Thermal conductivity measurements of methane in the dense gaseous state

. Physica 32 885-899

Misic, D. Thodos, G. 1966

THERMAL CONDUCTIVITY MEASUREMENTS OF METHANE IN THE DENSE GASEOUS STATE by D. MISIC Northwestern

University,

and G. THODOS Evanston,

Illinois,

U.S.A.

Synopsis The thermal conductivity of methane has been measured at 1.9, 24.6, 43.6 and 75.1 “C and pressures up to 580 atm with a coaxial cylindrical cell. For each of these temperatures, the thermal conductivity - reduced density relationships have been developed and have been used to establish the corresponding (k/p~)~l~ values. These values have been utilized to calculate thermal conductivities predicted from the Enskog theory. The measured thermal conductivity values also have been used to produce the relationships of k - k* versus pi and k - k* versus (LJPR/XR),,~ for methane. These relationships also include the thermal conductivity values of other investigators which were found in good agreement with the results of the present study. The experimental results of this investigation for the dense gaseous state assist to establish a continuous unique relationship between the gaseous and liquid states of metahne.

Intro&&on. To establish the thermal conductivity behavior of gases and liquids, reliable experimental data are essential. Such data become very valuable in practical applications and in the testing of theoretical models. In the present expertiental study, methane was arbitrarily selected to be investigated since for this substance thermal conductivity measurements are meager. Experimental values by Lenoir and Comingsr7) are restricted to 41.1X and pressures up to 200 atm, while those of Lenoir, Junk, and Comings 18) were taken at 52.8% and also pressures up to 200 atm. The early work of Keyesrs)

was conducted

at 50, 150, 250 and 300°C and

pressures only up to 60 atm, while his later work14) includes the low temperature region of - 152.7, - 101.9 and 0°C and pressures no higher than 9 atm. In 1950, Stolyarov, Ipatiev and Teodorovichs*) reported experimental thermal conductivities for methane between 20 and 200°C and pressures up to 500 atm. Their data do not exhibit good internal consistency indicating the presence of experimental difficulties in their study. The latest experimental thermal conductivity measurements of Ikenberry and Ricera) for methane in the dense gaseous and liquid regions are valuable because they extend the experimental data of this study from the dense gaseous region into the liquid region for this substance. -

885 -

886

D. MISIC AND G. THODOS

Experimental

eqtiipment and procedure.

The experimental

unit consisted

of a coaxial cylindrical cell having an annular gap of 0.0254 cm. and an outside diameter of the inner cylinder of 1.8898 cm. The total length of the assembled

cell was 35.56 cm and the outside diameter

was 8.57 cm. This cell was designed to withstand A detailed

description

of the cell and associated

elsewhere 21) 22). However,

of the outer cylinder

pressures up to 1700 atm. equipment

a minor change in the pressurizing

is presented procedure was

followed since the methane was available in quart size cylinders only at a pressure of not more than 80 atm. In this study, a prescribed amount of methane was condensed in a thermal expansion cell immersed in liquid nitrogen. This cell was constructed of 316 stainless steel which had been tested for pressures up to 1200 atm. After allowing the cell to reach room temperature, the gaseous methane, now available at pressures up to 700 atm. was slowly transferred directly either to the thermal conductivity cell or to the pressurizing vessel connected to the Ruska pump. The procedure then followed was identical to that outlined in the parent articlesa).

Fig. 1. Relationships

between

and 75.1 “C for methane

thermal

resulting

conductivity

from the experimental

and pressure

at

measurements

1.9, 24.6, 43.6 of this study.

THERMAL

Analysis

CONDUCTIVITY

The procedure

of data.

887

OF METHANE

used to calculate

thermal

conductivities

for methane was the same as that outlined previously for a similar study with nitrogenss) The contributions due to natural convection and radiation were kept perimental

to a minimum measurements.

and were well within A pressure correction

the accuracy of the exwas applied to the raw

thermal conductivity values, ka, to account for the pressure cell dimensions. This correction was calculated to be k = ka[ 1 + 2.464

effect

on the

x lo-s] P

(1)

where P is the pressure in psia. The resulting experimental thermal conductivities for methane are tabulated in tables I, II, III and IV for temperatures of 1.9. 24.6, 43.6 and 751°C respectively, and for pressures up to 577.7 atm. These values are plotted against pressure as shown in figure 1. The atmospheric thermal conductivity measurements of this study and those resulting from the values reported in the literature 4, 8, 11, 13, 14, 15, 17, 18, 1’9, 26, 27, 28, 30, 31, 32,33) are in good agreement. The atmospheric thermal conductivities resulting from these references are also presented in table I. In 1922, Enskogs), using principles of kinetic theory and a rigid spherical model, developed relationships for the transport properties of dense gases and liquids. For viscosity and thermal conductivity, these relationships are Application

of Ertskog

-= P

iu*

theory.

