ITK-233 Termodinamika Teknik Kimia I
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Transcript of ITK-233 Termodinamika Teknik Kimia I
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DICKY DERMAWANwww.dickydermawan.net78 .net
d ickydermawan@gmai l .com
ITK-233Termodinamika Teknik
Kimia I
3 SKS
5 – Relations among Thermodynamic Properties & Properties Diagrams
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State Principle
The only measurable property is P, T & VHow we can find U, H, S, … from this?
We already have:
.....)orT&SorV&PorV&TorP&T(f)propertyAny( ncompositiophase
PT
V
V
1
TP
V
V
1
VV T
UC
P
P T
HC
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Fundamental Relations
TSHG
TSUA
PVUH
U
dPVdTSdG
dVPdTSdA
dPVdSTdH
dVPdSTdU
)P,T(GG
)V,T(AA
)P,S(HH
)V,S(UU
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Mathematical Formulation (1)
yx
2
yxxy
x
y
x
N
y
M
yx
z
y
z
xx
z
y
y
zN
x
zM
dyNdxMdz
)y,x(zz
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Mathematical Formulation (2)
dzz
ydx
x
ydy)z,x(yy
dzz
xdy
y
xdx)z,y(xx
)y,x(zz)z,x(yy)z,y(xx)z,y,x(ff
xz
yz
Elimination of the differential dy gives:
0dzz
x
z
y
y
xdx1
x
y
y
x
yxzzz
Since dx and dz are independent, the coefficient of dx and dz must be zero, thus:
z
z
xy1
y
x
x
z
y
yz
yx
z
x
and:
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Fundamental Relations
dPVdTSdG
dVPdTSdA
dPVdSTdH
dVPdSTdU
...
...
...
PV
U&T
S
U
SV
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Fundamental Properties & Maxwell Relations
dPVdTSdG
dVPdTSdA
dPVdSTdH
dVPdSTdU
...
...
....
S
P
V
T
VS
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Example H=H(T,P)
a. How does enthalpy affected by temperature and pressure?
b. Prove that c. Use the result of (a) to prove that enthalpy of ideal
gas is affected only by temperature.
d. State H=H(T,P) for virial gas:
e. State H=H(T,P) for real gas:
dPV)T1(dTCdH P
...P'DP'CP'B1(RTPV 32
RT
PVZ
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Example: S=S(T,P)
a. How does entropy affected by temperature and pressure?
b. Prove that
c. Show that for ideal gas 1
2
T
T
P
P
PlnRdT
T
CS
2
1
dPVdTT
CdS P
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Example: U=U(T,V)
a. How does internal energy affected by temperature and volume?
b. Express the results of (a) in term of β and κ
c. Use the result of (a) to prove that internal energy of ideal gas is not affected by pressure
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Example: S=S(T,V)
a. How does entropy affected by temperature and volume?
b. Express the results of (a) in term of β and κ
c. Show that for ideal gas with constant Cv:
1
2
1
2v V
VlnR
T
TlnCS
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Gibbs Energy as Generating Function
a. Prove that
b. c.
d.
TP
)RT/G(
RT
V
PT
)RT/G(T
RT
H
RT
G
RT
H
R
S
RT
PV
RT
H
RT
U
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Cp, Cv & Pressure Effect
The Joule-Thomson coefficient: is important in refrigeration engineering. Show that it can be calculated using:
Prove that:
Prove that:
P
2
2
T
P
T
VT
P
C
PVVP T
V
T
PTCC
HP
T
PPH T
VTV
C
1
P
T
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Example: U = U(T,P)
a. Prove that
b. Prove that the internal energy of ideal gas is not affected by pressure
c. Prove that
V)TP(P
U
T
V)PT(CT
UV
P
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Thermodynamic Property Diagrams
Represents properties: P, V, T, H & S of a substance on a single plot.
The most common:T/S DiagramP/H DiagramH/S (Mollier diagram)
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T – S Diagram of Air
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T – S Diagram of CO
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T – S Diagram of CO2
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P-H Diagram of Ammonia
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P-H Diagram of
Chlorine
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H/S (Mollier Diagram) for NO
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H/S (Mollier Diagram) for Water
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Example 6.6
a. Superheated steam originally at 150 psia & 500 oF expands through a nozzle to an exhaust pressure of 50 psia. Assuming the process is reversible & adiabatic, determine the downstream state of the steam and ΔH.
b. Repeat problem (a) if the process is irreversible with thermodynamic efficiency of 88%.