Heat Exchanger DesignThis Second Edition of the well-received work on design, construction, and operation of heat exchangers. Demonstrates how to apply theories of fluid mechanics and heat transfer to practical problems posed by design, testing, and installation of heat exchangers. Tables and data have been brought up to date, and there is new material on problems of vibration and fouling, and on optimization of energy use in the chemical process and manufacturing industries. Covers all basic principles of heat exchanger design, and addresses many specialized situations encountered in engineering applications. |
Contents
I | 1 |
II | 23 |
III | 39 |
IV | 70 |
V | 87 |
VI | 127 |
VII | 140 |
VIII | 151 |
XVII | 337 |
XVIII | 365 |
XIX | 383 |
XX | 402 |
XXII | 417 |
XXIII | 418 |
XXIV | 423 |
XXV | 440 |
IX | 175 |
X | 200 |
XI | 216 |
XII | 228 |
XIII | 246 |
XIV | 266 |
XV | 285 |
XVI | 316 |
XXVIII | 452 |
XXIX | 462 |
XXX | 490 |
XXXI | 502 |
XXXII | 517 |
XXXIV | 529 |
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Common terms and phrases
applications ASME axial Babcock and Wilcox baffle boiler boiling brazing Btu/h ft² calculated condenser cooling tower corrosion cost counterflow Courtesy Oak Ridge crossflow curves density effects enthalpy feedwater Figure film fins fluid flow fluid streams friction factor geometry header sheet heat exchanger heat flux heat pipe heat transfer coefficient heat transfer matrix heat transfer surface increase inlet laminar flow lb/ft³ lb/h liquid LMTD mass flow rate metal nuclear number of tubes Nusselt Oak Ridge National obtained operation outlet particles passage plate power plant preheating pressure drop problems radiator ratio reactor region Reynolds number shell shell-side shown in Fig steam stress superheater surface area Table temperature difference thermal conductivity thermal radiation thickness tion Trans tube banks tube bundle tube diameter tube length tube matrix turbine turbulent typical unit velocity distribution viscosity W/m² welded