1

6

k -= k* To test his theory,

4

bP [ bPX + s + s

Enskog

+ +

0.7614

bpx

0.7574 bpx

1*I 1

(2)

.

was able to utilize only equation

that time, high pressure thermal conductivity

measurements

(2) because

at

were not availa-

ble. Using the high pressure viscosity measurements of W arburg and Baboss), Enskog obtained reasonable agreement between experimental values and viscosities calculated from his theory. For real gases Enskog proposed the following equation of state: P + up2 = %(I If a and b are assumed to be constant, with respect to temperature at constant

*) For the meaning

of the different

+bpx) equation (4) can be differentiated volume to produce the relationship

letters see the list at the end of this article.

0.313

0.440 0.555

0.625

0.675

0.718 0.795

0.960

1.06

1.26

1.26

1.27

1.40

1.53

1.84

1.90

82.2 99.3

109.9

118.7

124.5 137.1

164.3

183.4

229.6

230.0

232.4

273.7

328.3

517.9

572.6

0.190 0.280

40.1 56.5

0.313

0.165

35.0

62.3

0.091

20.0

62.3

0.0755

16.7

2.38 1

2.193

1.484

1.270

1.083

1.071

1.071

0.8353

0.7354

0.5234 0.5875

0.4887

0.450

0.3133 0.3985

0.2225

0.2225

0.1349 0.1988

0.1172

0.0646

0.0536

22.23

20.33

13.15

11.00

9.153

9.028

9.028

6.732

5.765

3.785 4.367

3.477

3.136

2.000 2.686

1.324

1.324

0.7462 1.162

0.6377

0.3353

0.2753

25.47

23.85

18.69

17.61

15.96

16.04

15.81

14.66

13.89

11.37 12.67

11.31

11.00

10.05 10.68

9.22

9.27

8.38 9.06

8.42

7.91

7.70

0.13

k’

17.95

16.33

11.17

10.09

8.44

8.52

8.29

7.14

6.37

3.85 5.15

3.79

3.48

2.53 3.16

1.70

1.75

0.86 1.54

0.90

0.39

0.26

I

1

useof

41.02

38.60

29.16

25.80

23.08

22.9 1

22.91

19.64

18.20

15.49 16.38

15.13

14.54

12.81 13.82

11.93

11.93

11.14 11.70

11.00

10.62

10.56

10.37

10.28

_._-.

10.28 X 10-s 10.28

1

data

33.88

32.02

24.56

21.80

19.50

19.36

19.32

16.53

15.25

12.78 13.60

12.44

11.89

10.25 11.22

9.36

9.36

8.54 9.13

8.50

7.96

7.08

7.64 x 10-b

11.46

33.00

34.26

31.39

23.80

22.17

20.70

22.18

12.77

9.82

12.43 7.32

10.01

8.07

2.00 5.05

1.52

0.97

1.94 0.78

0.99

0.57

1.26

-0.12

( % dev I

27.304

25.618

19.252

17.330

15.609

15.576

15.576

13.479

12.558

10.571 11.169

10.244

9.870

8.550 9.345

7.703

7.703

6.950 7.490

6.164

6.390

6.306

6.045

% 10-s

9.42

+

+

+

-

-

-

-

-

11.54

7.20

7.41

3.01

1.59

1.70

2.89

1.48

8.06

-11.75

- 7.03 - 11.85

-

- 10.27

- 14.92 - 12.50

- lb.45

- 16.90

- 17.06 - 17.24

- 26.79

- 19.22

- 18.95

- 20.98

use of Wp)mtn kcalc ( % dev

10-s cal ems/g s”K

at 1.9”C

12.34 x

kcnle

viscosity

=

for methane

(k/p)tin

quantities

I*, poises 5)

and related

0.00 x 10-s 0.00 0.00

0.0845

IO-6

k -

7.65

0.0170

kex,

7.57

0.024

1

1.02

1 (m&~R)pR

Cal/s cm OK

5.4

bPX

conductivities

10-s Cal/s cm°K

thermal

7.52 x

\

I

k’ = 7.52 x

and calculated

7.60

PR

Experimental

1.02

(

1.44

1.02

P, atm.

