Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...

Articles Figures Tables About

Thomson coefficient

At constant pressure L Joule-Thomson coefficient fX, fXjT-... [Pg.103]

To convert the Joule-Thomson coefficient, I, in degrees Celsius per atmosphere to degrees Fahrenheit per atmosphere, multiply by 1.8. [Pg.176]

TABLE 2-149 Additional References Available for the Joule-Thomson Coefficient... [Pg.176]

Since the Joule-Thomson process is isenthalpic, the slope of each line can be represented as (dT/dp)lf. This quantity is referred to as the Joule Thomson coefficient, pj j.. Thus1... [Pg.141]

Values for the Joule-Thomson coefficient can be obtained from equations of state. To do so, one starts with the relationship between exact differentials given by equation (1.37) to write (using molar quantities)... [Pg.141]

Figure 3.7(a) shows experimental values of fj,j T obtained for N gas, while Figure 3.7(b) shows how the Joule-Thomson coefficient for N2 gas changes with pressure and temperature.2... [Pg.142]

Figure 3.7 (a) Joule-Thomson inversion curve (/o.t. = 0) for nitrogen, (b) The Joule -Thomson coefficient of nitrogen gas. At the lowest temperature, 123.15 K. nitrogen liquifies hence the curve for the gas terminates at the vapor pressure. [Pg.143]

These derivatives are of importance for reversible, adiabatic processes (such as in an ideal turbine or compressor), since then the entropy is constant. An example is the Joule-Thomson coefficient for constant H. [Pg.22]

Joule-Thomson Coefficient. Knowing that a process is isenthalpic, we can formulate the Joule-Thomson effect quantitatively. [Pg.100]

The Joule-Thomson coefficient p.jx, is positive when a cooling of the gas (a temperature drop) is observed because dP is always negative, p.j x, will be positive when dT is negative. Conversely, p.j x, is a negative quantity when the gas warms on expansion because dT then is a positive quantity. Values of the Joule-Thomson coefficient for argon and nitrogen at several pressures and temperatures are listed in Table 5.5. [Pg.100]

It frequently is necessary to express the Joule-Thomson coefficient in terms of other partial derivatives. Considering the enthalpy as a function of temperature and pressure H T, P), we can write the total differential... [Pg.100]

It is also possible to measure (dH/dP)T, the isothermal Joule-Thomson coefficient directly, which is a quantity more diiectly related to deviations from ideality [14]. [Pg.101]

Joule-Thomson Inversion Temperature. The Joule-Thomson coefficient is a function of temperature and pressure. Figure 5.8 shows the locus of points on a temperature-pressure diagram for which p,jx. is zero. Those points are at the Joule-Thomson inversion temperature 7). It is only inside the envelope of this... [Pg.101]

From Equation (5.68), we know that the pressure coefficient of the molar enthalpy of a gas is related to the Joule-Thomson coefficient p,j x by the equation... [Pg.239]

Because of this relationship between (TT — and p-j x.. the former quantity frequently is referred to as the Joule-Thomson enthalpy. The pressure coefficient of this Joule-Thomson enthalpy change can be calculated from the known values of the Joule-Thomson coefficient and the heat capacity of the gas. Similarly, as (H — is a derived function of the fugacity, knowledge of the temperature dependence of the latter can be used to calculate the Joule-Thomson coefficient. As the fugacity and the Joule-Thomson coefficient are both measures of the deviation of a gas from ideahty, it is not surprising that they are related. [Pg.239]

Although the van der Waals equation is not the best of the semi-empirical equations for predicting quantitatively the PVT behavior of real gases, it does provide excellent qualitative predictions. We have pointed out that the temperature coefficient of the fugacity function is related to the Joule-Thomson coefficient p,j x.- Let us now use the van der Waals equation to calculate p,j.T. from a fugacity equation. We will restrict our discussion to relatively low pressures. [Pg.247]

As Cpm is positive, the sign of the Joule-Thomson coefficient depends on the sign of the expression in parentheses in Equations (10.79) and (10.80). The expression in Equation (10.79) is a quadratic in T, and are two values of T exist at any value of P for which p.j x, = 0. Thus, Equation (10.79) predicts two values of the Joule-Thomson inversion temperature T,- for any pressure low enough for Equation (10.75) to be a good approximation for a. As we saw in Section (5.2) and Figure 5.8, this prediction fits, at least qualitatively, the experimental data for the Joule-Thomson experiment for N2 at low pressure. [Pg.249]

Joule Thomson coefficient m may be defined as the temperature change in degrees produced by a drop of one atmospheric pressure when the gas expands under conditions of constant enthalpy. It is expressed as... [Pg.28]

The Joule-Thomson coefficient for a real gas is not zero in the limit of zero pressure ... [Pg.30]

But = C , heat capacity at constant pressure and = m, Joule-Thomson coefficient... [Pg.31]

Energy and Enthalpy E(T) H(T) E(V) H(P) Determine Cv end Cp from data Determine AHvap and AHtu Internal Pressure Combine with Cp to get Joule-Thomson coefficient... [Pg.202]

In the period 1852-62, J. P. Joule and W. Thomson (later Lord Kelvin) perfected a clever method for measuring the isenthalpic property (dT/dP)Ih which has come to be called the Joule-Thomson coefficient, symbolized /xJT ... [Pg.93]

The measured Joule-Thomson coefficient (3.62) can therefore be identified more precisely as fjLjT = (
[Pg.94]

The measured Joule-Thomson coefficient /jljt provides valuable information about how the enthalpy of real gases depends on variables other than temperature. To obtain information about the P dependence of H, we can employ the Jacobi cyclic identity (1.14b) to rewrite the Joule-Thomson coefficient as... [Pg.94]

Figure 3.12 Qualitative temperature and pressure dependence of the Joule-Thomson coefficient MotO P) for C02. Figure 3.12 Qualitative temperature and pressure dependence of the Joule-Thomson coefficient MotO P) for C02.
Problem Prove that the Joule-Thomson coefficient /jljt satisfies the identity (3.69) Mjt = (TaP — )(V/CP). [Pg.166]

In terms of Table 12.1, T and —P are already standard complementary variables, so the Joule-Thomson coefficient is conveniently evaluated from (12.18), with X=T, Y= -P, Z = H ... [Pg.400]


See other pages where Thomson coefficient is mentioned: [Pg.229]    [Pg.91]    [Pg.94]    [Pg.108]    [Pg.506]    [Pg.510]    [Pg.1130]    [Pg.1039]    [Pg.150]    [Pg.360]    [Pg.363]    [Pg.372]    [Pg.377]    [Pg.275]    [Pg.249]    [Pg.253]    [Pg.28]    [Pg.30]    [Pg.33]    [Pg.506]    [Pg.510]    [Pg.400]   
See also in sourсe #XX -- [ Pg.37 ]

See also in sourсe #XX -- [ Pg.231 ]




SEARCH



Coefficients Joule-Thomson

Enthalpy Joule-Thomson coefficients

Exact treatment of the Joule-Thomson coefficient

Isothermal Joule-Thomson coefficient

Joule-Thomson coefficient calculation

Joule-Thomson coefficients inversion temperature

Joule-Thomson expansion coefficient

Pressure Joule-Thomson coefficients

Systems Joule-Thomson coefficients

Tables Additional References Available for the Joule-Thomson Coefficient

Temperature Joule-Thomson coefficients

The Joule-Thomson coefficient

Thermodynamics Joule-Thomson coefficients

© 2024 chempedia.info