carbon dioxide, CO2
4. Nitrogen, N2
5. Mixtures of gases, such as air, as long as there is no change of phase
Introduction
DEFINITION OF THE PURE SUBSTANCE
A pure substance is a system which is
- homogeneous in composition
- homogeneous in chemical aggregation
- invariable in chemical aggregation
the state of chemical combination of the
system does not change with time
the chemical elements must be combined chemically
in the same way in all parts of the system
Steam CO2 H2 + O2
Pure Substance Pure Substance Not a Pure Substance
• Let's consider the results of heating liquid water from 20oC, 1 atm. while keeping the pressure
constant
- We will follow the constant pressure process
- First place liquid water in a piston-cylinder device where a fixed weight is placed on the piston
to keep the pressure of the water constant at all times
- As liquid water is heated while the pressure is held constant, the following events occur
• Process 1-2:
- The temperature and specific volume will increase from the
compressed liquid, or subcooled liquid, state 1, to the saturated liquid
state 2
- In the compressed liquid region, the properties of the liquid are
approximately equal to the properties of the saturated liquid state at
the temperature
State 1
P = 1 atm.
T = 20oC
Phase Change of a Pure Substance
• Process 2-3:
- At state 2 the liquid has reached the temperature at which it begins to boil, called the
saturation temperature, and is said to exist as a saturated liquid
- Properties at the saturated liquid state are noted by the subscript f and v2 = vf
- During the phase change both the temperature and pressure remain constant (according to
the International Temperature Scale of 1990, ITS-90, water boils at 99.975oC & 100oC when the
pressure is 1 atm or 101.325 kPa)
- At state 3 the liquid and vapor phase are in equilibrium and any point on the line between
states 2 and 3 has the same temperature and pressure
State 2
P = 1 atm.
T = 100oC
State 3
P = 1 atm.
T = 100oC
• Process 3-4:
- At state 4, a saturated vapor exists and vaporization is complete
- The subscript g will always denote a saturated vapor state, v4 = vg
- The saturation temperature is the independent property
- The saturation pressure is the independent property
- The saturation pressure is the pressure at which phase change will occur for a given temperature
- In the saturation region the temperature and pressure are dependent properties; if one is
known, then the other is automatically known
State 4
P = 1 atm.
T = 100oC
Process 4-5:
- If the constant pressure heating is continued, the temperature will begin to increase above the
saturation temperature, 100oC in this example, and the volume also increases
- State 5 is called a superheated state because T5 is greater than the saturation temperature
for the pressure and the vapor is not about to condense
- Thermodynamic properties for water in the superheated region are found in the superheated
steam tables
State 5
P = 1 atm.
T = 300oC
99.975
Theory of flowing Steam Generation
𝜂SG x 𝜹mfuel x HV = 𝜹q
𝜹q = dh - vdp
Constant Pressure Steam Generation:
𝜹q = dh - vdp =0
Constant Pressure Steam Generation Process
It should be noted that the points 2 and 3
are at the same boiling point temperature
and pressure and also that, at those
conditions, the liquid and the steam are in
equilibrium with each other
• Wet steam: A mixture of water plus steam (liquid plus vapor) at the boiling point temperature of
water at a given pressure
- Quality of steam refers to the fraction or percentage
of gaseous steam in a wet steam mixture
• Dry steam: Steam, at the given pressure, that contains no water (also referred to as saturated
steam)
- The steam quality = 100%.
- At the top of steam generator units for producing
saturated steam, there are moisture separators used to
remove residual water droplets from outgoing steam
• Superheated steam: Dry steam, at the given pressure, that has been heated to a temperature
higher than the boiling point of water at that pressure
• Repeating this process for other constant pressure lines as shown below
T,oC
v, m3kgv, m3kg
374.14
0.003155
T,oC
Saturation pressure versus
saturation temperature
• Heat of vaporization: The amount of heat required to convert the liquid water completely into
vapor
• Saturation temperature and saturation pressure: The temperature at which vaporization takes
place
• Sub- cooled liquid: If the temperature of the liquid water on cooling becomes lower than the
saturation temperature for the given pressure
• Compressed liquid: When the pressure on the liquid water is greater than the saturation
pressure at a given temperature
• The term compressed liquid or sub-cooled liquid is used to distinguish it from saturated liquid. All
points in the liquid region indicate the states of the compressed liquid
• Superheated temperature: When all the liquid has been evaporated completely and heat is
further added, the temperature of the vapor increases
- When the temperature increases above the saturation temperature (in this case 100°C), the
vapor is known as the superheated vapor
- There is rapid increase in volume and the piston moves upwards
• Degree of superheat: The difference between the superheated temperature and the saturation
temperature at the given pressure
• When the pressure is greater than the critical pressure, the liquid water is directly
converted into superheated steam.
• As there is no definite point at which the liquid water changes into superheated steam, it is
generally called liquid water when the temperature is less than the critical temperature and
superheated steam when the temperature is above the critical temperature
99.61oC
179.88oC
T,oC
v, m3kg
P2 = 1000 kPa
P1 = 100 kPa
The region between the saturated liquid line and the saturated vapor
line is called by these terms: saturated liquid-vapor mixture region,
wet region (i.e., a mixture of saturated liquid and saturated vapor),
two-phase region, and just the saturation region
All of the saturated
vapor states are
connected, the
saturated vapor line is
established
saturated liquid and saturated vapor line
intersect at the critical point and form
what is often called the “steam dome”
All of the saturated liquid
states are connected,
the saturated liquid line is
established
The region to the right
of the saturated vapor
line and above the critical
temperature is called the
superheated region
The region to the left of
the saturated liquid line
and below the critical
temperature is called the
compressed liquid region
• Notice that the trend of the temperature following a constant pressure line is to increase with
increasing volume and the trend of the pressure following a constant temperature line is to
decrease with increasing volume
P,oC
v, m3kg
T = constant lines on
this diagram have a
downward trend
At temperatures and pressures
above the critical point, the
phase transition from liquid to
vapor is no longer discrete
v, m3kg
T,oC
• The critical-point properties of water are
- Pcr 22.06 Mpa
- Tcr 373.95°C
- vcr 0.003106 m3/kg
• The triple point of water is 0.01oC, 0.6117 kPa
• The critical point of water is 373.95oC, 22.064 MPa
Pressure
Temperature
P-T diagram, often called the phase diagram, for pure substances
• Process : liquid to vapor transition
• Process : solid to liquid transition
• Process : solid to vapor transition
• It must be understood that only on p-T diagram is
the triple point represented by a point
• On p-V diagram it is a line
• On a U-V diagram it is a triangle
The triple point is merely
the point of intersection
of sublimation and
vaporization curves
Pressure
Temperature
• Since state 3 is a mixture of saturated liquid and saturated vapor, how do we locate it on
the T-v diagram?
- To establish the location of state 3, a parameter called the quality x is defined as
x
mass
mass
m
m m
saturated vapor
total
g
f g
= =
+
Quality and Saturated Liquid-Vapor Mixture
Saturated Vapor vg
Saturated Liquid vf
Saturated Liquid
Vapor Mixture vfg
=
v, m3kg
T,oC;P
• Sensible heat of water (hf) It is defined as the quantity of heat absorbed by 1 kg of water when
it is heated from 0°C (freezing point) to boiling point.
- It is also called total heat (or enthalpy) of water or liquid heat invariably.
