441--Tube Bundle Vibration Characteristics

doi:10.1615/hedhme.a.000441

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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

F-correction method: F-factor charts and equations for various heat exchanger configurations, F-factor method: F-type shells: Fabrication: Failure modes of heat exchangers, Falling films, direct contact heat transfer in, Falling film evaporator: Fanno flow, Fans in air-cooled heat exchangers: Fatigue as failure mode of a heat exchanger Fatigue life, of expansion bellows, Fawcett, R Fedor's method, for critical temperature, Fenghour, A Ferritic stainless steels, as material of construction, Fick's law for diffusion, Film boiling: Film model, condenser design by Film temperature, definition of for turbulent flow over flat plate, Films in heat exchangers, Filmwise condensation: Fincotherm, heat transfer medium, Finite-difference equations: Finite difference methods: Finite-element methods: Fins (see also Extended surfaces): Fire-tube boiler, Fired heaters, Fires, room, radiation interaction phenomena in, Firsova, E V, Fixed beds: Fixed tubesheet, shell-and-tube exchangers: Flanges, mechanical design of in heat exchangers, Flash evaporation Flat absorber of thermal radiation, Flat heads: Flat plate: Flat reflector of thermal radiation, Floating head designs for shell-and-tube heat exchangers: Flooded type evaporator, in refrigeration, Flooding phenomena: Flow distribution: Flow-induced vibration,

Introduction design considerations, introduction, prediction procedure, shell-side velocities causing, tube bundle vibration characteristics,

Tube Bundle Vibration Characteristics amplitude of vibration, damping, finned-tube natural frequencies, span lengths, straight tube natural frequencies, U-bend tube natural frequencies,

vibration phenomena,

Flow regimes: Flow stream analysis method for segmentally baffled shell and tube heat exchangers, Flue gases, fouling by, Fluid elastic instability as source of flow-induced vibration, Fluid flow, lost work in, Fluid mechanics, Eulerian formulation for, Fluid-to-particle heat transfer in fluidized beds, Fluidized bed dryer: Fluidized bed gravity conveyors, Fluidized beds: Fluids: Fluorine: Fluorobenzene: Fluoroethane (Refrigerant 161): Fluoromethane (Refrigerant 41): Fluted tubes: Flux method, for modeling radiation in furnaces, Flux relationships in heat exchangers, Fogging in condensation Food processing, fouling of heat exchangers in, Forced flow reboilers: Formaldehyde: Formamide: Formic acid: Forster and Zuber correlation for nucleate boiling, Fouling, Foam systems, heat transfer in, Four phase flows, examples, Fourier law for conduction Fourier number (Fo): Frames for plate heat exchangers, France, guide to national practice for mechanical design, Free convection: Free-fall velocity, of particles, Free-stream turbulence, effect on flow over cylinders, Freeze protection of air-cooled heat exchangers, Freezing, of condensate in condensers Fresnel relations in reflection of radiation, Fretting corrosion, Friction factor: Friction multipliers in gas-liquid flow: Friction velocity, definition, Friedel correlation for frictional pressure gradient in straight channels, Froude number: Fuels, properties of, Fuller, R K, Furan: Furfural: Furnaces: Fusion welding, of tubes into tubesheets in shell-and-tube heat exchangers,

Index

HEDH

A B C D E F

F-correction method: F-factor charts and equations for various heat exchanger configurations, F-factor method: F-type shells: Fabrication: Failure modes of heat exchangers, Falling films, direct contact heat transfer in, Falling film evaporator: Fanno flow, Fans in air-cooled heat exchangers: Fatigue as failure mode of a heat exchanger Fatigue life, of expansion bellows, Fawcett, R Fedor's method, for critical temperature, Fenghour, A Ferritic stainless steels, as material of construction, Fick's law for diffusion, Film boiling: Film model, condenser design by Film temperature, definition of for turbulent flow over flat plate, Films in heat exchangers, Filmwise condensation: Fincotherm, heat transfer medium, Finite-difference equations: Finite difference methods: Finite-element methods: Fins (see also Extended surfaces): Fire-tube boiler, Fired heaters, Fires, room, radiation interaction phenomena in, Firsova, E V, Fixed beds: Fixed tubesheet, shell-and-tube exchangers: Flanges, mechanical design of in heat exchangers, Flash evaporation Flat absorber of thermal radiation, Flat heads: Flat plate: Flat reflector of thermal radiation, Floating head designs for shell-and-tube heat exchangers: Flooded type evaporator, in refrigeration, Flooding phenomena: Flow distribution: Flow-induced vibration,