Tfi =

TABLE

889

THERMAL CONDUCTIVITY OF METHANE

By the substitutions,

p = pep~t P = PcP~

and T = T,TR,

can be expressed in terms of reduced parameters

equation

(5)

as follows:

Thus, in order to obtain bp~ values for a substance from equation

(6), PVT

data must be available for a substance over the range of interest. The reduced density correlation resulting from all available PVT measurements on methane (20) was used to produce PR versus TR relationships for reduced densities ranging from pR = 0.010 to pR = 3.00. The slopes resulting from these relationships were then used to calculate WRPTR),, the quantity 1 + bp~ using equation (6). The details of evaluating this quantity are identical to a similar study concerned with argon (2). The values of 1 + bp~ obtained for methane are plotted against reduced pressure, PR, to produce the isothermal relationships presented in figure 2. In this figure the range of reduced pressures extends up to PR = 20 and covers the temperature range 0.60 I TR 5 4.0.

METHANE (zO-0.289) T,=191.1 ‘K P,=45.6atm

Reduced

Pressure, e = $C

Fig. 2. Isothermal relationships between 1 + bpx and reduced pressure for methane.

Reliable values of bp~ for moderate pressures and pressures slightly above one atmosphere are obtained by plotting bpX/pR versus pR. For methane in the high density region, all the isotherms produce a single well defined relationship. However, in the low density region, considerable random scatter is encountered which results from the limitations to obtain dependable values of bpx from figure 2 at these conditions. An extension of the bpX/pR versus pR’relationship from the high density region to pR = 0, establishes the intercept bpX/pR = 0.71. The quantity bpx/pR = bpcX. At

1.34 1.42

1.54

1.63

1.69

1.78

306.5 341.0

405.2

454.2

499.1

567.1

0.845 1.00

171.1 205.1

1.13

0.750

152.4

1.24

0.697

139.7

272.5

0.585

120.0

238.5

0.335

0.395

73.2

0.312

69.1

85.4

0.226

51.6

2.0256

1.8066

1.6773

1.5030

1.1805 1.3007

1.0428

0.9108

0.6287 0.7730

0.5482

0.5067

0.4212

0.2808

0.2378

0.2215

0.1605

0.1037

18.630

16.413

15.100

13.335

10.109 11.306

0.764

7.470

4.762 6.135

4.018

3.634

2.877

1.751

1.435

1.319

0.9073

0.5577

22.98

21.84

20.87

19.85

17.69 18.67

16.81

15.96

13.41 14.74

12.22

12.48

11.12

9.99

9.69

9.78

9.12

8.64

8.41

0.146

0.1633 0.2524

34.4

0.0324

0.0695

0.0493

0.0457

16.8

/

8.18 8.49

/ (aPdaT&, 8.24

bpx

1.02 11.0

)

fl

x 10-s

kexp

Cal/s cm”K

1.02

pi

14.77

35.9 1

34.60

30.42

25.60 27.26

23.82

21.99

17.97 20.00

16.78

15.99

14.84

13.28

12.80

12.70

12.17

11.71

11.40

11.18 11.30

11.18

11.18

x 10-S

)

data

=

30.010

28.993

27.497

25.713

21.696 23.098

20.207

18.620

15.014 16.861

13.938

13.220

12.137

10.602

10.124

10.007

9.441

8.922

a.533

x 10-a

kealc

8.408

use of viscosity

12.77

for methane

WpJmtn

quantities

p, poisesb)

.13.63

I

related

32.65

x 10-j

k’

and

II

12.66

11.64

9.40 10.46

8.60

7.75

5.20 6.53

4.01

3.27

2.91

1.70

1.48

1.57

0.9 1

0.43

0.20

0.00 0.28

0.00

0.00

k -

conductivities

lo-5caljscm”K

thermal x

calculated k’ = 8.21

8.21

)

1.56

and

1.02

p, atm

TR =

Experimental

TABLE

14.27

30.59

32.75

31.75

29.54

22.65 23.72

20.21

16.67

11.96 14.39

14.06

5.93

9.14

6.13

4.48

2.32

3.52

3.26

1.46

-0.96

s”K

24.958

22.856

21.712

20.092

17.118 18.220

15.882

14.664

11.991 13.377

11.205

10.770

9.892

8.535

8.126

7.971

7.413

6.926

6.496

6.369

x 10-S

keal,

8.31

f

+

+

_

-

-

-

11.31

8.61

4.65

4.03

1.22

3.23 2.41

5.52

8.12

_ 10.58 _ 9.25

_

_ 13.70

-11.04

- 14.56

- 16.14

- 18.50

_ 18.72

- 19.84

- 22.76

- 24.98

j % dew

use of (klp),t.

