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1.
G. R. Somayajulu 《International Journal of Thermophysics》1990,11(3):555-572
Because of the recent availability of the melting points of several ultralong normal paraffins, the melting behavior of normal paraffins has been investigated. Taking the melting point of polyethylene to represent the melting point of an ultralong paraffin, a new function has been established to represent the melting points of alkanes from the carbon number 32 onwards. Adopting the same value for the limiting melting point of an ultralong paraffin, equations are derived for the melting points of several homologous series.Nomenclature
a
A constant to be determined
-
b
A constant to be determined
-
m
Number of methylene groups in the molecule
-
n
Number of carbon atoms in the molecule
-
n
*
Number of carbon atom above which Eq. (6) is applicable
-
T
0
Temperature constant, K
-
T
c
Critical temperature, K
-
T
c
Critical temperature of an ultralong normal paraffin, K
-
T
b
Normal boiling point, K
-
T
b
Normal boiling point of an ultralong normal paraffin, K
-
T
m
Melting point, K
-
T
m
Melting point of an ultralong paraffin, K
- Standard deviation
{[(T
m
(obsd)–T
m
(calc)]2/(No. points–No. parameters)}0.5 相似文献
2.
A generalized equation for surface tension from the triple point to the critical point 总被引:1,自引:0,他引:1
G. R. Somayajulu 《International Journal of Thermophysics》1988,9(4):559-566
A three-parameter generalized equation is proposed for surface tension from the triple point to the critical point. This equation not only fits the data well but also is good for interpolation between the normal boiling point and the critical point. This equation is also good for extrapolation to the triple point. This equation has been tested using the surface tension of water from the triple point to the critical point. The constants of this equation obtained using orthobaric surface tensions are given for a number of compounds. The isobaric surface tensions determined at a pressure of 1 atm do not differ significantly from the orthobaric surface tensions. Such data also have been used in obtaining equations from the triple to the critical point.Nomenclature
T
c
Critical temperature, K
-
T
t
Triple point, K
-
T
m
Melting point, K
-
T
r
Reduced temperature, K
-
X
(T
c-T)/T
c
-
Surface tension, dyne · cm–1;10–3N · m–1
-
m
Surface tension at the melting point
-
f
Surface tension at T
r=0.9
-
t
Surface tension at the triple point
- Relative deviation
100[
obsd–
calcd]/
obsd
- Standard deviation
[(
obsd–
calcd)2/(No. points—No. parameters)]0.5 相似文献
3.
Satya Gopal Rao P. Venkatehwarlu K. Siripuram Rajesh Sripada Suresh 《Glass Physics and Chemistry》2021,47(4):308-320
Glass Physics and Chemistry - The growth of nanocrystalization in TeO2–SeO2–Na2O glasses is achieved by the conventional heat treatment method. The influence of Na2O concentration on... 相似文献
4.
Srinivas S. Sripada P.S. Ayyaswamy L.J. Huang 《International Journal of Heat and Mass Transfer》1996,39(18):3781-3790
A unit cylinder cell model with a body-fitted coordinate system is employed to analyze the hydrodynamics and heat transfer associated with steam condensation on a spray of equal sized water droplets. The droplets are assumed to be moving in the intermediate Reynolds number regime, Reg = O(100). The distance between neighboring droplet centers is allowed to be arbitrary in the plane of motion, but the droplets are assumed to be uniformly spaced in the plane perpendicular to the direction of motion. Furthermore, once a particular configuration of the droplets is set, the subsequent spacings between the droplet centers in that configuration are taken to remain constant during the entire condensation process. The formulation entails a simultaneous numerical solution of the quasi-steady elliptic partial differential equations that describe the flow field in both the dispersed and continuous phases in each cell. In part 1 of this study, the results for the velocity, surface pressure and drag are presented. In part II of this study, the results for the condensation induced velocities, surface shear stress, the Nusselt number and the Sherwood number are provided. In both parts of the study, the interactions between neighboring drops have been examined. 相似文献
5.
An effective and unique method of measuring independently the variations of resistive and capacitive constituents of a practical capacitive transducer using an improved pseudo-active bridge is described. The impedance change in some types of transducers may be due to changes in resistance and/or capacitance either way. Separation of changes in resistance and capacitance results in a better understanding of the transduced variable. The active bridge which separates the changes is suitable for online determination of the two changes. 相似文献
6.
7.
Danda Srinivas Rao Tadiparthi Venkata VijayaKumar Sripada Subba Rao Swarna Prabhakar Guntamadugu Bhaskar Raju 《北京科技大学学报(英文版)》2011,18(5):515-522
The recovery of iron from the screw classifier overflow slimes by direct flotation was studied.The relative effectiveness of sodium silicates with different silica-to-soda mole ratios as depressants for silica and silicate bearing minerals was investigated.Silica-to-soda mole ratio and silicate dosage were found to have significant effect on the separation efficiency.The results show that an increase of Fe content in the concentrate is observed with concomitant reduction in SiO2 and Al2O3 levels when a particular type of sodium silicate at a proper dosage is used.The concentrate of 58.89wt% Fe,4.68wt% SiO2,and 5.28wt% Al2O3 with the weight recovery of 38.74% and the metal recovery of 41.13% can be obtained from the iron ore slimes with 54.44wt% Fe,6.72wt% SiO2,and 6.80wt% Al2O3,when Na2SiO3 with a silica-to-soda mole ratio of 2.19 is used as a depressant at a feed rate of 0.2 kg/t. 相似文献
8.
