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Heat transfer between parallel continuous streams
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Index

HEDH
A B C D E F G H I J K L M N O P
Packaged units, specification of, Packing characteristic, in cooling towers, Packings, for cooling towers Packings, for fixed beds: Packinox heat exchanger, Paints, spectral characteristics of reflectance of surfaces treated with, Palen, J W Panchal, C B, Paraffins, normal and isonormal: Paraldehyde: Parallel channel instability, in condensers, Partial boiling in subcooled forced convective heat transfer, Participating media, radiation interaction in, Particle convective component, in heat transfer from fluidized beds, Particle emissivity, Particle Reynolds number in fixed beds, Particles:
fluid-to-particle heat transfer in fluidized beds, free fall velocity of, in direct contact heat transfer,
Heat transfer between parallel continuous streams
particle-to-wall heat transfer in fluidized beds,
Particulate fluidization, Particulate fouling, Pass arrangements, in plate heat exchangers, Passes, tube side, Passive methods, for augmentation of heat transfer, passive systems for: PD5500 mechanical design of shell-and-tube heat exchangers to, Peacock, D K, Pearson number, Peclet number Peng-Robinson equation of state, application to hydrocarbons, Penner's rule, in absorption of radiation by gases, Pentachloroethane (Refrigerant 120): Pentadecane: Pentadecene: Pentadiene 1, 2: Pentadiene 1, trans 3: Pentadiene 1, 4: Pentadiene 2-3: Pentafluoroethane (Refrigerant 125) Pentamethylbenzene: Pentane: Pentanoic acid: 1-Pentanol: 1-Pentene: cis-2-Pentene: trans-2-Pentene: Pentylacetate: Pentylbenzene: Pentylcyclohexane: Pentylcyclopentane: Pentylcyclopropane, liquid properties, Perforated fins, in plate fin heat exchangers, Perforated plates, loss coefficients in, Periodic operation, of regenerator, Periodic variations in temperature, thermal conduction in bodies with, PFR correlation, for heat transfer in high fin tube banks, Pharmaceutical industry, fouling of heat exchangers in, Phase change materials, in augmentation of heat transfer, Phase change number, Phase equilibrium: Phase inversion Phase separation, as source of corrosion problems, Phenol: Phenols: Phenylhydrazine: Phonons, in thermal conductivity of solids, Phosgene: Physical properties: Pi theorum, in dimensional analysis, Pinch analysis, for heat exchanger network design, Pioro, I L Pioro, LS, Pipe leads, Piperidine: Pipes, circular: Pipes, noncircular: Piping components: Pitting corrosion, in stainless steels, Planck's constant, Planck's law, for spectral distribution of blackbody radiation, Plane shells, steady-state thermal conduction in, Plastic deformation Plate fin heat exchangers Plate fins, efficiency, Plate heat exchangers: Plate evaporator Plates: Plug flow: Plug flow model, for furnaces, Pneumatic conveyance, Pneumatic conveying dryer, P-NTU method: Polarization, of thermal radiation, Polyglycols, as heat transfer media, Polymers: Pool boiling, Porous surfaces: Port arrangements, in plate heat exchangers, Portable fouling unit, Poskas, P, Postdryout heat transfer: Powders: Power law fluid (non-Newtonian), Power plant: Prandtl number Precipitation (crystallization) fouling, Precipitation hardening, of stainless steels, Pressure coefficient: Pressure control of condensers, Pressure drop: Pressure gradient: Pressure, specification of in mechanical design to EN13445, Pressure testing, Pressure vessels, principle codes for, Pressurised water reactor, fouling in, Printed circuit heat exchanger, Problem table algorithm, in pinch analysis, Process heaters: Progressive plastic deformation Prolate spheroids, free convective heat transfer from, Promoters, in dropwise condensation, Propadiene: Propane: 1-Propanol: 2-Propanol: Propeller agitator, Property ratio method, for temperature dependent physical property Propionaldehyde: Propionic acid: Propionic anhydride: Proprionitrile: Propyl acetate: Propylamine: Propylbenzene: Propylcyclohexane: Propylcyclopentane: Propylene: 1,3-Propylene glycol: Propylene oxide: Propyl formate: Propyl propionate: Pseudo-boiling in supercritical fluids, Pseudo-film boiling in supercritical fluids, Pseudocritical pressure, Pseudocritical tempertaure, Pugh, S F Pulp and paper industry, fouling of heat exchangers in, Pulsations, use in augmentation of heat transfer, Pulverized fuel water-tube boiler, Pumping, lost work in, Pushkina and Sorokin correlation, for flooding in vertical tubes, Pyramid, free convective heat transfer from, Pyridine:
Q R S T U V W X Y Z
P Particles: in direct contact heat transfer,
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Heat transfer between parallel continuous streams