10-G cal ems/g

/ % dev

x

at 24.6”C

THERMAL

CONDUCTIVITY

891

OF METHANE

pR = 0, x = 1, and therefore $JX/PR becomes the dimensionless group bp,. Since the critical molar density is pc = 0.162/l 6.042 = 0.010098 g-moles/cm3, the second virial coefficient becomes b = 0.7 1lo.01 0098 = 70.31 cm”/g-mole. This value produces the collision diameter (r = 3.82 x IO-8 cm, from the relationship b = 23zNa3/3. Hirschfelder, Curtiss, and Birds) present values of b = 70.16 cm3/g-mole and u. = 3.817 x 10-s cm.

Methane (z.=O289)

.

Fig. 3. Relationship between bpX/pR and pi for methane at 1.9, 24.6, 43.6 and 75.1 “C.

One approach to test the Enskog theory involves the use of experimental viscosity measurements corresponding to the temperature and pressure conditions of the thermal conductivity measurements. In this study the high pressure viscosity measurements of methane recently obtained by Giddingss) were used in conjunction with Equation (2) to obtain values of bp. These values were then applied to equation (3) to produce the ratio K/k*. The same results follow by dividing equation (3) by equation (2). From the k/k* values, the calculated high pressure thermal conductivities were obtained and were compared with the corresponding experimental values. These comparisons areincluded in tables I, II, III and IV for 1,9, 24.6, 43.6 and 75.1 “C, respectively. A second approach for the calculation of thermal conductivities at elevated pressures follows from the Enskog theory. By rearranging equation (3) becomes -

k

= bk*

P

Differentiating

equation

W/d ____ Wpx)

-

1

6

+ s

bPX

+

1

(7)

1

(8)

0.7574 bpx

*

(7) with respect to bpx gives = bk*

-

1

___

(bPX)2

+ or7574

.

Letting d(k/p)/d(bpx) b e zero, the bpx value at the minimum becomes bpx = 1.149. When this value is substituted into equation (7), it follows

1.69

573.9

1.02 1.13

1.54 1.62

0.755

171.1

239.2 273.2

463.7 518.1

0.685

155.8

1.44

0.632

143.9

1.41

0.540

123.5

407.6

0.521

388.8

0.363

86.6

120.1

1.23

0.287

69.1

1.32

0.258

62.6

341.2

0.084

21.4

307.2

0.0451 0.084

11.5 21.4

I .a066

1.5030 1.6540

1.329

1.2845

1.1524

1.0320

0.7946 0.9130

0.5512

0.4959

0.4557

0.3872

0.3725

I

0.258 1

0.2038

0.1832

0.0596

0.0320 0.0596

16.413

13.335 14.876

11.605

11.144

9.833

0.647

6.335 7.478

4.053

3.546

3.184

2.592

2.474

1.580

1.195

1.056

0.3080

0.1611 0.3080

22.74

20.72 21.70

19.40

19.35

18.33

17.48

15.40 16.53

12.98

12.70

12.43

11.84

11.74

10.67

10.10

9.77

9.12

8.88 9.13

8.82

1 WRW&~

thermal

x IO-5

keap

cal/s 1

III

13.88

11.86 12.84

10.54

10.49

9.47

8.62

6.54 7.66

4.12

3.84

3.57

2.98

2.88

1.81

1.24

0.91

0.26

0.02 0.27

0.00

0.00

0.00

x to-5

k - k'

cm OK

cm”k

conductivities

10-b Cal/s cmjs

8.97

bpx

x

1.02

/

calculated

k’ = a.86

and

1.02

PR

Experimental

a.92

/

1.66

I .02

P, atm.