- It is reckoned from 0°C where sensible heat is taken as zero
- If 1 kg of water is heated from 0°C to 100°C the sensible heat added to it will be 4.18 × 100 = 418 kJ
but if water is at say 20°C initially then sensible heat added will be 4.18 × (100 – 20) = 334.4 kJ
This type of heat is denoted by letter hf and its value can be directly read from the steam tables
• Note: The value of specific heat of water may be taken as 4.18 kJ/kg K at low pressures but at high
pressures it is different from this value
• Latent heat or hidden heat (hfg) It is the amount of heat required to convert water at a given
temperature and pressure into steam at the same temperature and pressure
- It is expressed by the symbol hfg and its value is available from steam tables
- The value of latent heat is not constant and varies according to pressure variation
• If in 1 kg of wet steam 0.9 kg is the dry steam and 0.1 kg water particles then x = 0.9
- Note: No steam can be completely dry and saturated, so long as it is in contact with the water from which
it is being formed
• The quality is zero for the saturated liquid and one for the saturated vapor (0 ≤ x ≤ 1)
• Total heat or enthalpy of wet steam (h): defined as the quantity of heat required to convert 1
kg of water at 0°C into wet steam at constant pressure
- It is the sum of total heat of water and the latent heat and this sum is also called enthalpy.
- In other words, h = hf + xhfg If steam is dry and saturated, then x = 1 and hg =hf +hfg
• Superheated steam: When steam is heated after it has become dry and saturated, it is called
superheated steam and the process of heating is called superheating. Superheating is always
carried out at constant pressure
• The additional amount of heat supplied to the steam during superheating is called as ‘Heat of
superheat’ and can be calculated by using the specific heat of superheated steam at constant
pressure (cps), the value of which varies from 2.0 to 2.1 kJ/kg K depending upon pressure and
temperature
• If Tsup., Ts are the temperatures of superheated steam in K and wet or dry steam, then (Tsup – Ts)
is called ‘degree of superheat’
• The total heat of superheated steam is given by hsup = hf + hfg + cps (Tsup – Ts)
• Superheated steam behaves like a gas and therefore it follows the gas laws
• The value of n for this type of steam is 1.3 and the law for the adiabatic expansion is pv1.3 =
constant
• Volume of wet and dry steam: If the steam has dryness fraction of x, then 1 kg of this steam
will contain x kg of dry steam and (1 – x) kg of water. If vf is the volume of 1 kg of water and vg is
the volume of 1 kg of perfect dry steam (also known as specific volume),
volume of 1 kg of wet steam = volume of dry steam + volume of water
= xvg + (1 – x)vf
• Note. The volume of vf at low pressures is very small and is generally neglected. Thus is general,
the volume of 1 kg of wet steam is given by, xvg and density 1/ xvg kg/m3
=xvg +vf –xvf
=vf +x(vg –vf)
= vf + xvfg
=vf +xvfg + vfg –vfg
=(vf + vfg) – (1 – x)vfg
= vg – (1 – x) vfg
• Volume of superheated steam. As superheated steam behaves like a perfect gas its volume can
be found out in the same way as the gases.
If, vg = Specific volume of dry steam at pressure p
Ts = Saturation temperature in K
Tsup = Temperature of superheated steam in K
vsup = Volume of 1 kg of superheated steam at pressure p
Then,
p.vg / Ts = p.vsup/ Tsup
vsup = vgTsup / Ts
If steam is superheated to a volume of vsup per kg. hsup = hf + hfg + cps (Tsup –Ts)
Temp.,
T oC
Sat.
Press.,
Psat kPa
Specific volume,
m3/kg
Internal energy,
kJ/kg
Enthalpy,
kJ/kg
Entropy,
kJ/kg -K
Sat. liquid,
vf
Sat.
vapor,
vg
Sat.
liquid,
uf
Evap.,
ufg
Sat.
vapor,
ug
Sat.
liquid,
hf
Evap.,
hfg
Sat.
vapor,
hg
Sat.
liquid, sf
Evap., sfg Sat.
vapor,
sg
0.01 0.6117 0.001000 206.00 0.00 2374.9 2374.9 0.00 2500.9 2500.9 0.0000 9.1556 9.1556
5 0.8725 0.001000 147.03 21.02 2360.8 2381.8 21.02 2489.1 2510.1 0.0763 8.9487 9.0249
10 1.228 0.001000 106.32 42.02 2346.6 2388.7 42.02 2477.2 2519.2 0.1511 8.7488 8.8999
15 1.706 0.001001 77.885 62.98 2332.5 2395.5 62.98 2465.4 2528.3 0.2245 8.5559 8.7803
20 2.339 0.001002 57.762 83.91 2318.4 2402.3 83.91 2453.5 2537.4 0.2965 8.3696 8.6661
25 3.170 0.001003 43.340 104.83 2304.3 2409.1 104.83 2441.7 2546.5 0.3672 8.1895 8.5567
30 4.247 0.001004 32.879 125.73 2290.2 2415.9 125.74 2429.8 2555.6 0.4368 8.0152 8.4520
35 5.629 0.001006 25.205 146.63 2276.0 2422.7 146.64 2417.9 2564.6 0.5051 7.8466 8.3517
40 7.385 0.001008 19.515 167.53 2261.9 2429.4 167.53 2406.0 2573.5 0.5724 7.6832 8.2556
45 9.595 0.001010 15.251 188.43 2247.7 2436.1 188.44 2394.0 2582.4 0.6386 7.5247 8.1633
50 12.35 0.001012 12.026 209.33 2233.4 2442.7 209.34 2382.0 2591.3 0.7038 7.3710 8.0748
55 15.76 0.001015 9.5639 230.24 2219.1 2449.3 230.26 2369.8 2600.1 0.7680 7.2218 7.9898
60 19.95 0.001017 7.6670 251.16 2204.7 2455.9 251.18 2357.7 2608.8 0.8313 7.0769 7.9082
65 25.04 0.001020 6.1935 272.09 2190.3 2462.4 272.12 2345.4 2617.5 0.8937 6.9360 7.8296
70 31.20 0.001023 5.0396 293.04 2175.8 2468.9 293.07 2333.0 2626.1 0.9551 6.7989 7.7540
75 38.60 0.001026 4.1291 313.99 2161.3 2475.3 314.03 2320.6 2634.6 1.0158 6.6655 7.6812
80 47.42 0.001029 3.4053 334.97 2146.6 2481.6 335.02 2308.0 2643.0 1.0756 6.5355 7.6111
85 57.87 0.001032 2.8261 355.96 2131.9 2487.8 356.02 2295.3 2651.4 1.1346 6.4089 7.5435
90 70.18 0.001036 2.3593 376.97 2117.0 2494.0 377.04 2282.5 2659.6 1.1929 6.2853 7.4782
95 84.61 0.001040 1.9808 398.00 2102.0 2500.1 398.09 2269.6 2667.6 1.2504 6.1647 7.4151
100 101.42 0.001043 1.6720 419.06 2087.0 2506.0 419.17 2256.4 2675.6 1.3072 6.0470 7.3542
٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠
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360 18666 0.001895 0.006950 1726.16 625.7 2351.9 1761.53 720.1 2481.6 3.9165 1.1373 5.0537
365 19822 0.002015 0.006009 1777.22 526.4 2303.6 1817.16 605.5 2422.7 4.0004 0.9489 4.9493
370 21044 0.002217 0.004953 1844.53 385.6 2230.1 1891.19 443.1 2334.3 4.1119 0.6890 4.8009
373.95 22064 0.003106 0.003106 2015.8 0 2015.8 2084.3 0 2084.3 4.4070 0 4.4070
TABLE:SaturatedSteam-PressureTable
TABLE: Saturated Water-Pressure Table
Press.
