Navigation by alphabet

A B C D E F G H I J K L M N O P Q R S T U V W X Y Z
Wadekar, V Wagner equation, for vapour pressure, Wake, Coles law of the, Wall layer transmissivity, Wall temperature: Wallis correlations: Wallis criterion, for transition from stratified to annular flow, applications in condensation, Walz' method, for laminar boundary layers, Waste heat boilers, Waste water, fouling by, Water: Watertube boiler, Wavelengths, of blackbody radiation, Waves, interfacial, effect on film condensation on vertical surface, Wavy fins, in plate fin exchangers, Webb, D R
Condensation of Vapour Mixtures Condensation of Vapour Mixtures Forming Immicible Liquids
Webb, R L Weber, M, Weber number, Weil, C J Welded channel head, in shell-and tube heat exchanger, Welded fins: Welded plate exchangers: Welding: Welds: Wentz and Thodos equation, for fixed-bed pressure drop, Wet-bulb temperature, Wettability, of surface, effect on pool boiling, Whalley and Hewitt correlations: White-Metzner model, for non-Newtonian fluid, Wicks, for heat pipes: Wilday, A J Wildsmith, G, Wills-Johnson flow stream analysis method for segmentally baffled shell-and-tube heat exchangers, Wilson, D I Window zone, in shell-and-tube heat exchangers: Winter, H H, Wire matrix inserts, in heat exchangers, Wirth, K E, Wispy annular flow, regions of occurrence of, Work (in exergy analysis) Working fluid, selection of for heat pipe,

Index

HEDH
A B C D E F G H I J K L M N O P Q R S T U V W
Wadekar, V Wagner equation, for vapour pressure, Wake, Coles law of the, Wall layer transmissivity, Wall temperature: Wallis correlations: Wallis criterion, for transition from stratified to annular flow, applications in condensation, Walz' method, for laminar boundary layers, Waste heat boilers, Waste water, fouling by, Water: Watertube boiler, Wavelengths, of blackbody radiation, Waves, interfacial, effect on film condensation on vertical surface, Wavy fins, in plate fin exchangers, Webb, D R
Condensation of Vapour Mixtures Condensation of Vapour Mixtures Forming Immicible Liquids
Webb, R L Weber, M, Weber number, Weil, C J Welded channel head, in shell-and tube heat exchanger, Welded fins: Welded plate exchangers: Welding: Welds: Wentz and Thodos equation, for fixed-bed pressure drop, Wet-bulb temperature, Wettability, of surface, effect on pool boiling, Whalley and Hewitt correlations: White-Metzner model, for non-Newtonian fluid, Wicks, for heat pipes: Wilday, A J Wildsmith, G, Wills-Johnson flow stream analysis method for segmentally baffled shell-and-tube heat exchangers, Wilson, D I Window zone, in shell-and-tube heat exchangers: Winter, H H, Wire matrix inserts, in heat exchangers, Wirth, K E, Wispy annular flow, regions of occurrence of, Work (in exergy analysis) Working fluid, selection of for heat pipe,
X Y Z
W Webb, D R
Download the citation in the EndNote formatOpen in a new tab. Download the citation in the RefWorks formatOpen in a new tab. Download the citation in the BibTex formatOpen in a new tab.

Condensation of Vapour Mixtures Forming Immicible Liquids

DOI 10.1615/hedhme.a.000187

2.6 CONDENSATION
2.6.4 Condensation of vapour mixtures forming immiscible liquids

David R. Webb

A. Introduction

The author would like to acknowledge the use he has made of the previous article in HEDH, written by R. Sardesai in 1983. However a significant change in approach has been adopted and the present article has been written as a consistent extension to Section 186. Section 186, Webb and McNaught (1980) and Webb (1990) should be read as pre-cursors to the present article.

The formation of a second immiscible condensate phase during condensation can affect the behaviour in a number of ways and reliable design should account for the possibility. Firstly various modes of condensation may occur. Thus it is possible for a single phase condensate to be formed. Vapours, which will form the other phase, act as non-condensing species imposing a greater gas-side resistance. Secondly when both liquid condensates are present the nature of the flow pattern will influence the condensate film heat transfer coefficient.

The various modes of heat transfer which are possible may be identified by consideration of the phase diagram, Figure 1, which applies for the case of mixtures which may be considered fully immiscible as liquids. The state of the mixture may lie in any of the four regions of the diagram, vapour, two-phase with liquid 1 present, two-phase with liquid 2 present or all liquid. Vapour-liquid equilibrium states with liquid 1 and 2 occur along FE and EG respectively, with the azeotrope at E, where vapour and both liquid phases co-exist at equilibrium.

Figure 1 Phase diagram for vapours which form immiscible condensates

... You need a subscriptionOpen in a new tab. to view the full text of the article. If you already have the subscription, please login here

© 2024 by Begell House, Inc.