7-R =

TABLE and

34.80

31.02 33.03

28.65

27.83

25.65

24.07

20.73 22.42

17.36

16.60

16.04

15.17

15.02

13.71

13.17

12.99

12.09

11.93 12.09

11.78

11.78

11.78

5)

x 10-S

1

29.972

27.154 28.520

24.866

24.150

22.278

20.907

17.917 19.440

14.770

14.044

13.503

12.644

12.494

11.159

10.579

10.378

9.299

9.083 9.299

data

13.32

x IO-5

k es,e

=

for methane

use of viscosity

(k/p),,,

quantities

~1,poises

related

I

14.51

31.80

31.05 31.43

28.18

24.8 1

21.54

19.60

16.34 17.68

13.79

10.58

8.63

6.79

6.42

4.58

4.74

6.22

1.96

2.29 1.85

s”K

23.904

20.957 22.440

19.305

18.854

17.585

16.444

14.139 15.291

11.739

11.145

10.705

9.971

9.834

8.668

8.140

7.945

6.860

6.634 6.860

x

10-S

j

7

+ +

-

-

-

-

-

-

_

11.89

5.12

1.14 3.41

0.49

2.56

4.06

5.93

8.19 7.44

9.56

- 12.24

- 13.88

- 15.78

- 16.24

- 18.76

- 19.41

- 18.68

- 24.78

- 25.29 - 24.86

% dev

use of (Wp)min kealc

1O-5 cal cm2jg

at 43.6”C

1 % dew )

x

THERMAL

CONDUCTIVITY

893

OF METHANE

that min and therefore,

equation

= 2.940 bk*

(7) can be expressed

(9)

in the alternate

form,

k -=

(10)

P

To apply equation (lo), isothermal experimental thermal conductivities should be available at sufficiently high pressures in order to establish the (k/P)nG, value from a k/p versus bpx or k/p versus p plot. The pressures used in this investigation did not go high enough to establish this minimum, except at 1.9”C. A plot of k/pR versus pi for this temperature is given in

Fig. 4. Kelationship

between

k/pR and pi resulting

measurements

of methane

from

the thermal

conductivity

at 1.9 “C

figure 4. Since for the other three temperatures, no minimum was observed, the following approach applicable to all four temperatures was used. The experimental thermal conductivities were plotted against PR, the reduced density, as shown in fig. 5. The following analytical expressions resulted from a least squares approach using an IBM 709 digital computer: 1.9”C k X 105 = 7.5801

+ 3.3058~~

+ 7.0778~:

-

+ 2.2411 pi

(11)

4.2029 pi + 1.1765 pi

(12)

6.3124~:

24.6”C k x

105 = 8.2399

+ 2.3775 pR + 7.0636 p; -

894

D. MISIC AND G. THODOS

43.6”C k x lo5 = 8.8248 + 3.8699 PR + 2.528 ,D;

(13)

75.1% k x

lo5 = 10.2626 + 3.1742 PR + 2.4854 p; + 0.1402 &

(14)

and are presented with the experimental values in fig. 5. Equations (ll), (12), (13) and (14) were divided by PR and were then differentiated with respect to PR to obtain relationships which when set to zero, produced the following PR and k/pR values at the minimum of each isotherm : Calculated minima “C 1.9 24.6 43.6 75.1

Fig. 5. Relationships

between

Pfl 1so9 1.683 1.868

1.848

k//m

I

12.34 x 10-S 12.77 13.32 13.80

k and pi for methane

at 1.9, 24.6, 43.6 and 75.1 “C

,

I

0.5674

0.7633 0.8615

0.773

0.990

205.1 273.2

0.9582

1.4140

1.17

1.49

1.56

344.0

523.2

577.7

1.5397

0.9582

341.2

1.085 1.17

307.2

-

0.4679

0.0788

0.648

bpx

0.111

I

k’ =

-

0.4143

13.713

7.9279 12.443

7.9279

6.9876

6.0408

4.1932

3.2920

) /

I

21.57

17.64 21.17

17.82

17.01

15.59

14.02

13.53

10.98

10.01 x 10-s

11.07 11.47

7.54

7.72

6.91

5.49

3.92

3.43

0.00 x IO-5 0.88

k -

cm”K

-

30.41 31.71

24.07

22.52 23.96

21.15

18.48

17.18

13.25

12.81 x 10-S

p, poises 5)

28.747

27.646

21.900

20.455 21.796

19.143

16.513

15.183

10.757 x 10-S

kesle

-

I

data

13.80

for methane

use of viscositv

quantities

ca

_-

and related Cklo)min ,... ~~=

k’

conductivities

IV

lo-scal/scm”K

thermal

ker,

10.10 x

and calculated

L W’RI~TR)~R

Experimental

171.1

PR

1.82

1.02 31.0

P, atm.