P kPa
Sat. Temp.,
Tsat
oC
Specific volume,
m3/kg
Internal energy,
kJ/kg
Enthalpy,
kJ/kg
Entropy,
kJ/kg - K
Sat.
liquid,
vf
Sat.
vapor,
vg
Sat.
liquid,
uf
Evap.,
ufg
Sat.
vapor,
ug
Sat.
liquid,
hf
Evap.,
hfg
Sat.
vapor,
hg
Sat.
liquid,
sf
Evap.,
sfg
Sat.
vapor,
sg
0.6117 0.01 0.001000 206.00 0.00 2374.9 2374.9 0.00 2500.9 2500.9 0.0000 9.1556 9.1556
1.0 6.97 0.001000 129.19 29.30 2355.2 2384.5 29.30 2484.4 2513.7 0.1059 8.8690 8.9749
1.5 13.02 0.001001 87.964 54.69 2338.1 2392.8 54.69 2470.1 2524.7 0.1956 8.6314 8.8270
2.0 17.50 0.001001 66.990 73.43 2325.5 2398.9 73.43 2459.5 2532.9 0.2606 8.4621 8.7227
2.5 21.08 0.001002 54.242 88.42 2315.4 2403.8 88.42 2451.0 2539.4 0.3118 8.3302 8.6421
3.0 24.08 0.001003 45.654 100.98 2306.9 2407.9 100.98 2443.9 2544.8 0.3543 8.2222 8.5765
4.0 28.96 0.001004 34.791 121.39 2293.1 2414.5 121.39 2432.3 2553.7 0.4224 8.0510 8.4734
5.0 32.87 0.001005 28.185 137.75 2282.1 2419.8 137.75 2423.0 2560.7 0.4762 7.9176 8.3938
7.5 40.29 0.001008 19.233 168.74 2261.1 2429.8 168.75 2405.3 2574.0 0.5763 7.6738 8.2501
10 45.81 0.001010 14.670 191.79 2245.4 2437.2 191.81 2392.1 2583.9 0.6492 7.4996 8.1488
15 53.97 0.001014 10.020 225.93 2222.1 2448.0 225.94 2372.3 2598.3 0.7549 7.2522 8.0071
20 60.06 0.001017 7.6481 251.40 2204.6 2456.0 251.42 2357.5 2608.9 0.8320 7.0752 7.9073
25 64.96 0.001020 6.2034 271.93 2190.4 2462.4 271.96 2345.5 2617.5 0.8932 6.9370 7.8302
30 69.09 0.001022 5.2287 289.24 2178.5 2467.7 289.27 2335.3 2624.6 0.9441 6.8234 7.7675
40 75.86 0.001026 3.9933 317.58 2158.8 2476.3 317.62 2318.4 2636.1 1.0261 6.6430 7.6691
50 81.32 0.001030 3.2403 340.49 2142.7 2483.2 340.54 2304.7 2645.2 1.0912 6.5019 7.5931
75 91.76 0.001037 2.2172 384.36 2111.8 2496.1 384.44 2278.0 2662.4 1.2132 6.2426 7.4558
100 99.61 0.001043 1.6941 417.40 2088.2 2505.6 417.51 2257.5 2675.0 1.3028 6.0562 7.3589
125 105.97 0.001048 1.3750 444.23 2068.8 2513.0 444.36 2240.6 2684.9 1.3741 5.9100 7.2841
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٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠
20,000 365.75 0.002038 0.005862 1785.84 509.0 2294.8 1826.59 585.5 2412.1 4.0146 0.9164 4.9310
21,000 369.83 0.002207 0.004994 1841.62 391.9 2233.5 1887.97 450.4 2338.4 4.1071 0.7005 4.8076
22,000 373.71 0.002703 0.003644 1951.65 140.8 2092.4 2011.12 161.5 2172.6 4.2942 0.2496 4.5439
22,064 373.95 0.003106 0.003106 2015.8 0 2015.8 2084.3 0 2084.3 4.4070 0 4.4070
• The last entry is the critical
point at 22.064MPa
Superheated Water Table
- A substance is said to be superheated if the given temperature is greater than the saturation
temperature for the given pressure
• In the superheated water Table, T and P are the independent properties
• The value of temperature to the right of the pressure is the saturation temperature for the
pressure
- The first entry in the table is the saturated vapor state at the pressure
• A substance is said to be a compressed liquid when the pressure is greater than the saturation
pressure for the temperature.
• It is now noted that state 1 is called a compressed liquid state because the saturation pressure
for the temperature T1 is less than P1
Compressed Liquid Water Table
• The plot of total heat against entropy, is more widely used than any other entropy diagram, since the work
done on vapor cycles can be scaled from this diagram directly as a length; whereas on T-s diagram it is
represented by an area
ENTHALPY-ENTROPY (h-s) CHART OR MOLLIER DIAGRAM
• Lines of constant pressure are indicated by p1,
p2 etc., lines of constant temperature by T1,
T2, etc
• Any two independent properties which appear
on the chart are sufficient to define the
state (e.g., p1 and x1 define state 1 and h can
be read off the vertical axis)
• In the superheat region, pressure and
temperature can define the state (e.g., p3 and
T4 define the state 2, and h2 can be read off)
• A line of constant entropy between two state
points 2 and 3 defines the properties at all
points during an isentropic process between
the two states
• For any state, at least two properties should be
known to determine the other unknown
properties of steam at that state
• The Mollier diagram is used only when quality is
greater than 50% and for superheated steam
Example: Find the specific volume, enthalpy and internal energy of wet steam at 18 bar with dryness
fraction (x) = 0.85, by using Steam Tables and Mollier chart.
Solution: Given: Pressure of steam, p= 18 bar; Dryness fraction, x= 0.85
(a) By using steam tables (for dry saturated steam): at 18 bar pressure, we have:
ts = 207.11°C, hf = 884.5 kJ/kg, hg = 2794.8 kJ/kg, hfg = 1910.3 kJ/kg, vg= 0.110 m3/kg
(i) Specific volume of wet steam, v : = x.vg
Answer: v = x.vg =0.85 x 0.110 = 0.0935 m3/kg
(ii) Specific enthalpy of wet steam, h = hf + xhfg
Answer: h = hf + xhfg= 884.6 + 0.85 x 1910.3 = 2508.35 kJ/kg.
(iii) Specific internal energy of wet steam, u = h – pv
Answer: u = h – pv= 2508.35 – 18 x 102 (0.0935) = 2340.75 kJ/kg
Locate point ‘1’ at an intersection of 18 bar pressure line and 0.85 dryness fraction line.
Read the value of enthalpy (h) and specific volume (v) from Mollier diagram corresponding to point ‘1’.