DOI 10.1615/hedhme.a.000213

2.10.2 Heat Transfer between Parallel Continuous Streams

H. R. Jacobs

A. Falling films

In cooling towers, wetted wall towers, packed beds, etc., so-called falling films play an important role. Thus, they constitute one of the most commonly found forms of direct contact heat transfer. The initial work on falling films can be traced to the work of Nusselt (1916) in 1916. Since that time, large numbers of studies have been performed. Hassan (1967) investigated a vertically falling film neglecting surface tension, interfacial shear and pressure gradients. He obtained a universal non-dimensional curve for the developing film thickness. Murty and Sastri (1974) studied the problem of a film exiting a slot flowing down an inclined plane of defined height. The surrounding gas was assumed to be quiescent, and pressure variation and surface tension effects were assumed negligible. Assuming a smooth interface and continuity of velocity and shear at the interface, they determined the film thickness as a function of length along the plate. Murty and Sarma (1976) presented an expression for film thickness for either laminar or turbulent film flow down an inclined wall with a co-current gas stream and incorporated interfacial shear and gravity effects in the non-dimensional film thickness. Experimental non-dimensional velocity profiles were used to present a universal, non-dimensional film thickness. Tekic, et al. Tekic et al. (1984) repeated the model of Murty and Sastri (1974), but incorporated normal and tangential stresses on the film interface and neglected the interfacial shear of the still air. Their results presented a family of curves for liquids with different physical properties, but underpredicted the film entrance length.

While the above studies are interesting, co-current flows result in minimum heat transfer, whilst countercurrent flows maximize heat transfer. Countercurrent flows, however, can lead at high velocities, to stripping of a falling film from the supporting substructure. This is a common problem in cooling towers and can lead to the requirement for excessive make-up water and a highly visible plume. Usually, the falling film develops a rough wavy interface, followed by the formation of larger waves on its surface prior to entrainment of liquid in the gas stream. The waves can be a result of either Tollmein-Schlichting or Kelvin-Helmholtz instabilities. Ostrach and Koestel (1965) discussed these and other instabilities associated with two-phase flows. The Tollmein-Schlichting waves are associated with transition from laminar to turbulent flows and do not apply for the situation of laminar gas and liquid flows. The Kelvin-Helmholtz instabilities are interfacial phenomena resulting from the shear at the interface due to relative velocity differences between the two flows.

Ishii and Grolmes (1975) discussed entrainment of liquid into the gas stream. For the case of vertical falling films in countercurrent flow, shearing droplets from the top of roll waves and the formation of large amplitude bulges in the liquid near the flooding point are possible mechanisms for entrainment. With an increase in velocity, partial or total fluid reversal can occur.

The problem of flooding in annular countercurrent devices (wetted-wall towers) was reviewed by Bharathan et al. (1978). Tien and Liu (1979) outlined an overview of theory and experiment. More recently Bankoff and Lee (1986) and McQuillan et al. (1985) reviewed this problem and established a data bank of experimental flooding points. Stephan and Mayinger (1990) studied such systems at high gas pressure.

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