TR =

TABLE

x

20.60

33.27

30.59

22.3 1 24.15

20.25

17.78 22.79

- 2.03 12.22

o/odev

-

_7.268

22.085

20.828

16.310

16.310

15.348

14.350

12.305

11.229

x 10-S

use of

10-S cal cma/g s”K

at 75.1 “C

+

-

-

~ -

-

11.20

2.39

1.62

7.54

9.77 8.45

7.95

- 12.23

- 17.01

-33.81

0/0 dev

P) mln

-I 1

896

D. MISIC AND G. THODOS

Using the values of (k/~&~~, thermal with Equation IV. Application

conductivity

(lo), to produce the results presented

of semi-theoretical

approaches.

values were calculated in tables I, II, III and

The approach

suggested

by

Abas-zadel) that the residual thermal conductivity, k - k*, when plotted against density produces a single relationship for all temperatures, has been successfully “applied for argonz3), nitrogen 25), carbon dioxide 12), ammonia7), and methane24). The experimental data of this study have been subjected to a

0

2

I

3

P*

Fig. 6. lielationship between k -

k* and pi for methane in the gaseous and liquid

regions.

similar treatment which also includes the recent thermal conductivity values of Ikenberry and Ricelo) for liquid methane. A plot of k - k* versus PR is presented in fig. 6 which, in addition, includes the thermal conductivity values reported for methane in the dense gaseous state by KeyesIs). Lenoir,andComings17),Lenoir, Junk,andComingsl*),andStolyarov, Ipatiev, and Teodorovich28). These values produce the single unique relationship presented in fig. 6. Except for the few points of Ikenberry and Ricelo) taken near the critical temperature (TR = 1.048), the remaining values of his investigation and those of the other investigators, produce the unique relationship which is continuous throughout the gaseous and liquid states. The values reported by Stolyarov e.a. 28)“exhibit some inconsistencies and deviate somewhat from the established relationship of figure 6. The experimental thermal conductivity values of this study are consistent and assist to establish the relationship of fig. 6 in the dense gaseous region where reliable data were not available. Golubev6) has introduced the thermodynamic quantity, (WjaT),, to replace the density in the corklation of p - p*, the residual viscosity. The resulting ,U - ,LL*versus (aP/BT) v relationships were linear when plotted on

THERMAL

log-log coordinates. to produce

CONDUCTIVITY

This concept has been used by Lenner

generalized

relationships

897

OF METHANE

of viscosity

t and Thodos16)

which were linear

for

argon, krypton, and xenon. A logical extension to thermal conductivity appears appropriate in which the residual thermal conductivity, k L K*, in reduced form. Thus, is related to (aP/aT),, expressed for convenience the quantity

(aP,/aT,),,

of bpx given in tables of this study.

follows directly

I, II, III

In addition,

from equation

and IV which correspond

(6) and the values to the conditions

these values were produced for conditions

corre-

0 lkenberry and Rice 9 0 + 9

Fig. 7. Relationship

Lencmr and Comings Lenar. Junk, and Comings Siolyorov, Ipatw. and Teodorovich This invesiigatlon

between k - k’ and (aP,/aT& for methane in the dense gaseous and liquid regions.

sponding to the data of the other investigators 10, 13, 14, 17, 18, 28) and are presented in fig. 7. The thermal conductivity data of methane produce in fig. 7 a relationship which is linear on log-log coordinates and exhibits a scatter in the low density region. The resulting relationship can be expressed analytically as follows :

.

(15)

This relationship enables the calculation of thermal conductivities in the gaseous and liquid regions from the PVT behavior of the substance and its corresponding atmospheric thermal conductivity value. This type of correlation deserves further attention and should be tested with substances other than methane.

898

D. MISIC AND G. THODOS

Acknowledgement. support of the Petroleum

The authors Research

gratefully

acknowledge

Fund of the American

the financial

Chemical Society

through Grant 329-A. Also due thanks are extended to the Phillips Petroleum Company

for the methane

used in this study.

