ABCDEFG
G-type shells in shell-and-tube heat exchangers:Gaddis, E S,1.6.1-1/1.6.12-1Galerkin method, for heat conduction finite-element calculations,2.4.8-11/2.4.8-17Galileo number,2.2.1-11Gas constant, xxxiiiGas heater, approximate overall heat transfer coefficients in,2.1.2-3Gas-liquid flows:Gas-liquid-liquid flows, see Liquid-liquid-gas flowsGas-liquid-solid interfaces, fouling at,3.17.2-14Gas-solid flow (see Solid-gas flow)Gas-solid interfaces, fouling at,3.17.2-1/3.17.2-2Gas sparging, for agitation of vessels:Gas tungsten arc welding,4.11.3-1/4.11.3-5Gaseous fuels, properties of,3.11.3-2Gases:Gasketed plate heat exchangers (see Plate heat exchangers)Gaskets:Gauss-Seidel method, for solution of implicit equations,2.4.7-21/2.4.7-22Gee, C4.12.1-1, 4.12.3-1/4.12.5-1Geometric optics models for radiative heat transfer from surfaces,2.9.4-8geothermal brines, fouling of heat exchangers by,3.17.6-16/3.17.6-17Germany, Federal Republic of, mechanical design of heat exchangers in:Gersten, K,2.2.1-1/2.2.3-9Girth flanges, in shell-and-tube heat exchangers,4.14.2, 4.14.5-1/4.14.5-3Glass production, furnaces and kilns for,3.11.2-6Glycerol (glycerine):Gn (heat generation number),2.5.12-6Gnielinski, V2.5.1-1/2.5.4-6, 2.5.14-1/2.5.14-4Gnielinski correlation, for heat transfer in tube banks,2.5.3-5/2.5.3-9Gomez-Thodas method, for vapour pressure,5.1.3-2/5.1.3-3Goodness factor, as a basis for comparison of plate fin heat exchanger surfaces,3.9.7-1/3.9.7-3Goody narrow band model for gas radiation properties,2.9.5-5Gorenflo correlation, for nucleate boiling,2.7.2-8/2.7.2-10Gowenlock, R,4.3.4-1/4.3.4-24Graetz number:Graetz problem (see Nusselt-Graetz problem)Granular products, moving, heat transfer to,2.8.3-1/2.8.3-7Graphite, density of,5.4.1-1Graphite block heat exchanger,4.4.4-4Graphite, exfoliated, for gaskets,4.12.2-2Graphs, labeling of, xxixxiiGrashof number1.2.3-4, 2.2.1-11, 2.2.2-6Gravitational acceleration, effect in pool boiling,2.7.2-9Gravity conveyor:Gray (SI unit), xxviiiGregorig effect in enhancement of condensation,2.6.6-4Grid baffles:
HIJKLMNOPQRSTUVWXYZin longitudinal flow over tube bundles,3.3.12-4/3.3.12-6heat transfer in,3.3.12-10/3.3.12-12mechanism of flow in,3.3.12-6/3.3.12-7orifice baffles,3.3.12-6pressure drop in,3.3.12-7/3.3.12-10rod baffles,3.3.12-4/3.3.12-5strip baffles,3.3.12-5/3.3.12-6use with low finned tubes,3.3.12-12/3.3.12-13
Grid selection, for finite difference method,2.4.7-3/2.4.7-5Griffin, J M,2.14.1-1/2.14.4-6Groeneveld correlation for postdryout heat transfer,2.7.3-31Groeneveld and Delorme correlation for postdryout heat transfer,2.7.3-41Groll, M2.13.3-1/2.13.3-27, 2.13.8-1/2.13.8-26Gross plastic deformationGroup contribution parameters tables,5.5.4-10Guerrieri and Talty correlations for forced convective heat transfer in two-phase flow,2.7.3-13Gungor and Winterton correlation, for forced convective boiling,2.7.3-26Guo, Z Y,2.13.2-1/2.13.1-20Gylys, J,2.12.1-1/2.12.2-10