(i) Specific enthalpy of wet steam, h = 2508 KJ/kg
(ii) Specific volume of wet steam, v = 0.0935 m3/kg
(iii) Specific Internal energy of wet steam, u = h – pv = 2508 – 18 x 102 (0.0935) = 2340 kJ/kg
The definition of quality x
m
m
m
m m
g g
f g
= =
+
Then
m
m
m m
m
x
f g
=
−
= −1
- Note, quantity 1- x is often given the name moisture
- The specific volume of the saturated mixture becomes v = (1 - x) vf + x vg
- The average specific volume at any state 3 is given in terms of the quality as follows
Consider a mixture of saturated liquid and saturated vapor
The liquid has a mass mf and occupies a volume Vf = mf vf
The vapor has a mass mg and occupies a volume Vg = mg vg
Note V = Vf + Vg
m = mf + mg
V = mass * specific volume = m.v = mfvf + mgvg ; v =
#$	
&$
#
+
#'&'
#
The form that is most often used v = vf + x (vg - vf)
• It is noted that the value of any extensive property per unit mass in the saturation region is
calculated from an equation having a form similar to that of the above equation
• Let Y be any extensive property and let y be the corresponding intensive property, Y/m, then
y
Y
m
y x y y
y x y
where y y y
f g f
f fg
fg g f
= = + −
= +
= −
( )
• The term yfg is the difference between the saturated vapor and the saturated liquid values of the
property y; y may be replaced by any of the variables v, u, h, or s
• We often use the above equation to determine the quality x of a saturated liquid-vapor state
• The following application is called the Lever Rule:
x
y y
y
f
fg
=
−
Measurement of dryness fraction
• The quality of wet steam is defined by its dryness fraction
• When the dryness fraction, pressure and temperature of the steam are known, then the state of
wet steam is fully defined
• In a steam plant it is at times necessary to know the state of the steam
• Many of the steam prime-movers are supplied with superheated steam
• The enthalpy (total heat) of such a steam is readily determined when its pressure and
temperature are known
• However, there are many cases in which saturated steam or wet steam is supplied
• The measurement of its temperature, when pressure is known, simply confirms the fact that the
steam is saturated or wet
- In no way it gives any information as to either the quality of steam or the enthalpy of steam
- For wet steam, this entails finding the dryness fraction
• To aid in the determination of the quality (dryness fraction) of wet steam, various types of steam
calorimeters have been devised
• The types of colorimeters used for this purpose are :
-Throttling calorimeter - Steam that is nearly dry
- Separating calorimeter - Steam is very wet
- Combined Separating and Throttling calorimeter
Throttling Calorimeter
The steam to be sampled is taken from
the pipe by means of suitable positioned
and dimensioned sampling tube
It passes into an insulated
container and is throttled
through an orifice to
atmospheric pressure
Here the temperature is
taken and the steam
ideally should have about
5.5 K of superheat
The throttling process
is shown on h-s diagram
by the line 1-2
• If steam initially wet is throttled through a sufficiently large pressure drop, then the steam at
state 2 will become superheated
• State 2 can then be defined by the measured pressure and temperature
• The enthalpy, h2 can then be found and hence
h2 = h1= (hf1 + x1hfg1) at p1
Where, h2 = hf2 + hfg2 + cps (Tsup2 −Ts2)]
∴ x1 = h2 − hf1 / hfg2
Hence the dryness fraction is determined and state 1 is defined
• Since mechanical separation of suspended water particles from wet steam cannot be perfect, a
separating calorimeter is not so accurate as a throttling calorimeter
• The operation of the throttling calorimeter depends on the steam being superheated after
throttling and it will fail in its purpose, if the steam is so wet before throttling that it remains
wet after throttling
• Therefore, a very successful method of measuring the dryness fraction of very wet steam is by a
combined separating and throttling calorimeter
• If the steam whose dryness fraction is to be determined is very wet then throttling to
atmospheric pressure may not be sufficient to ensure superheated steam at exit
• In this case it is necessary to dry the steam partially, before throttling, This is done by passing
the steam sample from the main through a separating calorimeter
Separating and Throttling Calorimeter
The steam is made to change direction
suddenly, and the water, being denser
than the dry steam is separated out
The quantity of water which
is separated out (mw) is
measured at the separator
the steam remaining, which now has a
higher dryness fraction, is passed
through the throttling calorimeter
With the combined separating and
throttling calorimeter it is necessary to
condense the steam after throttling and
measure the amount of condensate (ms)
If a throttling calorimeter only is sufficient, there is no need to measure condensate, the pressure and
temperature measurements at exit being sufficient
• A detailed study of the heating process reveals that the temperature of the solid rises and then
during the change of phase from solid to liquid (or solid to vapour) the temperature remains
constant
- This phenomenon is common to all phase changes
• Since the temperature is constant, pressure and temperature are not independent properties and
cannot be used to specify state during a change of phase
• The combined picture of change of pressure, specific volume and temperature may be shown on a
three dimensional state model
- illustrates the equilibrium states for a pure substance which expands on fusion
- Water is an example of a substance that exhibits this phenomenon
The P-V-T Surface for a Real Substance
• All the equilibrium states lie on the surface of the model
• States represented by the space above or below the surface are not possible
• It may be seen that the triple point appears as a line in this representation
• The point C.P. is called the critical point and no liquid phase exists at temperatures above
the iso- therms through this point
- The term evaporation is meaningless in this situation
• At the critical point the temperature and pressure are called the critical temperature and the
critical pressure respectively
- When the temperature of a substance is above the critical value, it is called a gas
• It is not possible to cause a phase change in a gas unless the temperature is lowered to a value
less than the critical temperature
- Oxygen and nitrogen are examples of gases that have critical temperatures below normal
atmospheric temperature
• Real substances that readily change phase from solid to liquid to gas such as water, refrigerant-134a, and
ammonia cannot be treated as ideal gases in general
• The pressure, volume, temperature relation, or equation of state for these substances is generally very
complicated, and the thermodynamic properties are given in table form
• The properties of these substances may be illustrated by the functional relation F (P,v,T)=0, called an
equation of state
State Postulate
- The state postulate for a simple, pure substance states that the equilibrium state can be determined by
specifying any two independent intensive properties
P-V-T Surface for a Substance
that contracts upon freezing
P-V-T Surface for a Substance
that expands upon freezing
• These figures show three regions where a substance like water may exist as a solid, liquid or gas
(or vapor)
• Also these figures show that a substance may exist as a mixture of two phases during phase
change, solid-vapor, solid-liquid, and liquid-vapor
• Water may exist in the compressed liquid region, a region where saturated liquid water and
saturated water vapor are in equilibrium (called the saturation region), and the superheated vapor
region (the solid or ice region is not shown)
• Property tables give data for
- Temperature
- Pressure
- Volume
- Specific internal energy u
- Specific enthalpy h
- the specific entropy s
• The enthalpy is a convenient grouping of the internal energy, pressure, and volume and is given
- H = U + PV
- enthalpy per unit mass is h = u + Pv
• The enthalpy h is quite useful in calculating the energy of mass streams flowing into and out of
control volumes
• The enthalpy is also useful in the energy balance during a constant pressure process for a
substance contained in a closed piston-cylinder device
Property Tables
• Saturation pressure is the pressure at which the liquid and vapor phases are in equilibrium at a
given temperature
• Saturation temperature is the temperature at which the liquid and vapor phases are in equilibrium
at a given pressure
• The subscript fg used in tables, refers to the difference between the saturated vapor value and
the saturated liquid value region
- That is, u u u
h h h
s s s
fg g f
fg g f
fg g f
= −
= −
= −
• The quantity hfg is called the enthalpy of vaporization (or latent heat of vaporization)
• It represents the amount of energy needed to vaporize a unit of mass of saturated liquid at a
given temperature or pressure
• It decreases as the temperature or pressure increases, and becomes zero at the critical point
The Lever Rule is illustrated in the following figures
Superheated Water Table
- A substance is said to be superheated if the given temperature is greater than the saturation
temperature for the given pressure
• In the superheated water Table, T and P are the independent properties
• The value of temperature to the right of the pressure is the saturation temperature for the
pressure
- The first entry in the table is the saturated vapor state at the pressure
Is ?
Is ?