Introduction design considerations, introduction, prediction procedure, shell-side velocities causing, tube bundle vibration characteristics,

Tube Bundle Vibration Characteristics amplitude of vibration, damping, finned-tube natural frequencies, span lengths, straight tube natural frequencies, U-bend tube natural frequencies,

vibration phenomena,

Flow regimes: Flow stream analysis method for segmentally baffled shell and tube heat exchangers, Flue gases, fouling by, Fluid elastic instability as source of flow-induced vibration, Fluid flow, lost work in, Fluid mechanics, Eulerian formulation for, Fluid-to-particle heat transfer in fluidized beds, Fluidized bed dryer: Fluidized bed gravity conveyors, Fluidized beds: Fluids: Fluorine: Fluorobenzene: Fluoroethane (Refrigerant 161): Fluoromethane (Refrigerant 41): Fluted tubes: Flux method, for modeling radiation in furnaces, Flux relationships in heat exchangers, Fogging in condensation Food processing, fouling of heat exchangers in, Forced flow reboilers: Formaldehyde: Formamide: Formic acid: Forster and Zuber correlation for nucleate boiling, Fouling, Foam systems, heat transfer in, Four phase flows, examples, Fourier law for conduction Fourier number (Fo): Frames for plate heat exchangers, France, guide to national practice for mechanical design, Free convection: Free-fall velocity, of particles, Free-stream turbulence, effect on flow over cylinders, Freeze protection of air-cooled heat exchangers, Freezing, of condensate in condensers Fresnel relations in reflection of radiation, Fretting corrosion, Friction factor: Friction multipliers in gas-liquid flow: Friction velocity, definition, Friedel correlation for frictional pressure gradient in straight channels, Froude number: Fuels, properties of, Fuller, R K, Furan: Furfural: Furnaces: Fusion welding, of tubes into tubesheets in shell-and-tube heat exchangers,

G H I J K L M N O P Q R S T U V W X Y Z

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Tube Bundle Vibration Characteristics

DOI 10.1615/hedhme.a.000441

4.6.2 Tube bundle vibration characteristics

James M. Chenoweth

Every component of a shell-and-tube heat exchanger vibrates at its own unique natural frequencies. Tubes are generally the most flexible parts and thus the most easily excited. Tubes can and do vibrate at different frequencies. The lowest natural frequency for any tube is called the fundamental or first mode. Higher natural frequencies are referred as the second mode, third mode, and so on. For conservative design purposes, only the fundamental natural frequency will be considered and will be called simply the natural frequency.

The natural frequency of a tube, like that of a simple beam, depends on the length of spans, how the ends are supported (clamped or simply), the type of intermediate supports (simply supported, pinned, or clamped), the cross-sectional geometry, the number of spans, and the materials of construction. Although the natural frequency of tubes can be measured experimentally, predictive methods to estimate approximate values are suitable for most engineering purposes.

Tubes in shell-and-tube heat exchangers are generally considered to be (1) rigidly fastened in the tube-sheets and (2) simply supported at intermediate points of contact with baffles and/or support plates. Some tubes in the center of the bundle may be supported by every baffle, whereas tubes that pass through the baffle windows may be supported only by every second or third baffle. Furthermore, the end spacings are often wider than central baffle spacings to accommodate nozzles and shell flanges. Thus, tubes in various parts of a bundle have different patterns of support and this results in tubes with different natural frequencies in the same heat exchanger.

A. Natural frequencies of straight tubes

For the vibration analysis of most shell-and-tube heat exchangers, determination of the lowest natural tube frequency is adequate. This can be done using a rigorous approach (Gorman, 1975), a graphical approach (Moretti, 1973), or a finite-clement computer program such as NASTRAN (1973). These provide higher-mode natural frequencies in addition to the lowest and the mode shapes for each. Figure 1 shows natural frequencies and mode shapes for the first five modes of vibration for a typical six-cross-pass heat exchanger. Notice the similarity in the natural frequencies for first modes of vibration and the differences in mode shape. Such information is useful in interpreting the behavior of tube vibration.

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