Nomenclature: a, b constants, equation (4)

thermal conductivity, Cal/s cm “K apparent thermal conductivity, Cal/s cm “K thermal conductivity of gas at atmospheric pressure, Cal/s cm”K molecular weight M N Avogadro’s number, 6.0228 x loss molecules/gram mole P pressure, atm PC critical pressure, atm reduced pressure, P/P, PR gas constant, 82.055 ems atm/g-mole”K H T absolute temperature, OK TC critical temperature, OK reduced temperature, T/Tc TR critical compressibility factor, P,v,/RT, zc k

ko k*

Greek viscosity, g/cm s viscosity of gas at atmospheric pressure, g/cm s 3.14159 2% density, g/ems P PC critical density, g/cm3 PR reduced density, p/pe collision diameter, cm B probability of nearess x P

P*

Received l-6-65

REFERENCES 1) Abas-zade, A. K., Doklady Akad. Nauk Azerbaidzhan SSR 3 (1947) 3. 2) Gediminas, Damasius and Thodos, George, Industr. engng Chem., Fundamentals 2 (1963) 73. 3) Enskog, David, Svensk. Akad. Handl. 63 No. 4 (1922). 4) Eucken, A., Phys. Z. 12 (1911) 1101. J. G., Ph. D. dissertation, Rice University, Houston, Texas (1963). 5) Giddings, I. F., “Viscosity of Gases and Gaseous Mixtures,” Fizmatgiz, Moscow (1959). 6) Golubev, 7) Groenier, W. S. and Thodos, George, J. them. Eng. Data 6 (1961) 240. 8) Hercus, E. 0. and Laby, T. H., Proc. roy. Sot. (London) 95 (1919) 190. J. O., Curtiss, C. F. and Bird, R. B., ‘*Molecular Theory of Gases and Liquids 9) Hirschfelder, Wiley, New York (1954). L. D. and Rice, S. A., J. them. Phys. 39 (1963) 1561. 10) Ikenberry, H. L. and Grilly, E. R., J. them. Phys. 14 (1946) 233. 11) Johnston, 12) Kennedy, J. T. and Thodos, George, A.I. Ch. E. Journal 7 (1961) 625.

THERMAL

CONDUCTIVITY

OF METHANE

899

13) Keyes, F. G., Trans. Am. Sot. Mech. Engrs. 76 (1954) 809. 14) Keyes, F. G., Trans. Am. Sot. Mech. Engrs. 77 (1955) 1395. M. W., Robinson, A. M., Scrivins, J., 15) Lambert, J. D., Cotten, K. J., Pailthorpe, Vale, W. R. F. and Young, R. M., Proc. roy. Sot. (London), A%31 (1955) 280. 16) Lennert, D. A. and Thodos, George, A.I. Ch. E. Journal 11 (1965) 155. 17) Lenoir, J. M. and Comings, E. W., Chem. Eng. Progr. 47 (1951) 223. 18) Lenoir, J. M., Junk, W. A. andcomings, E. W., Chem. Eng. Progr.dt) (1953) 539. 19) Mann, W. B. and Dickins, B. G., Proc. ray. Sot. (London), Al34 (1931) 77. 20) Matschke, D. E. and Thodos, George, J. Petroleum Technol. 12 (1960) 67. 21) Misic, Dragoslav, Ph. D. dissertation, Northwestern University (1965). 22) Misic, Dragoslav and Thodos, George, A.1.Ch.E. Journal 11 (1965)650. 23) Owens, E. J. and Thodos, George, A.1.Ch.E. Journal 3 (1957) 454. 24) Owens, E. J. and Thodos, George, Proc. Conf. Therm6d. Prop. Fluids, London, p. 163, July lo-12 (1957). 25) Schaefer, C. A. and Thodos, George, A. I. Ch. E. Journal 5 (1959) 367. 26) Schottky, W. F., 2. Elektrochem. 56 (1952) 889. 27) Stefan, J., Berichte der Wiener Akademie 65 (1872) II, 45. 28) Stolyarov, E. A., Ipatiev, V. V. and Teodorovich, V. P., Zhur. Fiz. Khim. “4 (1950) 166. 29) Warberg, E. and von Babo, L., Wied. Ann. 17 (1882) 390. 30) Weber, S., Ann Physik (4) 54 (1917) 437. 31) Weber, S., Ann. Physik (4) 54 (1917) 481. 32) Winkelmann, A., Ann. Physik 156 (1875) 497. 33) Ziegler, E., Dissertation, Universitat zu Halle, Germany 1904.