Is ?
v v
v v v
v v
f
f g
g
<
< <
<
The answer to one of these questions must be yes
- If the answer to the first question is yes, the state is in the compressed liquid region, and the compressed
liquid tables are used to find the properties of the state
- If the answer to the second question is yes, the state is in the saturation region, and either the saturation
temperature table or the saturation pressure table is used to find the properties. Then the quality is
calculated and is used to calculate the other properties, u, h, and s
- If the answer to the third question is yes, the state is in the superheated region and the superheated tables
are used to find the other properties
The correct table to use to find the thermodynamic properties of a real substance can always be determined by
comparing the known state properties to the properties in the saturation region. Given the temperature or
pressure and one other property from the group v, u, h, and s, the following procedure is used. For example if
the pressure and specific volume are specified, three questions are asked: For the given pressure,
How to Choose the Right Table
Some tables may not always give the internal energy. When it is not listed, the internal energy is calculated
from the definition of the enthalpy as, u = h - Pv

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Pure substances

  • 2. • Simple System: A simple system is one in which the effects of motion, viscosity, fluid shear, capillarity, anisotropic stress, and external force fields are absent • Homogeneous Substance: A substance that has uniform thermodynamic properties throughout is said to be homogeneous • Pure Substance: A pure substance has a homogeneous and invariable chemical composition and may exist in more than one phase Examples: 1. Water (solid, liquid, and vapor phases) 2. Mixture of liquid water and water vapor 3. Carbon dioxide, CO2 4. Nitrogen, N2 5. Mixtures of gases, such as air, as long as there is no change of phase Introduction
  • 3. DEFINITION OF THE PURE SUBSTANCE A pure substance is a system which is - homogeneous in composition - homogeneous in chemical aggregation - invariable in chemical aggregation the state of chemical combination of the system does not change with time the chemical elements must be combined chemically in the same way in all parts of the system Steam CO2 H2 + O2 Pure Substance Pure Substance Not a Pure Substance
  • 4. • Let's consider the results of heating liquid water from 20oC, 1 atm. while keeping the pressure constant - We will follow the constant pressure process - First place liquid water in a piston-cylinder device where a fixed weight is placed on the piston to keep the pressure of the water constant at all times - As liquid water is heated while the pressure is held constant, the following events occur • Process 1-2: - The temperature and specific volume will increase from the compressed liquid, or subcooled liquid, state 1, to the saturated liquid state 2 - In the compressed liquid region, the properties of the liquid are approximately equal to the properties of the saturated liquid state at the temperature State 1 P = 1 atm. T = 20oC Phase Change of a Pure Substance
  • 5. • Process 2-3: - At state 2 the liquid has reached the temperature at which it begins to boil, called the saturation temperature, and is said to exist as a saturated liquid - Properties at the saturated liquid state are noted by the subscript f and v2 = vf - During the phase change both the temperature and pressure remain constant (according to the International Temperature Scale of 1990, ITS-90, water boils at 99.975oC & 100oC when the pressure is 1 atm or 101.325 kPa) - At state 3 the liquid and vapor phase are in equilibrium and any point on the line between states 2 and 3 has the same temperature and pressure State 2 P = 1 atm. T = 100oC State 3 P = 1 atm. T = 100oC
  • 6. • Process 3-4: - At state 4, a saturated vapor exists and vaporization is complete - The subscript g will always denote a saturated vapor state, v4 = vg - The saturation temperature is the independent property - The saturation pressure is the independent property - The saturation pressure is the pressure at which phase change will occur for a given temperature - In the saturation region the temperature and pressure are dependent properties; if one is known, then the other is automatically known State 4 P = 1 atm. T = 100oC
  • 7. Process 4-5: - If the constant pressure heating is continued, the temperature will begin to increase above the saturation temperature, 100oC in this example, and the volume also increases - State 5 is called a superheated state because T5 is greater than the saturation temperature for the pressure and the vapor is not about to condense - Thermodynamic properties for water in the superheated region are found in the superheated steam tables State 5 P = 1 atm. T = 300oC
  • 8. 99.975 Theory of flowing Steam Generation 𝜂SG x 𝜹mfuel x HV = 𝜹q 𝜹q = dh - vdp Constant Pressure Steam Generation: 𝜹q = dh - vdp =0 Constant Pressure Steam Generation Process It should be noted that the points 2 and 3 are at the same boiling point temperature and pressure and also that, at those conditions, the liquid and the steam are in equilibrium with each other
  • 9. • Wet steam: A mixture of water plus steam (liquid plus vapor) at the boiling point temperature of water at a given pressure - Quality of steam refers to the fraction or percentage of gaseous steam in a wet steam mixture • Dry steam: Steam, at the given pressure, that contains no water (also referred to as saturated steam) - The steam quality = 100%. - At the top of steam generator units for producing saturated steam, there are moisture separators used to remove residual water droplets from outgoing steam • Superheated steam: Dry steam, at the given pressure, that has been heated to a temperature higher than the boiling point of water at that pressure
  • 10. • Repeating this process for other constant pressure lines as shown below T,oC v, m3kgv, m3kg 374.14 0.003155 T,oC
  • 12. • Heat of vaporization: The amount of heat required to convert the liquid water completely into vapor • Saturation temperature and saturation pressure: The temperature at which vaporization takes place • Sub- cooled liquid: If the temperature of the liquid water on cooling becomes lower than the saturation temperature for the given pressure • Compressed liquid: When the pressure on the liquid water is greater than the saturation pressure at a given temperature • The term compressed liquid or sub-cooled liquid is used to distinguish it from saturated liquid. All points in the liquid region indicate the states of the compressed liquid
  • 13. • Superheated temperature: When all the liquid has been evaporated completely and heat is further added, the temperature of the vapor increases - When the temperature increases above the saturation temperature (in this case 100°C), the vapor is known as the superheated vapor - There is rapid increase in volume and the piston moves upwards • Degree of superheat: The difference between the superheated temperature and the saturation temperature at the given pressure • When the pressure is greater than the critical pressure, the liquid water is directly converted into superheated steam. • As there is no definite point at which the liquid water changes into superheated steam, it is generally called liquid water when the temperature is less than the critical temperature and superheated steam when the temperature is above the critical temperature
  • 14. 99.61oC 179.88oC T,oC v, m3kg P2 = 1000 kPa P1 = 100 kPa The region between the saturated liquid line and the saturated vapor line is called by these terms: saturated liquid-vapor mixture region, wet region (i.e., a mixture of saturated liquid and saturated vapor), two-phase region, and just the saturation region All of the saturated vapor states are connected, the saturated vapor line is established saturated liquid and saturated vapor line intersect at the critical point and form what is often called the “steam dome” All of the saturated liquid states are connected, the saturated liquid line is established The region to the right of the saturated vapor line and above the critical temperature is called the superheated region The region to the left of the saturated liquid line and below the critical temperature is called the compressed liquid region
