Process Heat Transfer (2nd Ed.) Principles, Applications and Rules of Thumb
Auteurs : Serth Robert W., Lestina Thomas
Process Heat Transfer is a reference on the design and implementation of industrial heat exchangers. It provides the background needed to understand and master the commercial software packages used by professional engineers in the design and analysis of heat exchangers. This book focuses on types of heat exchangers most widely used by industry: shell-and-tube exchangers (including condensers, reboilers and vaporizers), air-cooled heat exchangers and double-pipe (hairpin) exchangers. It provides a substantial introduction to the design of heat exchanger networks using pinch technology, the most efficient strategy used to achieve optimal recovery of heat in industrial processes.
Heat Conduction; Convective and Radiative Heat Transfer; Heat Exchangers; Design of Double-Pipe Heat Exchangers; Design of Shell and Tube Heat Exchangers; The Delaware Method; The Stream Analysis Method; Heat Exchanger Networks; Boiling Heat Transfer; Reboilers; Condensers; Air-Cooled Heat Exchangers; Appendix
Chemical and Process Engineers, Mechanical Engineers, Plant Engineers; Graduate students.
Vice President, Research & Engineering Services, Heat Transfer Research, Inc, TX, USA. Tom Lestina has more than 30 years of engineering and project management experience.
- Utilizes leading commercial software. Get expert HTRI Xchanger Suite guidance, tips and tricks previously available via high cost professional training sessions.
- Details the development of initial configuration for a heat exchanger and how to systematically modify it to obtain an efficient final design.
- Abundant case studies and rules of thumb, along with copious software examples, provide a complete library of reference designs and heuristics for readers to base their own designs on.
Date de parution : 04-2014
Ouvrage de 632 p.
21.4x27.6 cm
Mots-clés :
Air-cooled heat exchanger; Aspen Energy Analyzer; Bell-Ghaley method; Chen correlation; Chisholm correlation; Condensers; Delaware method; Double-pipe; Fourier's law; HEN; HEXTRAN; HTRI; HTRI Xchanger Suite; Heat-transfer coefficient; Kettle reboiler; LMTD; Liu-Winterton correlation; Lockhart-Martinelli correlation; Mostinski correlation; Nusselt theory; Pinch design; Problem Table algorithm; R-value; Shell-and tube; Simplified Delaware method; Stefan-Boltzman equation; Stream analysis; Two-phase flow; Wegstein method; Wills-Johnston method; Xchanger Suite; area target; black body; bypass streams; composite curves; conduction shape factor; convective boiling; cooper correlation; design; dome segment area; error function; extended surface; fan sizing; film boiling; finned annulus; finned tubing; finned-pipe; forced convection; forced-draft; fouling factor; free convection; gray body; hairpin; heat conduction equation; heat exchanger; heat exchanger effectiveness; heat-transfer fin; high-fin tubing; horizontal thermosyphon; hydraulic calculations; ideal tube bank correlation; induced-draft; interfacial shear; leakage streams; minimum approach; mixed convection; mixture boiling; multi-tube hairpin; non-condensable gas; over-design; over-surface; overall heat-transfer coefficient; plate-and-frame; plate-fin; pool boiling; propane condenser; reboiler piping; self-venting nozzle; shell-and-plate; shell-and-tube; shell-side calculations; shell-side clearances; shell-side geometry; super targeting; targeting; temperature cross; temperature profile; temperature profile distortion; thermal conductivity; thermal resistance; venting; vertical thermosyphon
