Acentric Factor Estimation From The Corresponding States Principle
Acentric Factor Estimation From The Corresponding States Principle
Acentric Factor Estimation From The Corresponding States Principle
UDC 541.67:532.11
Note
NOTE
(1)
w2 : 2
(2)
where Tr = T/Tc is the reduced temperature and prs = ps/pc is the reduced vapor pressure.
Pitzer et al.1 (PLCHP), Chao et al.3 (CGOH), Carruth and Kobayashi4 (CK),
and His and Lu5 (HL) have reported their values of f(0) and f(1) (Table I). Lee and
Kesler6 (LK) have reported their analytical expressions of f(0) and f(1) in the form
of a Riedel type of vapor pressure equation
f(1)
(3)
(4)
Ambrose and Walton7 (AW) have reported their analytical expressions of f(0),
and f(2) in the form of a Wagner type of vapor pressure equation
doi: 10.2298/JSC0603213G
213
214
GROZDANI]
(8)
(9)
Brandani9 has reported two sets of analytical expressions in the form of a Wagner type of vapor pressure equation, as follows. One for the relation (Eq. 1) (BI)
f(0) (Tr) = [ 6.25914 (1 Tr) + 2.33303 (1 Tr)1.5 2.53374 (1 Tr)2.5 +
(10)
+ 3.09743 (1 Tr)5 8.34044 (1 Tr)10] / Tr
f(1) (Tr) = [ 4.27201 (1 Tr) 1.79968 (1 Tr)1.5 0.49821 (1 Tr)2.5
(11)
24.37590 (1 Tr)5 + 31.32263 (1 Tr)10] / Tr
and the other for relation (Eq. 2) (BII)
f(0) (Tr) = [ 6.25914 (1 Tr) + 2.33303 (1 Tr)1.5 2.53374 (1 Tr)2.5 +
(12)
+ 3.09743 (1 Tr)5 8.34044 (1 Tr)10] / Tr
f(1) (Tr) = [ 5.65777 (1 Tr) + 1.91392 (1 Tr)1.5 3.75173 (1 Tr)2.5
(13)
18.16398 (1 Tr)5 + 18.74981 (1 Tr)10] / Tr
f(2) (Tr) = [3.81370 (1 Tr) 10.05038 (1 Tr)1.5 + 10.94146 (1 Tr)2.5
(14)
13.17857 (1 Tr)5 + 0.18671 (1 Tr)10] / Tr
Twu et al.10 (TCC) have reported their analytical expressions of f(0) and f(1) in
the form of a Wagner type of vapor pressure equation
f(0) (Tr) = [ 5.96346 (1 Tr) + 1.17639 (1 Tr)1.5 0.559607 (1 Tr)3
(15)
1.31901 (1 Tr)6] / Tr
f(1) (Tr) = [ 4.78522 (1 Tr) + 0.413999 (1 Tr)1.5 8.91239 (1 Tr)3
(16)
4.98662 (1 Tr)6] / Tr
In order to avoid interpolation, the values of f(0) and f(1) from Table I were correlated by the Brandani type of Wagner relation for vapor pressure
215
(17)
Tr
PLCHP
CGOH
f(1)
CK
HL
PLCHP
CGOH
CK
0.250
15.312
36.611
0.260
14.690
32.812
0.270
14.138
30.164
0.280
13.608
27.539
0.290
13.079
25.144
0.300
12.549
22.888
0.310
12.019
20.677
0.320
11.524
19.111
0.330
11.052
17.615
0.340
10.592
16.302
0.350
10.408 10.154
13.654 15.289
0.360
9.717
14.368
0.370
9.302
13.539
0.375
9.279
0.380
0.400
8.243
0.410
0.420
0.425
12.572
8.911
0.390
12.802
8.520
12.158
8.151
11.375 11.536
7.794
10.983
7.460
10.454
7.391
9.993
0.430
7.138
9.947
0.440
6.839
9.441
0.450
6.631
0.460
0.475
7.622
5.556
5.330
0.510
5.107
0.520
4.905
0.530
8.174
7.645
5.791
5.365
8.980
8.508
6.033
0.490
0.525
8.635
5.964
0.480
0.500
6.562
6.286
0.470
HL
4.858
7.207
5.372
6.701
6.820
6.475
4.948
6.125
5.826
4.697
6.507
5.761
5.816
216
GROZDANI]
TABLE I. Continued
f(0)
Tr
PLCHP
CGOH
0.540
0.550
0.560
4.398
3.868
3.574
3.555
3.283
3.279
3.012
3.012
0.660
4.329
4.393
3.553
3.914
3.937
3.270
3.546
3.557
3.009