  • 15. • Notice that the trend of the temperature following a constant pressure line is to increase with increasing volume and the trend of the pressure following a constant temperature line is to decrease with increasing volume P,oC v, m3kg T = constant lines on this diagram have a downward trend
  • 16. At temperatures and pressures above the critical point, the phase transition from liquid to vapor is no longer discrete v, m3kg T,oC • The critical-point properties of water are - Pcr 22.06 Mpa - Tcr 373.95°C - vcr 0.003106 m3/kg
  • 17. • The triple point of water is 0.01oC, 0.6117 kPa • The critical point of water is 373.95oC, 22.064 MPa Pressure Temperature P-T diagram, often called the phase diagram, for pure substances • Process : liquid to vapor transition • Process : solid to liquid transition • Process : solid to vapor transition • It must be understood that only on p-T diagram is the triple point represented by a point • On p-V diagram it is a line • On a U-V diagram it is a triangle The triple point is merely the point of intersection of sublimation and vaporization curves Pressure Temperature
  • 18. • Since state 3 is a mixture of saturated liquid and saturated vapor, how do we locate it on the T-v diagram? - To establish the location of state 3, a parameter called the quality x is defined as x mass mass m m m saturated vapor total g f g = = + Quality and Saturated Liquid-Vapor Mixture Saturated Vapor vg Saturated Liquid vf Saturated Liquid Vapor Mixture vfg = v, m3kg T,oC;P
  • 19. • Sensible heat of water (hf) It is defined as the quantity of heat absorbed by 1 kg of water when it is heated from 0°C (freezing point) to boiling point. - It is also called total heat (or enthalpy) of water or liquid heat invariably. - It is reckoned from 0°C where sensible heat is taken as zero - If 1 kg of water is heated from 0°C to 100°C the sensible heat added to it will be 4.18 × 100 = 418 kJ but if water is at say 20°C initially then sensible heat added will be 4.18 × (100 – 20) = 334.4 kJ This type of heat is denoted by letter hf and its value can be directly read from the steam tables • Note: The value of specific heat of water may be taken as 4.18 kJ/kg K at low pressures but at high pressures it is different from this value • Latent heat or hidden heat (hfg) It is the amount of heat required to convert water at a given temperature and pressure into steam at the same temperature and pressure - It is expressed by the symbol hfg and its value is available from steam tables - The value of latent heat is not constant and varies according to pressure variation
  • 20. • If in 1 kg of wet steam 0.9 kg is the dry steam and 0.1 kg water particles then x = 0.9 - Note: No steam can be completely dry and saturated, so long as it is in contact with the water from which it is being formed • The quality is zero for the saturated liquid and one for the saturated vapor (0 ≤ x ≤ 1) • Total heat or enthalpy of wet steam (h): defined as the quantity of heat required to convert 1 kg of water at 0°C into wet steam at constant pressure - It is the sum of total heat of water and the latent heat and this sum is also called enthalpy. - In other words, h = hf + xhfg If steam is dry and saturated, then x = 1 and hg =hf +hfg
  • 21. • Superheated steam: When steam is heated after it has become dry and saturated, it is called superheated steam and the process of heating is called superheating. Superheating is always carried out at constant pressure • The additional amount of heat supplied to the steam during superheating is called as ‘Heat of superheat’ and can be calculated by using the specific heat of superheated steam at constant pressure (cps), the value of which varies from 2.0 to 2.1 kJ/kg K depending upon pressure and temperature • If Tsup., Ts are the temperatures of superheated steam in K and wet or dry steam, then (Tsup – Ts) is called ‘degree of superheat’ • The total heat of superheated steam is given by hsup = hf + hfg + cps (Tsup – Ts) • Superheated steam behaves like a gas and therefore it follows the gas laws • The value of n for this type of steam is 1.3 and the law for the adiabatic expansion is pv1.3 = constant
  • 22. • Volume of wet and dry steam: If the steam has dryness fraction of x, then 1 kg of this steam will contain x kg of dry steam and (1 – x) kg of water. If vf is the volume of 1 kg of water and vg is the volume of 1 kg of perfect dry steam (also known as specific volume), volume of 1 kg of wet steam = volume of dry steam + volume of water = xvg + (1 – x)vf • Note. The volume of vf at low pressures is very small and is generally neglected. Thus is general, the volume of 1 kg of wet steam is given by, xvg and density 1/ xvg kg/m3 =xvg +vf –xvf =vf +x(vg –vf) = vf + xvfg =vf +xvfg + vfg –vfg =(vf + vfg) – (1 – x)vfg = vg – (1 – x) vfg
  • 23. • Volume of superheated steam. As superheated steam behaves like a perfect gas its volume can be found out in the same way as the gases. If, vg = Specific volume of dry steam at pressure p Ts = Saturation temperature in K Tsup = Temperature of superheated steam in K vsup = Volume of 1 kg of superheated steam at pressure p Then, p.vg / Ts = p.vsup/ Tsup vsup = vgTsup / Ts If steam is superheated to a volume of vsup per kg. hsup = hf + hfg + cps (Tsup –Ts)
  • 24. Temp., T oC Sat. Press., Psat kPa Specific volume, m3/kg Internal energy, kJ/kg Enthalpy, kJ/kg Entropy, kJ/kg -K Sat. liquid, vf Sat. vapor, vg Sat. liquid, uf Evap., ufg Sat. vapor, ug Sat. liquid, hf Evap., hfg Sat. vapor, hg Sat. liquid, sf Evap., sfg Sat. vapor, sg 0.01 0.6117 0.001000 206.00 0.00 2374.9 2374.9 0.00 2500.9 2500.9 0.0000 9.1556 9.1556 5 0.8725 0.001000 147.03 21.02 2360.8 2381.8 21.02 2489.1 2510.1 0.0763 8.9487 9.0249 10 1.228 0.001000 106.32 42.02 2346.6 2388.7 42.02 2477.2 2519.2 0.1511 8.7488 8.8999 15 1.706 0.001001 77.885 62.98 2332.5 2395.5 62.98 2465.4 2528.3 0.2245 8.5559 8.7803 20 2.339 0.001002 57.762 83.91 2318.4 2402.3 83.91 2453.5 2537.4 0.2965 8.3696 8.6661 25 3.170 0.001003 43.340 104.83 2304.3 2409.1 104.83 2441.7 2546.5 0.3672 8.1895 8.5567 30 4.247 0.001004 32.879 125.73 2290.2 2415.9 125.74 2429.8 2555.6 0.4368 8.0152 8.4520 35 5.629 0.001006 25.205 146.63 2276.0 2422.7 146.64 2417.9 2564.6 0.5051 7.8466 8.3517 40 7.385 0.001008 19.515 167.53 2261.9 2429.4 167.53 2406.0 2573.5 0.5724 7.6832 8.2556 45 9.595 0.001010 15.251 188.43 2247.7 2436.1 188.44 2394.0 2582.4 0.6386 7.5247 8.1633 50 12.35 0.001012 12.026 209.33 2233.4 2442.7 209.34 2382.0 2591.3 0.7038 7.3710 8.0748 55 15.76 0.001015 9.5639 230.24 2219.1 2449.3 230.26 2369.8 2600.1 0.7680 7.2218 7.9898 60 19.95 0.001017 7.6670 251.16 2204.7 2455.9 251.18 2357.7 2608.8 0.8313 7.0769 7.9082 65 25.04 0.001020 6.1935 272.09 2190.3 2462.4 272.12 2345.4 2617.5 0.8937 6.9360 7.8296 70 31.20 0.001023 5.0396 293.04 2175.8 2468.9 293.07 2333.0 2626.1 0.9551 6.7989 7.7540 75 38.60 0.001026 4.1291 313.99 2161.3 2475.3 314.03 2320.6 2634.6 1.0158 6.6655 7.6812 80 47.42 0.001029 3.4053 334.97 2146.6 2481.6 335.02 2308.0 2643.0 1.0756 6.5355 7.6111 85 57.87 0.001032 2.8261 355.96 2131.9 2487.8 356.02 2295.3 2651.4 1.1346 6.4089 7.5435 90 70.18 0.001036 2.3593 376.97 2117.0 2494.0 377.04 2282.5 2659.6 1.1929 6.2853 7.4782 95 84.61 0.001040 1.9808 398.00 2102.0 2500.1 398.09 2269.6 2667.6 1.2504 6.1647 7.4151 100 101.42 0.001043 1.6720 419.06 2087.0 2506.0 419.17 2256.4 2675.6 1.3072 6.0470 7.3542 ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ 360 18666 0.001895 0.006950 1726.16 625.7 2351.9 1761.53 720.1 2481.6 3.9165 1.1373 5.0537 365 19822 0.002015 0.006009 1777.22 526.4 2303.6 1817.16 605.5 2422.7 4.0004 0.9489 4.9493 370 21044 0.002217 0.004953 1844.53 385.6 2230.1 1891.19 443.1 2334.3 4.1119 0.6890 4.8009 373.95 22064 0.003106 0.003106 2015.8 0 2015.8 2084.3 0 2084.3 4.4070 0 4.4070 TABLE:SaturatedSteam-PressureTable
