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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
E-type shells in shell-and-tube heat exchangers:
recommended calculation methods for pressure drop and heat transfer in,
Objectives and Background
temperature difference correction (F) and ?-NTU charts for,
Ebert and Panchal equation, for crude oil fouling, Eckert number, Eddy viscosity: Eddy diffusivity, of heat, Edge, D, Edwards, D K EEC code for thermal design of heat exchangers, Effective diffusivity, Effective thermal conductivity of fixed beds, Effective tube length in shell-and-tube heat exchangers, Effectiveness of a heat exchanger: Efficiency of fins, Eicosane: Eicosene: Ejectors, in flash distillation plant, EJMA (Expansion Joint Manufacturers Association), standards for expansion bellows Elastic properties of solids: El-Dessouky, H, Electrical enhancement processes, in heat transfer augmentation, Electric fields, effect on properties of rheologically complex materials, Electric fields, in augmentation of condensation, Electrical process heater, specification of, Electrokinetics, for heat transfer augmentation in microfluidic systems, Electromagnetic theory of radiation, Electrostatic fields in augmentation of heat transfer, Elements: Elhadidy relation between heat and momentum transfer, Embedding methods for radiative heat transfer in nonisothermal gases, Embittlement, of stainless steels, Emission of thermal radiation, in solids, Emissivity: Emitting media, interaction phenomena with, Emulsions, viscosity of, EN13445 (European Pressure Vessel Codes), design of heat exchangers to, Enclosures: Energy equation: Energy recovery, maximum, in heat exchanger network design, Enhanced surfaces, fouling in, Enhancement devices: Enlargements in pipes: Enthalpy: Entrainment in annular gas-liquid flow Entrance effects in heat and mass transfer: Entrance lengths, hydrodynamic in pipe flow, Entrance losses for tube inlet in shell-and-tube heat exchanger, Entry losses in plate heat exchangers, Entropy generation and minimisation Environmental impact, of fouling, Eotvos number: Epstein, N, Epstein matrix, for fouling, Equalizing rings, for expansion bellows, Equilibrium interphase: Equilibrium vapor nucleus, Equivalent sand roughness, Ergun equation, for pressure drop in fixed beds ESDU correlations: Esters: Ethane: Ethanol: Ethers: Ethyl acetate: Ethylacetylene: Ethylacrylate: Ethylamine: Ethylbenzene: Ethyl benzoate: Ethyl butanoate: Ethylcyclohexane: Ethylcyclopentane: Ethyl formate: Ethylene: Ethylene diamine: Ethylene glycol: Ethylene oxide: Ethylmercaptan: 1-Ethylnaphthalene: 2-Ethylnaphthalene: Ethyl proprionate: Ethyl propylether: Ettouney, H, Euler number: Eutectic mixtures, condensation of forming immiscible liquids, Evaporation: Evaporative crystallisers, Evaporators: Exergy, definition of, Exergy analysis, Exit losses for tubes in shell-and-tube exchanger, Expansion bellows, for shell-and-tube heat exchangers: EJMA (Expansion Joint Manufacturers Association), standards for Expansion joints, mechanical design of: Expansion of tubes into tube sheets: Expansion turbine, lost work in, Explosively clad plate, Explosive welding of tubes into tube sheets Explosive expansion joints, Extended surfaces (see also Fins) Externally induced convection, in kettle reboilers, Extinction coefficient, Extinction efficiency, Eyring fluid (non-Newtonian),

