Extended Surface Heat TransferJohn Wiley & Sons, 14 бер. 2002 р. - 1120 стор. Drei anerkannte Experten dieses schnellebigen, modernen Fachgebiets erläutern hier Theorie, Design und Anwendungen eines breiten Spektrums von Oberflächen, die speziell für den effizienten Wärmetransport ausgelegt sind. Behandelt werden u. a. kompakte Wärmetauscher, periodische Wärmeströme und Siedevorgänge an Kühlrippen. Umfassend und informativ! |
Зміст
1 | |
2 CONVECTION WITH REAL CONSTRAINTS | 59 |
3 CONVECTIVE OPTIMIZATIONS | 102 |
4 CONVECTION COEFFICIENTS | 160 |
5 LINEAR TRANSFORMATIONS | 220 |
6 ELEMENTS OF LINEAR TRANSFORMATIONS | 244 |
7 ALGORITHMS FOR FINNED ARRAY ASSEMBLY | 308 |
8 ADVANCED ARRAY METHODS AND ARRAY OPTIMIZATION | 337 |
14 OPTIMUM DESIGN OF RADIATING AND CONVECTINGRADIATING FINS | 636 |
15 MULTIDIMENSIONAL HEAT TRANSFER IN FINS AND FIN ASSEMBLIES | 699 |
16 TRANSIENT HEAT TRANSFER IN EXTENDED SURFACES | 754 |
17 PERIODIC HEAT FLOW IN FINS | 819 |
18 BOILING FROM FINNED SURFACES | 844 |
19 CONDENSATION ON FINNED SURFACES | 880 |
20 AUGMENTATION AND ADDITIONAL STUDIES | 948 |
APPENDIX AGAMMA AND BESSEL FUNCTIONS | 971 |
9 FINNED PASSAGES | 390 |
10 COMPACT HEAT EXCHANGERS | 443 |
11 LONGITUDINAL FIN DOUBLEPIPE EXCHANGERS | 489 |
12 TRANSVERSE HIGHFIN EXCHANGERS | 540 |
13 FINS WITH RADIATION | 572 |
APPENDIX B MATRICES AND DETERMINANTS | 1005 |
1034 | |
AUTHOR INDEX | 1075 |
1087 | |
Інші видання - Показати все
Extended Surface Heat Transfer Allan D. Kraus,Abdul Aziz,James Welty Попередній перегляд недоступний - 2002 |
Extended Surface Heat Transfer Allan D. Kraus,Abdul Aziz,James Welty Попередній перегляд недоступний - 2001 |
Загальні терміни та фрази
admittance analysis application array assumed base temperature becomes boiling calculated Chapter combination considered constant convection coordinate correlation cosh curves derivative determine developed diameter difference dimensionless dimensions effect element employed equal equation evaluated Example expression extended faces factor Figure fin efficiency fin height fin of rectangular finned first fluid function geometry given gives heat dissipation heat exchanger heat flow heat transfer coefficient increases length linear longitudinal fin loss matrix method noted observed obtained optimization optimum parabolic parameter performance pipe plate presented pressure problem radial fin radiation radius ratio rectangular profile relationship resistance shown in Fig shows side single sinh solution spacing spine surface Table tanh temperature excess thermal conductivity thickness transformation triangular tube vapor variable yields
Популярні уривки
Сторінка 1038 - Department of Mechanical Engineering, Ben-Gurion University of the Negev, Beer Sheva, Israel.
Сторінка 7 - Examples of finned surfaces: (a ) Longitudinal fin of rectangular profile ; (b ) cylindrical tube equipped with fins of rectangular profile: (c) longitudinal fin of trapezoidal profile: (d) longitudinal fin of parabolic profile; (e) cylindrical tube equipped with radial fin of rectangular profile; (/) cylindrical tube equipped with radial fin of truncated conical profile; (g) cylindrical spine; (h ) truncated conical spine; (i) parabolic spine.
Сторінка 10 - The heat transfer coefficient to or from the fin is constant and uniform over the entire surface of the fin. 4 The temperature of the medium surrounding the fin is uniform. 5 The fin thickness is so small compared with its height that temperature gradients across the fin thickness can be neglected.
Сторінка 1054 - Analysis of temperature distribution and radiant heat transfer along a rectangular fin of constant thickness, NASA TN D-196 (1959).
Сторінка 10 - The fin thickness is so small compared with its height that temperature gradients across the fin thickness can be neglected. 6 The temperature at the base of the fin is uniform. 7 There is no contact resistance where the base of the fin joins the prime surface. 8 There are no heat sources within the fin itself.