3.201
3.201
2.524
2.524
3.887
3.749
3.495
3.369
3.092
3.039
2.761
2.878
2.878
2.777
2.729
2.531
2.579
2.411
2.303
4.299
4.168
2.636
0.690
4.746
4.651
2.878
2.758
5.162
3.866
3.150
2.758
HL
5.234
4.881
3.419
0.670
0.680
5.158
CK
5.457
4.789
3.707
0.650
CGOH
4.198
4.023
0.630
0.640
PLCHP
4.352
3.887
0.610
0.620
HL
4.564
4.186
0.590
0.600
CK
4.525
4.223
0.570
0.580
f(1)
2.579
2.482
2.441
0.700
2.303
2.303
2.303
0.720
2.093
2.091
2.061
2.026
0.740
1.895
1.895
1.842
1.817
0.760
1.709
1.704
1.623
1.633
0.780
1.531
1.529
1.428
1.428
0.800
1.363
1.361
1.255
1.248
0.820
1.202
1.094
0.840
1.048
0.933
0.860
0.900
0.794
0.880
0.760
0.656
0.900
0.622
0.530
0.920
0.488
0.414
0.940
0.359
0.306
0.950
0.297
0.251
0.960
0.235
0.198
0.970
0.175
0.147
0.980
0.115
0.097
0.990
0.058
0.048
1.000
0.000
0.000
2.303
2.303
7.6151 10-1
5.9709 101
0.39
2.15
1.0839 101
1.2703 102
0.00113
0.16
1.15
s[1]
pav[%]
pmax[%]
0.00455
0.23
0.09
0.0135
2.8799 101
1.9255 101
1.00
0.41
0.0654
3.9425 102
1.9331 102
1.8019
102
0.52
0.22
0.0164
2.2373 101
8.7988 100
3.1917
100
1.4536
101
6.7016
100
1.4580
CK
f(1)
f(0)
HL
f(1)
2.72
1.26
0.177
1.1824 102
4.4772 101
4.1098
101
2.5055 101
0.29
0.11
0.00422
5.0205 101
1.1093 101
4.3672
100
1.9991 100
1.84
0.81
0.0301
2.4422 102
3.2449 101
2.6509 101
1.5711 101
f(0)
1.2509 100
100
f(1)
Model
5.7745 101
CGOH
4.4335 10-1
f(0)
f(1)
PLCHP
f(0)
218
GROZDANI]
s = (w exp,i - w cal ,i ) 2 / (n - m )
i=1
0 .5
(18)
(19)
i =1
(20)
w = [f(1)(Tbr) d]/[2f(2)(Tbr)]
(21)
(22)
All expression were tested on the selected substances from Table III. The values in this table are from Poling et al..11 The results are presented in Table IV.
TABLE III. Experimental data reported in the literature11
i
n-Alkanes
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
Substances
Tb/K
Tc/K
Tbr
pc
Methane
Ethane
Propane
Butane
Pentane
Hexane
Heptane
Octane
Nonane
Decane
Undecane
Dodecane
Tridecane
Tetradecane
Pentadecane
Hexadecane
Heptadecane
111.66
184.55
231.02
272.66
309.22
341.88
371.57
398.82
423.97
447.30
469.08
489.48
508.63
526.76
543.83
559.98
574.56
190.56
305.32
369.83
425.12
469.70
507.60
540.20
568.70
594.60
617.70
639.00
658.00
675.00
693.00
708.00
723.00
736.00
0.59
0.60
0.62
0.64
0.66
0.67
0.69
0.70
0.71
0.72
0.73
0.74
0.75
0.76
0.77
0.77
0.78
45.99
48.72
42.48
37.96
33.70
30.25
27.40
24.90
22.90
21.10
19.80
18.20
16.80
15.70
14.80
14.00
13.40
0.011
0.099
0.152
0.200
0.252
0.300
0.350
0.399
0.445
0.490
0.537
0.576
0.618
0.644
0.685
0.718
0.753
219
Tb/K
Tc/K
Tbr
pc
18
Octadecane
588.30
747.00
0.79
12.90
0.800
19
Nonadecane
602.34
755.00
0.80
11.60
0.845
20
Eicosane
616.84
768.00
0.80
10.70
0.865
21
2,2-Dimethylbutane
322.87
488.70
0.66
30.80
0.233
22
2,3-Dimethylbutane
331.12
499.90
0.66
31.30
0.248
23
2,2,3-Trimethylbutane
354.01
531.10
0.67
29.50
0.250
24
2,2,3,3-Tetramethylbutane
379.44
567.80
0.67
28.70
0.248
25
2-Methylpentane
333.40
497.50
0.67
30.10
0.278
26
3-Ethylhexane
391.69
565.40
0.69
26.10
0.362
27
4-Methylheptane
390.86
561.70
0.70
25.40
0.371