Index

HEDH
A B C D E
E-type shells in shell-and-tube heat exchangers:
recommended calculation methods for pressure drop and heat transfer in,
Objectives and Background
temperature difference correction (F) and ?-NTU charts for,
Ebert and Panchal equation, for crude oil fouling, Eckert number, Eddy viscosity: Eddy diffusivity, of heat, Edge, D, Edwards, D K EEC code for thermal design of heat exchangers, Effective diffusivity, Effective thermal conductivity of fixed beds, Effective tube length in shell-and-tube heat exchangers, Effectiveness of a heat exchanger: Efficiency of fins, Eicosane: Eicosene: Ejectors, in flash distillation plant, EJMA (Expansion Joint Manufacturers Association), standards for expansion bellows Elastic properties of solids: El-Dessouky, H, Electrical enhancement processes, in heat transfer augmentation, Electric fields, effect on properties of rheologically complex materials, Electric fields, in augmentation of condensation, Electrical process heater, specification of, Electrokinetics, for heat transfer augmentation in microfluidic systems, Electromagnetic theory of radiation, Electrostatic fields in augmentation of heat transfer, Elements: Elhadidy relation between heat and momentum transfer, Embedding methods for radiative heat transfer in nonisothermal gases, Embittlement, of stainless steels, Emission of thermal radiation, in solids, Emissivity: Emitting media, interaction phenomena with, Emulsions, viscosity of, EN13445 (European Pressure Vessel Codes), design of heat exchangers to, Enclosures: Energy equation: Energy recovery, maximum, in heat exchanger network design, Enhanced surfaces, fouling in, Enhancement devices: Enlargements in pipes: Enthalpy: Entrainment in annular gas-liquid flow Entrance effects in heat and mass transfer: Entrance lengths, hydrodynamic in pipe flow, Entrance losses for tube inlet in shell-and-tube heat exchanger, Entry losses in plate heat exchangers, Entropy generation and minimisation Environmental impact, of fouling, Eotvos number: Epstein, N, Epstein matrix, for fouling, Equalizing rings, for expansion bellows, Equilibrium interphase: Equilibrium vapor nucleus, Equivalent sand roughness, Ergun equation, for pressure drop in fixed beds ESDU correlations: Esters: Ethane: Ethanol: Ethers: Ethyl acetate: Ethylacetylene: Ethylacrylate: Ethylamine: Ethylbenzene: Ethyl benzoate: Ethyl butanoate: Ethylcyclohexane: Ethylcyclopentane: Ethyl formate: Ethylene: Ethylene diamine: Ethylene glycol: Ethylene oxide: Ethylmercaptan: 1-Ethylnaphthalene: 2-Ethylnaphthalene: Ethyl proprionate: Ethyl propylether: Ettouney, H, Euler number: Eutectic mixtures, condensation of forming immiscible liquids, Evaporation: Evaporative crystallisers, Evaporators: Exergy, definition of, Exergy analysis, Exit losses for tubes in shell-and-tube exchanger, Expansion bellows, for shell-and-tube heat exchangers: EJMA (Expansion Joint Manufacturers Association), standards for Expansion joints, mechanical design of: Expansion of tubes into tube sheets: Expansion turbine, lost work in, Explosively clad plate, Explosive welding of tubes into tube sheets Explosive expansion joints, Extended surfaces (see also Fins) Externally induced convection, in kettle reboilers, Extinction coefficient, Extinction efficiency, Eyring fluid (non-Newtonian),
F G H I J K L M N O P Q R S T U V W X Y Z
E E-type shells in shell-and-tube heat exchangers: recommended calculation methods for pressure drop and heat transfer in,
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Shell-and-Tube Heat Exchanger Design: Objectives and Background

DOI 10.1615/hedhme.a.000247

3.3.1 and 3.3.4 Shell-and-tube heat exchanger design: objectives and background

J. Taborek

The basic design of shell-and-tube exchangers was introduced in the early 1900s to fill the needs in power plants for large heat exchanger surfaces as condensers and feedwater heaters capable of operating under relatively high pressures. Both of these original applications of shell-and-tube heat exchangers continue to be used, but the designs have become highly sophisticated and specialized, subject to various specific codes and practices.

The broad industrial use of shell-and-tube heat exchangers known today also started in the 1900s to accommodate the demands of the emerging oil industry. Oil heaters and coolers, reboilers, and condensers for a variety of crude oil fraction and related organic liquids were required for rugged outdoor service, often "dirty" fluids, and high temperatures and pressures. Ease of cleaning and field repairs was unconditionally required.

The most serious problems in these early stages of shell-and-tube heat exchanger development appeared not to be those of heat transfer (which was crudely estimated from practice) but rather of material strength calculations for the various components, especially tubesheets. A host of other problems in the area of manufacturing techniques and practices followed, such as tube-to-tubesheet joints, flange and nozzle welding, and so on, surprisingly many being still on the list of items of continued concern and development.

During the 1920s shell-and-tube manufacturing technology became fairly well developed, mainly because of the efforts of relatively few major manufacturers. Units up to 500 m2 (5,000 ft2), that is, approximately 750-mm diameter and 6-m length (3 ft by 16 ft), were manufactured for the rapidly growing oil industry. In the 1930s, the shell-and-tube heat exchanger designers established many sound design principles from intuition and data emerging on ideal tube banks. Water-water and water-steam exchangers were probably designed about as well as they are today, because of the predominant effects of fouling resistances. Viscous flow was one of the most difficult problems for shell-side flow and was poorly understood until the 1960s. Shell-side pressure drop is not even mentioned in the literature until the late 1940s. Condensers and reboilers were designed purely to experience-derived values, often tightly guarded secrets of the manufacturers.

The need for mechanical design standards was equally important for reasons of safety, uniformity of tolerances, quality control, and general orderliness in competition. The first such document is the TEMA Standards of 1941 (TEMA, 1941), presently in its sixth edition and considered a standard practice all over the world.

In the following sections, an and a method for sizing shell-and-tube heat exchangers will be presented. The former is an estimation method that can be used those occasions (e.g. assessment of plant cost, layout, and space requirements) when a good approximate size estimate of shell-and-tube heat exchangers is sufficient. This will provide a quicker answer than a detailed design. The detailed method (of intermediate complexity) includes a modified version of the Bell-Delaware method and the .

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