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McNaught, J M,2.6.2-1/2.6.2-19Macdonald equation, for fixed-bed pressure drop,2.2.5-3Mach number,2.2.1-13Macleod-Sugden method for surface tensionMacrolayer consumption model for critical heat flux in pool boiling,2.7.2-13Maddox, R N5.2.2-1/5.2.3-9, 5.5.1-1/5.5.1-62, 5.5.4-1/5.5.4-9Magnetic fields, effect on properties of rheologically complex materials,5.3.8-1/5.3.8-2Magnetic devices, for fouling mitigation,3.17.8-5Magnetohydrodynamcs, inaugmentation of heat transfer in microfluidic systems,2.5.11-10/2.5.11-11Maintenance, of paintings and coatings,4.15.5-5/4.15.5-6Manifolds (see Headers)Margarine manufacture, crystallization of edible oils and fats in, scraped surface heat exchangers for,3.24.1-2Marlotherm, heat transfer media,5.5.15-48/5.5.15-50Martensitic stainless steels,4.5.6-3/4.5.6-5Martin, H2.4.1-1/2.4.5-4, 2.5.5-1/2.5.6-11, 2.8.4-1/2.8.4-14Martinelli and Boelter equations for combined free and forced convection,2.5.10-2/2.5.10-3Martinelli and Nelson correlations:Maruyama, S,2.13.7-1/2.13.7-33Mass, conversion of units, xxxi, xlv-lviMass absorption coefficient,2.9.5-2Mass extinction coefficient,2.9.5-2Mass flux, unit conversion chart for, liiMass fraction, in multicomponent mixtures,1.2.1-2Mass and heat transfer, combined:Mass scattering coefficient,2.9.5-2Mass transfer:Mass transfer coefficient:Materials of construction, for heat exchangers,4.5.1-1/4.5.3-7Low temperature operation, ASME VIII code guidelines for,4.3.4-6/4.3.4-7Mathematical symbols, xliMatovosian, Robert,5.5.5-1/5.5.5-3Matrix heat exchangers (see Plate fin heat exchangers)Matrix inversion techniques, in radiative heat transfer,2.9.3-7/2.9.3-8Maximum drag reductionMaximum heat flux:Maximum mass flux:Maximum shear stress, under free molecule conditions,2.1.1-2Maximum velocities (in shell-and-tube heat exchangers)3.3.5-15, 4.5.3-3Maxwell model, for non-Newtonian fluid,2.2.8-8/2.2.8-9Maxwell principle, for physical quantities, xxMaxwell-Stefan equations, for multicomponent diffusion,2.6.3-13Maxwell velocity of a vapor, as limiting phenomenon in condensation,2.1.7-4/2.1.7-6Maxwell's equations, for electromagnetic radiation,2.9.2-7/2.9.2-8Mayhew, Y R, xix-xliii, xlv-lviMean beam length concept, in radiative heat transfer:Mean phase content,2.3.1-3Mean temperature difference:Measurement of fouling resistance,3.17.4-1/3.17.4-3Mechanical agitators, for agitated vessels,3.14.2-1/3.14.2-2Mechanical design of heat exchangers:Mechanical draft cooling towers,3.12.1-2/3.12.1-3Mechanical draft fan coolers,3.8.2-1/3.8.2-2Mechanical loads, specifications in EN13445,4.3.3-2Mechanical vapour compression cycles in refrigeration,3.26.3-1/3.26.3-5Mechanically agitated systems for direct contact heat transfer,3.19.1-4Mediatherm, heat transfer medium,5.5.15-51Melo, L F,3.17.6-19/3.17.6-20Melting, thermal conduction in,2.4.4-1/2.4.4-2Melting point:Membrane-wall waste heat boilers,3.16.2-3/3.16.2-4Mercury:Merilo correlation, for critical heat flux in horizontal tubes,2.7.4-7/2.7.4-8Merkel's equation, in cooling tower design,3.12.2-2/3.12.2-5Mertz, R,2.13.4-1/2.13.4-27Mesitylene, see 1,3,5-TrimethylbenzeneMetais and Eckert diagrams, for regimes of convection:Metals:Metallic coatings,4.15.5-5Metallurgical industry, kilns and furnaces for,3.11.2-5/3.11.2-6Metastable equilibrium, of vapor and liquid,2.7.1-1Methane:Methanol:Methyl acetate:Methylacetylene:Methyl acrylate:Methyl aminen-Methylaniline:Methyl