28
3,3,5-Trimethylheptane
428.83
609.60
0.70
23.20
0.383
240.34
398.25
0.60
55.75
0.130
i
n-Alkanes
i-Alkanes
Cycloalkanes
29
Cyclopropane
30
Cyclobutane
285.64
460.00
0.62
49.90
0.185
31
Cyclohexane
353.93
553.50
0.64
40.73
0.211
32
Cyclooctane
424.31
647.20
0.66
35.70
0.254
33
Ethylcyclopentane
376.59
569.50
0.66
33.97
0.270
34
Methylcyclohexane
374.09
572.19
0.65
34.71
0.235
Propene
225.46
364.90
0.62
46.00
0.142
36
1-Butene
266.92
419.50
0.64
40.20
0.194
37
1-Hexene
336.63
504.00
0.67
31.43
0.281
38
1-Octene
394.44
567.00
0.70
26.80
0.393
Ethyne
188.40
308.30
0.61
61.14
0.189
40
Benzene
353.24
562.05
0.63
48.95
0.210
41
Toluene
383.79
591.75
0.65
41.08
0.264
42
1,4-Dimethylbenzene
411.53
616.20
0.67
35.11
0.322
43
Naphthalene
491.16
748.40
0.66
40.50
0.304
44
Anthracene
614.39
869.30
0.71
28.70
0.501
Alkylcycloalkanes
Alkenes
35
Alkynes
39
Aromatics
From the values for Tbr from Table III it follows that the Chao et al.3 expressions
(Table II) are not applicable to any of the substances from this Table, while the Carruth
220
GROZDANI]
and Kobayashi4 expressions (Table II) are not applicable to some of the substances.
From the results presented in Table IV, it can be concluded that the Ambrose and
Walton7 expressions (Eqs. 57) have the best predictive characteristics.
TABLE IV. Comparison of the predicted and literature values of w
Expressions
pav/%
Expressions
pav/%
PLCHP
CGOH
Expressions
pav/%
1.96
LK
AW
1.59
BI
1.14
0.42
BII
0.80
CK
1.41
SP
HL
2.02
1.39
TCC
0.88
NOTATION
n
m
T
p
ps
pav
pmax
Greek letters
w
s
Acentric factor
Standard deviation
Subscripts
b
c
r
exp
cal
Boiling property
Critical property
Reduced property
Experimental value
Calculated value
IZVOD
U ovom radu razmotrene su mogu}nosti predskazivawa vrednosti faktora acentri~nosti na bazi principa korespondentnih stawa. Prikazane su predlo`ene funkcije, f(0), f(1) i f(2), kako u diskretnoj, tako i analiti~koj formi. Diskretne vrednosti su
korelisawem prevedene u analiti~ke izraze. Predskazivawe vrednosti faktora acentri~nosti testirano je na 44 nepolarne supstance. Najboqe pridiktivne osobine
pokazao je model koji su predlo`ili Ambrose i Walton.
(Primqeno 12. aprila, revidirano 3. juna 2005)
221
REFERENCES
1. K. S. Pitzer, D. Z. Lippmann, R. F. Curl, C. M. Huggins, D. E. Petersen, J. Am. Chem. Soc. 77
(1955) 3433
2. G. Z. A. Wu, L. I. Stiel, AIChE J. 31 (1985) 1632
3. K. C. Chao, R. A. Greenkorn, O. Olabisi, B. H. Hensel, AIChE J. 17 (1971) 353
4. G. F. Carruth, R. Kobayashi, Ind. Eng. Chem. Fundam. 11 (1972) 509
5. C. Hsi, B. C.-Y. Lu, AIChE J. 20 (1974) 109
6. B. I. Lee, M. G. Kesler, AIChE J. 21 (1975) 510
7. D. Ambrose, J. Walton, Pure & Appl. Chem. 61 (1989) 1395
8. D. R. Schreiber, K. S. Pitzer, Fluid Phase Equilib. 46 (1989) 113
9. S. Brandani, Ind. Eng. Chem. Res. 32 (1993) 756
10. C. H. Twu, J. E. Coon, J. R. Cunningham, Fluid Phase Equilib. 96 (1994) 19
11. B. E. Poling, J. M. Prausnitz, J. P. OConnell, The Properties of Gases and Liquids, McGraw-Hill,
New York, 2001.