  • 25. TABLE: Saturated Water-Pressure Table Press. P kPa Sat. Temp., Tsat oC Specific volume, m3/kg Internal energy, kJ/kg Enthalpy, kJ/kg Entropy, kJ/kg - K Sat. liquid, vf Sat. vapor, vg Sat. liquid, uf Evap., ufg Sat. vapor, ug Sat. liquid, hf Evap., hfg Sat. vapor, hg Sat. liquid, sf Evap., sfg Sat. vapor, sg 0.6117 0.01 0.001000 206.00 0.00 2374.9 2374.9 0.00 2500.9 2500.9 0.0000 9.1556 9.1556 1.0 6.97 0.001000 129.19 29.30 2355.2 2384.5 29.30 2484.4 2513.7 0.1059 8.8690 8.9749 1.5 13.02 0.001001 87.964 54.69 2338.1 2392.8 54.69 2470.1 2524.7 0.1956 8.6314 8.8270 2.0 17.50 0.001001 66.990 73.43 2325.5 2398.9 73.43 2459.5 2532.9 0.2606 8.4621 8.7227 2.5 21.08 0.001002 54.242 88.42 2315.4 2403.8 88.42 2451.0 2539.4 0.3118 8.3302 8.6421 3.0 24.08 0.001003 45.654 100.98 2306.9 2407.9 100.98 2443.9 2544.8 0.3543 8.2222 8.5765 4.0 28.96 0.001004 34.791 121.39 2293.1 2414.5 121.39 2432.3 2553.7 0.4224 8.0510 8.4734 5.0 32.87 0.001005 28.185 137.75 2282.1 2419.8 137.75 2423.0 2560.7 0.4762 7.9176 8.3938 7.5 40.29 0.001008 19.233 168.74 2261.1 2429.8 168.75 2405.3 2574.0 0.5763 7.6738 8.2501 10 45.81 0.001010 14.670 191.79 2245.4 2437.2 191.81 2392.1 2583.9 0.6492 7.4996 8.1488 15 53.97 0.001014 10.020 225.93 2222.1 2448.0 225.94 2372.3 2598.3 0.7549 7.2522 8.0071 20 60.06 0.001017 7.6481 251.40 2204.6 2456.0 251.42 2357.5 2608.9 0.8320 7.0752 7.9073 25 64.96 0.001020 6.2034 271.93 2190.4 2462.4 271.96 2345.5 2617.5 0.8932 6.9370 7.8302 30 69.09 0.001022 5.2287 289.24 2178.5 2467.7 289.27 2335.3 2624.6 0.9441 6.8234 7.7675 40 75.86 0.001026 3.9933 317.58 2158.8 2476.3 317.62 2318.4 2636.1 1.0261 6.6430 7.6691 50 81.32 0.001030 3.2403 340.49 2142.7 2483.2 340.54 2304.7 2645.2 1.0912 6.5019 7.5931 75 91.76 0.001037 2.2172 384.36 2111.8 2496.1 384.44 2278.0 2662.4 1.2132 6.2426 7.4558 100 99.61 0.001043 1.6941 417.40 2088.2 2505.6 417.51 2257.5 2675.0 1.3028 6.0562 7.3589 125 105.97 0.001048 1.3750 444.23 2068.8 2513.0 444.36 2240.6 2684.9 1.3741 5.9100 7.2841 ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ ٠ 20,000 365.75 0.002038 0.005862 1785.84 509.0 2294.8 1826.59 585.5 2412.1 4.0146 0.9164 4.9310 21,000 369.83 0.002207 0.004994 1841.62 391.9 2233.5 1887.97 450.4 2338.4 4.1071 0.7005 4.8076 22,000 373.71 0.002703 0.003644 1951.65 140.8 2092.4 2011.12 161.5 2172.6 4.2942 0.2496 4.5439 22,064 373.95 0.003106 0.003106 2015.8 0 2015.8 2084.3 0 2084.3 4.4070 0 4.4070 • The last entry is the critical point at 22.064MPa
  • 26. Superheated Water Table - A substance is said to be superheated if the given temperature is greater than the saturation temperature for the given pressure • In the superheated water Table, T and P are the independent properties • The value of temperature to the right of the pressure is the saturation temperature for the pressure - The first entry in the table is the saturated vapor state at the pressure
  • 27. • A substance is said to be a compressed liquid when the pressure is greater than the saturation pressure for the temperature. • It is now noted that state 1 is called a compressed liquid state because the saturation pressure for the temperature T1 is less than P1 Compressed Liquid Water Table
  • 28. • The plot of total heat against entropy, is more widely used than any other entropy diagram, since the work done on vapor cycles can be scaled from this diagram directly as a length; whereas on T-s diagram it is represented by an area ENTHALPY-ENTROPY (h-s) CHART OR MOLLIER DIAGRAM • Lines of constant pressure are indicated by p1, p2 etc., lines of constant temperature by T1, T2, etc • Any two independent properties which appear on the chart are sufficient to define the state (e.g., p1 and x1 define state 1 and h can be read off the vertical axis) • In the superheat region, pressure and temperature can define the state (e.g., p3 and T4 define the state 2, and h2 can be read off) • A line of constant entropy between two state points 2 and 3 defines the properties at all points during an isentropic process between the two states
  • 29. • For any state, at least two properties should be known to determine the other unknown properties of steam at that state • The Mollier diagram is used only when quality is greater than 50% and for superheated steam
  • 30. Example: Find the specific volume, enthalpy and internal energy of wet steam at 18 bar with dryness fraction (x) = 0.85, by using Steam Tables and Mollier chart. Solution: Given: Pressure of steam, p= 18 bar; Dryness fraction, x= 0.85 (a) By using steam tables (for dry saturated steam): at 18 bar pressure, we have: ts = 207.11°C, hf = 884.5 kJ/kg, hg = 2794.8 kJ/kg, hfg = 1910.3 kJ/kg, vg= 0.110 m3/kg (i) Specific volume of wet steam, v : = x.vg Answer: v = x.vg =0.85 x 0.110 = 0.0935 m3/kg (ii) Specific enthalpy of wet steam, h = hf + xhfg Answer: h = hf + xhfg= 884.6 + 0.85 x 1910.3 = 2508.35 kJ/kg. (iii) Specific internal energy of wet steam, u = h – pv Answer: u = h – pv= 2508.35 – 18 x 102 (0.0935) = 2340.75 kJ/kg
  • 31. Locate point ‘1’ at an intersection of 18 bar pressure line and 0.85 dryness fraction line. Read the value of enthalpy (h) and specific volume (v) from Mollier diagram corresponding to point ‘1’. (i) Specific enthalpy of wet steam, h = 2508 KJ/kg (ii) Specific volume of wet steam, v = 0.0935 m3/kg (iii) Specific Internal energy of wet steam, u = h – pv = 2508 – 18 x 102 (0.0935) = 2340 kJ/kg
  • 32. The definition of quality x m m m m m g g f g = = + Then m m m m m x f g = − = −1 - Note, quantity 1- x is often given the name moisture - The specific volume of the saturated mixture becomes v = (1 - x) vf + x vg - The average specific volume at any state 3 is given in terms of the quality as follows Consider a mixture of saturated liquid and saturated vapor The liquid has a mass mf and occupies a volume Vf = mf vf The vapor has a mass mg and occupies a volume Vg = mg vg Note V = Vf + Vg m = mf + mg V = mass * specific volume = m.v = mfvf + mgvg ; v = #$ &$ # + #'&' #
  • 33. The form that is most often used v = vf + x (vg - vf) • It is noted that the value of any extensive property per unit mass in the saturation region is calculated from an equation having a form similar to that of the above equation • Let Y be any extensive property and let y be the corresponding intensive property, Y/m, then y Y m y x y y y x y where y y y f g f f fg fg g f = = + − = + = − ( ) • The term yfg is the difference between the saturated vapor and the saturated liquid values of the property y; y may be replaced by any of the variables v, u, h, or s • We often use the above equation to determine the quality x of a saturated liquid-vapor state • The following application is called the Lever Rule: x y y y f fg = −
  • 34. Measurement of dryness fraction • The quality of wet steam is defined by its dryness fraction • When the dryness fraction, pressure and temperature of the steam are known, then the state of wet steam is fully defined • In a steam plant it is at times necessary to know the state of the steam • Many of the steam prime-movers are supplied with superheated steam • The enthalpy (total heat) of such a steam is readily determined when its pressure and temperature are known • However, there are many cases in which saturated steam or wet steam is supplied • The measurement of its temperature, when pressure is known, simply confirms the fact that the steam is saturated or wet - In no way it gives any information as to either the quality of steam or the enthalpy of steam - For wet steam, this entails finding the dryness fraction
  • 35. • To aid in the determination of the quality (dryness fraction) of wet steam, various types of steam calorimeters have been devised • The types of colorimeters used for this purpose are : -Throttling calorimeter - Steam that is nearly dry - Separating calorimeter - Steam is very wet - Combined Separating and Throttling calorimeter