benzoate:Methylbromide (see Bromomethane)2-Methyl-1,3-Butadiene (Isoprene):2-Methylbutane (isopentane):Methylbutanoate:2-Methyl-2-butene:Methylchloride (see Chloromethane)Methylcyclohexane:Methylcyclopentane:Methylethylketone:Methyl formate:Metallurgical slag, use of submerged combustion in reprocessing of,2.10.4-4/2.10.4-8Methyl fluorate:2-Methylhexane:Methy iodide (see Iodomethane)Methylisobutylketone:Methylmercaptan:1-Methylnaphthalene:2-Methylnaphthalene:2-Methylpentane:3-Methylpentane:2-Methylpropane (isobutane):2-Methylpropene:Methyl propionate:Methylpropylether:Methylpropyl ketone:Methyl salicylate:Methyl-t-butyl ether:Microbubbles, for drag reduction,2.14.1-2Microchannels (see also microfluidics)Micro-fin tubes:Microfluidics, enhancement of heat transfer in,2.5.11-10/2.5.11-11Micropipes (circular microchannels), single phase heat transfer in,2.13.1-1/2.13.1-3Microsystems, description of,2.13.1-1/2.13.1-3Mie scattering, in pulverized coal combustion,2.9.8-17Miller, C J4.5.4-1/4.5.4-12, 4.5.6-1/4.5.6-14Miller, E R3.17.6-22/3.17.6-25, 3.17.7-11/3.17.7-14, 3.17.8-19/3.17.8-22Mineral oils, as heat transfer media, physical properties of,5.5.15-28/5.5.15-39Mineral wool production, submerged combustion systems for,2.10.4-8/2.10.4-10Minimum fluidization velocity,2.2.6-3/2.2.6-5Minimum heat flux in pool boiling:Minimum tubeside velocity, in shell-and-tube heat exchangers,3.3.5-16Minimum velocity for fluidization,2.2.6-3/2.2.6-5Minimum wetting rate, for binary mixtures,2.7.8-11Mirror-image concept, in radiative heat transfer,2.9.4-1/2.9.4-2Mirrors, spectral characteristics of reflectance from,2.9.2-17Mishkinis, D,3.10.1-1/3.10.5-3, 3.10.7-1/3.10.7-3, 3.10.9-1/3.10-9-12Mist flow:Mitigation of fouling,3.17.8-1/3.17.8-13Mixed convection occurrence in horiozntal circular pipe, Metais and Eckert diagram for,2.2.2-7Mixing (shell-side), in twisted tube heat exchangers,3.23.3-13/3.23.3-16Mixing length, in turbulent flow,2.2.1-17Mixing vessel (see Agitated vessel)Mixtures:Modelling, of fouling:Models, theory of,2.2.1-15Modes of heat transfer, Nusselt description,2.1.0-2Modulus of elasticity:Moffat, R S M,4.7.11-1/4.7.11-7Molecular dynamics methods,2.13.7-1/2.13.7-33Molecular gas radiation properties,2.9.5-8/2.9.5-11Molecular weight:Mollier chart, for humid air,3.13.1-1Momentum equation:Monitoring, on line, of fouling,3.17.4-1Monochloroacetic acid:Monotube waste heat boilers,3.16.2-8Monte Carlo methods, in radiative heat transfer,2.9.4-2/2.9.4-5Moody chart:Morris, M4.3.1-1/4.3.1-5, 4.3.4-1/4.3.5-11, 4.3.6-1/4.3.6-30, 4.10.1-1/4.10.2-8, 4.13.1-1/4.13.6-3, 4.14.1-1/4.14.8-4Mostinski correlations:Moving bed, heat transfer to,2.8.3-3/2.8.3-7Moving belt, heat transfer to,2.1.3-2/2.1.3-3MSF, see Multiphase flash evaporationMuchowski, E,2.8.3-1/2.8.3-9Mueller, A C3.4.2-1/3.4.4-3, 3.4.6-1/3.4.9-5Muller-Steinhagen, H3.17.6-7/3.17.6-8, 3.17.7-22/3.17.7-23, 3.17.7-3Multicomponent mixtures:Multidimensional systems, heat conduction in,2.4.3-10/2.4.3-12Multiflux methods, for radiative heat transfer in nonisothermal gases,2.9.7-6/2.9.7-7Multipass shell-and-tube heat exchangers,1.1.1-2Multiphase fluid flow and pressure drop:Multiple duties, in plate heat exchangers,3.7.1-2Multiple effect evaporation,3.5.3-1/3.5.3-2Multiple hairpin heat exchanger,3.1.2-2Multirod clusters (see Rod bundles)Multistage flash evaporation (MSF)Multizone model, for furnaces,3.11.6-1/3.11.6-6Murray, I,4.4.4-1/4.4.4-11
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