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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
Nahme-Griffith number, Nakashima, CY Nanoparticles, for heat transfer augmentation, Naphthalene: Napthenes: National practice, in mechanical design, guide to, Natural convection: Natural draft cooling towers: Natural frequency of tube vibration in heat exchangers, Navier-Stokes equation, Neon: Neopentane: Net free area, in double-pipe heat exchangers, Netherlands, guide to national mechanical design practice, Networks, of heat exchangers, pinch analysis method for design of, Neumann boundary conditions, finite difference method, Nickel, thermal and mechanical properties Nickel alloys, Nickel steels, Niessen, R, Nitric oxide: Nitriles: Nitrobenzene: Nitro derivatives: Nitroethane: Nitrogen: Nitrogen dioxide: Nitrogen peroxide: Nitromethane: m-Nitrotoluene: Nitrous oxide Noise: Nonadecane: Nonadecene: Nonane: Nonene: Nonanol: Nonaqueous fluids, critical heat flux in, Non-circular microchannels: Noncondensables: Nondestructive testing, of heat exchangers Nongray media, interaction phenomena with, Nonmetallic materials: Non-Newtonian flow: Nonparticipating media, radiation interaction in, Nonuniform heat flux, critical heat flux with, Non-wetting surfaces, in condensation augmentation, North, C, No-tubes-in-window shells, calculation of heat transfer and pressure drop in, Nozzles:
design to ASME VIII, design to EN13445, design to PD5500
Design to PD 5500
impinging jets from, heat transfer in, loads in, loss coefficients in, in shell-and-tube heat exchangers: constructional features
Nowell, D G, Nucleate boiling: Nuclear industry, fouling problems in, Nucleation: Nucleation sites: Nuclei, formation in supersaturated vapor, Number of transfer units (NTU): Numerical methods: Nusselt: Nusselt-Graetz problem, in laminar heat transfer in ducts, Nusselt number:

Index

HEDH
A B C D E F G H I J K L M N
Nahme-Griffith number, Nakashima, CY Nanoparticles, for heat transfer augmentation, Naphthalene: Napthenes: National practice, in mechanical design, guide to, Natural convection: Natural draft cooling towers: Natural frequency of tube vibration in heat exchangers, Navier-Stokes equation, Neon: Neopentane: Net free area, in double-pipe heat exchangers, Netherlands, guide to national mechanical design practice, Networks, of heat exchangers, pinch analysis method for design of, Neumann boundary conditions, finite difference method, Nickel, thermal and mechanical properties Nickel alloys, Nickel steels, Niessen, R, Nitric oxide: Nitriles: Nitrobenzene: Nitro derivatives: Nitroethane: Nitrogen: Nitrogen dioxide: Nitrogen peroxide: Nitromethane: m-Nitrotoluene: Nitrous oxide Noise: Nonadecane: Nonadecene: Nonane: Nonene: Nonanol: Nonaqueous fluids, critical heat flux in, Non-circular microchannels: Noncondensables: Nondestructive testing, of heat exchangers Nongray media, interaction phenomena with, Nonmetallic materials: Non-Newtonian flow: Nonparticipating media, radiation interaction in, Nonuniform heat flux, critical heat flux with, Non-wetting surfaces, in condensation augmentation, North, C, No-tubes-in-window shells, calculation of heat transfer and pressure drop in, Nozzles:
design to ASME VIII, design to EN13445, design to PD5500
Design to PD 5500
impinging jets from, heat transfer in, loads in, loss coefficients in, in shell-and-tube heat exchangers: constructional features
Nowell, D G, Nucleate boiling: Nuclear industry, fouling problems in, Nucleation: Nucleation sites: Nuclei, formation in supersaturated vapor, Number of transfer units (NTU): Numerical methods: Nusselt: Nusselt-Graetz problem, in laminar heat transfer in ducts, Nusselt number:
O P Q R S T U V W X Y Z
N Nozzles: design to PD5500
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Design to PD 5500

DOI 10.1615/hedhme.a.000419

4.3 SHELL-AND-TUBE DESIGN CODES
4.3.2 Design to PD 5500

Richard Fawcett

A. General

(a) Introduction

PD 5500 as is usual with national pressure vessel is “updated” regularly. The version covered here is the third revision of PD 5500: 2000, September 2001 (British Standards Institution, 1997). It will continue to change, possibly prompted by reference here to some of its shortcomings. PD (Published Document) 5500 replaces BS 5500 which has now been withdrawn because its status as a national standard would be incompatible with BSI’s obligations to CEN when the European standard for unfired pressure vessels, EN 13445 (European Committee for Standardisation 1999), is published. PD 5500 has the same scope and content as had BS 5500 and differs only in so far as it does not retain the latter’s status as a national standard. This brings the UK into line with several other major European countries whose existing national pressure vessel codes are not national standards.

References in Section 419 to PD 5500 begin with “PD”, to distinguish them from references to HEDH.

The general method adopted herein for each topic is to indicate where it is dealt with in PD 5500, followed by such comments and explanation as are thought to be helpful. Attention is drawn to important bits that may easily be missed. The British Standards committee responsible for this code has tried over the years to make it clear and has provided explanatory material (either as notes in the text or separate documents) that it is not our task to duplicate here.

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