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Chapter 13 GAS MIXTURES Dr. Sam Sung Ting Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Thermodynamics:

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Presentation on theme: "Chapter 13 GAS MIXTURES Dr. Sam Sung Ting Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Thermodynamics:"— Presentation transcript:

1 Chapter 13 GAS MIXTURES Dr. Sam Sung Ting Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Thermodynamics: An Engineering Approach Seventh Edition in SI Units Yunus A. Cengel, Michael A. Boles McGraw-Hill, 2011

2 2 COMPOSITION OF A GAS MIXTURE: MASS AND MOLE FRACTIONS The mass of a mixture is equal to the sum of the masses of its components. The number of moles of a nonreacting mixture is equal to the sum of the number of moles of its components. To determine the properties of a mixture, we need to know the composition of the mixture as well as the properties of the individual components. There are two ways to describe the composition of a mixture: Mass fraction Mole fraction Molar analysis: specifying the number of moles of each component Gravimetric analysis: specifying the mass of each component

3 3 The sum of the mole fractions of a mixture is equal to 1. Apparent (or average) molar mass Gas constant The molar mass of a mixture Mass and mole fractions of a mixture are related by The sum of the mass and mole fractions of a mixture is equal to 1.

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7 7 P-v-T BEHAVIOR OF GAS MIXTURES: IDEAL AND REAL GASES The prediction of the P-v-T behavior of gas mixtures is usually based on two models: Dalton’s law of additive pressures: The pressure of a gas mixture is equal to the sum of the pressures each gas would exert if it existed alone at the mixture temperature and volume. Amagat’s law of additive volumes: The volume of a gas mixture is equal to the sum of the volumes each gas would occupy if it existed alone at the mixture temperature and pressure. Dalton’s law of additive pressures for a mixture of two ideal gases. Amagat’s law of additive volumes for a mixture of two ideal gases.

8 8 The volume a component would occupy if it existed alone at the mixture T and P is called the component volume (for ideal gases, it is equal to the partial volume y i V m ). For ideal gases, Dalton’s and Amagat’s laws are identical and give identical results. P i component pressure V i component volume P i /P m pressure fraction V i /V m volume fraction

9 9 Ideal-Gas Mixtures This equation is only valid for ideal-gas mixtures as it is derived by assuming ideal-gas behavior for the gas mixture and each of its components. The quantity y i P m is called the partial pressure (identical to the component pressure for ideal gases), and the quantity y i V m is called the partial volume (identical to the component volume for ideal gases). Note that for an ideal-gas mixture, the mole fraction, the pressure fraction, and the volume fraction of a component are identical. The composition of an ideal-gas mixture (such as the exhaust gases leaving a combustion chamber) is frequently determined by a volumetric analysis (Orsat Analysis).

10 10 Real-Gas Mixtures One way of predicting the P-v-T behavior of a real-gas mixture is to use compressibility factor. Z m is determined by using these pseudocritical properties. The result by Kay’s rule is accurate to within about 10% over a wide range of temperatures and pressures. Kay’s rule Z i is determined either at T m and V m Dalton’s law) or at T m and P m (Amagat’s law) for each individual gas. Using Dalton’s law gives more accurate results. Compressibility factor

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17 17 PROPERTIES OF GAS MIXTURES: IDEAL AND REAL GASES The extensive properties of a mixture are determined by simply adding the properties of the components. Extensive properties of a gas mixture Changes in properties of a gas mixture

18 18 The intensive properties of a mixture are determined by weighted averaging. Extensive properties of a gas mixture Properties per unit mass involve mass fractions (mf i ) and properties per unit mole involve mole fractions (y i ). The relations are exact for ideal- gas mixtures, and approximate for real-gas mixtures.

19 19 Ideal-Gas Mixtures Partial pressures (not the mixture pressure) are used in the evaluation of entropy changes of ideal-gas mixtures. Gibbs–Dalton law: Under the ideal-gas approximation, the properties of a gas are not influenced by the presence of other gases, and each gas component in the mixture behaves as if it exists alone at the mixture temperature T m and mixture volume V m. Also, the h, u, c v, and c p of an ideal gas depend on temperature only and are independent of the pressure or the volume of the ideal-gas mixture.

20 20 Real-Gas Mixtures It is difficult to predict the behavior of nonideal-gas mixtures because of the influence of dissimilar molecules on each other. This equation suggests that the generalized property relations and charts for real gases developed in Chap. 12 can also be used for the components of real-gas mixtures. But T R and P R for each component should be evaluated using T m and P m. If the V m and T m are specified instead of P m and T m, evaluate P m using Dalton’s law of additive pressures. Another way is to treat the mixture as a pseudopure substance having pseudocritical properties, determined in terms of the critical properties of the component gases by using Kay’s rule. T ds relation for a gas mixture

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