  • 36. Throttling Calorimeter The steam to be sampled is taken from the pipe by means of suitable positioned and dimensioned sampling tube It passes into an insulated container and is throttled through an orifice to atmospheric pressure Here the temperature is taken and the steam ideally should have about 5.5 K of superheat The throttling process is shown on h-s diagram by the line 1-2
  • 37. • If steam initially wet is throttled through a sufficiently large pressure drop, then the steam at state 2 will become superheated • State 2 can then be defined by the measured pressure and temperature • The enthalpy, h2 can then be found and hence h2 = h1= (hf1 + x1hfg1) at p1 Where, h2 = hf2 + hfg2 + cps (Tsup2 −Ts2)] ∴ x1 = h2 − hf1 / hfg2 Hence the dryness fraction is determined and state 1 is defined
  • 38. • Since mechanical separation of suspended water particles from wet steam cannot be perfect, a separating calorimeter is not so accurate as a throttling calorimeter • The operation of the throttling calorimeter depends on the steam being superheated after throttling and it will fail in its purpose, if the steam is so wet before throttling that it remains wet after throttling • Therefore, a very successful method of measuring the dryness fraction of very wet steam is by a combined separating and throttling calorimeter • If the steam whose dryness fraction is to be determined is very wet then throttling to atmospheric pressure may not be sufficient to ensure superheated steam at exit • In this case it is necessary to dry the steam partially, before throttling, This is done by passing the steam sample from the main through a separating calorimeter Separating and Throttling Calorimeter
  • 39. The steam is made to change direction suddenly, and the water, being denser than the dry steam is separated out The quantity of water which is separated out (mw) is measured at the separator the steam remaining, which now has a higher dryness fraction, is passed through the throttling calorimeter With the combined separating and throttling calorimeter it is necessary to condense the steam after throttling and measure the amount of condensate (ms) If a throttling calorimeter only is sufficient, there is no need to measure condensate, the pressure and temperature measurements at exit being sufficient
  • 40.
  • 41. • A detailed study of the heating process reveals that the temperature of the solid rises and then during the change of phase from solid to liquid (or solid to vapour) the temperature remains constant - This phenomenon is common to all phase changes • Since the temperature is constant, pressure and temperature are not independent properties and cannot be used to specify state during a change of phase • The combined picture of change of pressure, specific volume and temperature may be shown on a three dimensional state model - illustrates the equilibrium states for a pure substance which expands on fusion - Water is an example of a substance that exhibits this phenomenon The P-V-T Surface for a Real Substance
  • 42. • All the equilibrium states lie on the surface of the model • States represented by the space above or below the surface are not possible • It may be seen that the triple point appears as a line in this representation • The point C.P. is called the critical point and no liquid phase exists at temperatures above the iso- therms through this point - The term evaporation is meaningless in this situation • At the critical point the temperature and pressure are called the critical temperature and the critical pressure respectively - When the temperature of a substance is above the critical value, it is called a gas • It is not possible to cause a phase change in a gas unless the temperature is lowered to a value less than the critical temperature - Oxygen and nitrogen are examples of gases that have critical temperatures below normal atmospheric temperature
  • 43. • Real substances that readily change phase from solid to liquid to gas such as water, refrigerant-134a, and ammonia cannot be treated as ideal gases in general • The pressure, volume, temperature relation, or equation of state for these substances is generally very complicated, and the thermodynamic properties are given in table form • The properties of these substances may be illustrated by the functional relation F (P,v,T)=0, called an equation of state State Postulate - The state postulate for a simple, pure substance states that the equilibrium state can be determined by specifying any two independent intensive properties
  • 44. P-V-T Surface for a Substance that contracts upon freezing P-V-T Surface for a Substance that expands upon freezing • These figures show three regions where a substance like water may exist as a solid, liquid or gas (or vapor) • Also these figures show that a substance may exist as a mixture of two phases during phase change, solid-vapor, solid-liquid, and liquid-vapor • Water may exist in the compressed liquid region, a region where saturated liquid water and saturated water vapor are in equilibrium (called the saturation region), and the superheated vapor region (the solid or ice region is not shown)
  • 45. • Property tables give data for - Temperature - Pressure - Volume - Specific internal energy u - Specific enthalpy h - the specific entropy s • The enthalpy is a convenient grouping of the internal energy, pressure, and volume and is given - H = U + PV - enthalpy per unit mass is h = u + Pv • The enthalpy h is quite useful in calculating the energy of mass streams flowing into and out of control volumes • The enthalpy is also useful in the energy balance during a constant pressure process for a substance contained in a closed piston-cylinder device Property Tables
  • 46. • Saturation pressure is the pressure at which the liquid and vapor phases are in equilibrium at a given temperature • Saturation temperature is the temperature at which the liquid and vapor phases are in equilibrium at a given pressure • The subscript fg used in tables, refers to the difference between the saturated vapor value and the saturated liquid value region - That is, u u u h h h s s s fg g f fg g f fg g f = − = − = − • The quantity hfg is called the enthalpy of vaporization (or latent heat of vaporization) • It represents the amount of energy needed to vaporize a unit of mass of saturated liquid at a given temperature or pressure • It decreases as the temperature or pressure increases, and becomes zero at the critical point
  • 47. The Lever Rule is illustrated in the following figures Superheated Water Table - A substance is said to be superheated if the given temperature is greater than the saturation temperature for the given pressure • In the superheated water Table, T and P are the independent properties • The value of temperature to the right of the pressure is the saturation temperature for the pressure - The first entry in the table is the saturated vapor state at the pressure
  • 48. Is ? Is ? Is ? v v v v v v v f f g g < < < < The answer to one of these questions must be yes - If the answer to the first question is yes, the state is in the compressed liquid region, and the compressed liquid tables are used to find the properties of the state - If the answer to the second question is yes, the state is in the saturation region, and either the saturation temperature table or the saturation pressure table is used to find the properties. Then the quality is calculated and is used to calculate the other properties, u, h, and s - If the answer to the third question is yes, the state is in the superheated region and the superheated tables are used to find the other properties The correct table to use to find the thermodynamic properties of a real substance can always be determined by comparing the known state properties to the properties in the saturation region. Given the temperature or pressure and one other property from the group v, u, h, and s, the following procedure is used. For example if the pressure and specific volume are specified, three questions are asked: For the given pressure, How to Choose the Right Table Some tables may not always give the internal energy. When it is not listed, the internal energy is calculated from the definition of the enthalpy as, u = h - Pv