Bhaskar N Sripada Thomas H Jobe Cathy M Helgason 《IEEE transactions on systems, man, and cybernetics. Part B, Cybernetics》2005,35(6):1328-1339
Plurimonism is a new philosophy and method of science. It holds that the revolution in computer science and artificial intelligence has reached the point that all the sciences in general can now account for the complex relations of an irreducible plurality of unique observers engaged in describing the same event. Plurimonism seeks to describe the conscious and unconscious relations of the scientific observer during the act of observation of a given event while preserving the historical uniqueness and indivisible identity of each such observer. Using the framework of plurimonism, we mathematically formulate the problem of empathy. This self-reflective mathematical model entails four components of the empathic process involving two observers. They are: 1) the self; 2) the self's-other; 3) the other; and 4) the other's-self. It measures the degree of accuracy of the therapist-observer's empathy, as well as conscious and unconscious processes involved in the patient-observer's idealization and the therapist-observer's confidence in clinical psychotherapy. Ratings are obtained from both patient and therapist from four different points of view. The plural views of the patient's global assessment of functioning (GAF) are from: 1) the therapist's view (TGAF); 2) the patient's view (PGAF); 3) the therapist empathic view (TEGAF), which represents the therapist's estimate of PGAF; and 4) the patient's empathic estimate of the TGAF. The GAF scale is the standard dimensional 100-point-scale measure used in psychiatry for recording a patient's functioning. The patient's estimate of the therapist's degree of accuracy as well as the therapist's confidence in his or her empathic accuracy is also represented. Three formulae are presented that describe the degree of the therapist's empathic accuracy, the patient's over-idealization/under-idealization, and the therapist's over-confidence/under-confidence. The concept of empathy is here restricted to mean the degree to which one observer can take the point of view of another observer when both are observing the same thing. 相似文献
9.
G. R. Somayajulu 《International Journal of Thermophysics》1991,12(6):1039-1062
Because of the recent availability of the critical constants of normal alkanes up to octadecane, some modifications in the estimation procedures for the critical constants have become necessary. It has been shown that the equation of Ambrose for the critical temperature of normal alkanes leads to the result that as n , the limiting value for the critical temperature is equal to the limiting value for the normal boiling point and the limiting value for the critical pressure is 1 atm. Currently, the CH2 increment for the critical volume is considered constant. The recent data of Teja have shown that the CH2 increment increases indefinitely in a homologous series until the critical volume reaches its limiting value. This has made the current procedure for estimating the critical volume obsolete. Taking into account the new measurements of Teja, we have now developed new equations for estimating the critical constants. The limiting values for an infinitely long alkyl chain for T
b, T
c, P
c, and V
c have been found to be 1021 K, 1021 K, 1.01325 bar, and 18618 cm3 · mol–1, respectively. These new concepts have been applied to the estimation of various properties other than the critical constants.Nomenclature
M
Molar mass, kg·mol –1
-
V
c
Critical volume, cm3·mol–1
-
V
1
Saturated liquid volume, cm3·mol–1
-
P
c
Critical Pressure, bar
-
T
c
Critical temperature, K
-
T
b
Normal boiling point, K
-
T
B
Boyle temperature, K
-
T
A
Temperature at which the third virial coefficient is zero, K
-
V
c
Limiting value of critical volume = 18,618 cm3 · mol–1
-
P
c
Limiting value of critical pressure=1.01325 bar
-
T
c
Limiting value of critical temperature = 1021 K
-
T
b
Limiting value of normal boiling point = 1021 K
-
P
b
Pressure at the normal boiling point, 1 atm
-
Z
c
Critical compressibility factor
-
Z
c
Limiting value for the critical compressibility factor = 0.22222
-
R
Gas constant, 83.1448×10–6m3 · bar · K–1 · mol–1
-
Acentric factor
-
X
(T
c–T
b)/T
c
-
X
1
(T
c–T)/T
c
-
X
2
1–(T
B/T)5/4
-
X
3
1–(T
A/T)5/2
- Y
P
c/RT
c
-
Surface tension, mN · m–1
-
B
Second virial coefficient, cm3 · mol–1
-
B
Limiting value for the second virial coefficient = –30,463 cm3 · mol–1
-
C
Third virial coefficient, cm6 · mol–2
-
C
b
Third virial coefficient at the normal boiling point, cm6 · mol–2
-
C
c
Third virial coefficient at the critical temperature, cm6 · mol–2
-
C
B
Third virial coefficient at the Boyle temperature, cm6 · mol–2
-
H
vb
Enthalpy of vaporization at the normal boiling point, kJ · mol–1
-
n
Number of carbon atoms in a homologous series
-
p
Platt number, number of C-C-C-C structural elements
-
a, b, c, d, e, etc
Constants associated with the specific equation
-
T
c
*
, T
b
*
, P
c
*
, V
c
*
, etc.
Dimensionless variables 相似文献
10.