Complete heat transfer solutions of an insulated regular polyhedron by using an RPSWT model

Energy Conversion and Management

Volumn 46, Issue 13-14, 2005, Pages 2232-2257

  Lee, Jenn Fa ^a   Wong, King Leung ^a   Chen, Wen Lih ^a   Ku, Shih Shih ^a  

^a KUN SHAN UNIVERSITY   (Taiwan)

Author keywords

Complete solution; Critical thickness; Insulation; Neutral thickness; Polyhedron; RPSWT model; Sphere

Indexed keywords

ELECTRIC CONDUCTIVITY; HEAT CONVECTION; HEAT RESISTANCE; PLASTICS; SPHERES; SURFACE PROPERTIES; THICKNESS MEASUREMENT;

COMPLETE SOLUTION; CRITICAL THICKNESS; NEUTRAL THICKNESS; POLYHEDRON; RPSWT MODEL;

INSULATION;

EID: 16344386441     PISSN: 01968904     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.enconman.2004.06.027     Document Type: Article

References (24)

1. A.W. Porter On the lagging of pipes and wires Philos. Mag. London 20 1910 511
2. J.D. Lewins, and T.T. Cockerill On the teapot and its cosy Int. J. Mech. Eng. Educat. 22 1993 301 306
3. A. Bejan Heat transfer 1993 John Wiley and Sons, Inc. New York p. 42-5
4. F.P. Incropera, and D.P. DeWitt Fundamentals of heat transfer 1990 John Wiley and Sons, Inc. New York p. 79-91
5. J.P. Holman Heat transfer 1990 McGraw-Hill Inc. pp. 28-45
6. A.F. Mills Basic heat and mass transfer. University of California at Los Angles 1995 Irwin Homewood, IL pp. 7-28
7. F. Kreith, and M.S. Bohn Principles of heat transfer fifth ed. 1993 Harper International Edition pp. 21-41
8. Janna WS. Engineering heat transfer. PWS engineering Boston. PWS Publishers; 1986. p. 61-71
9. J.H. Lienhard A heat transfer textbook second ed. 1987 Prentice-Hall Inc. p. 62-3
10. Witty JR, Engineering heat transfer. SI version. John Wiley and Sons; 1978. p. 70-3
11. Ozisik MN. Heat transfer. A basic approach. McGraw Hill Book Company; 1988. p. 59-62
12. E.G. Pita Air conditioning principles and system third ed. 1998 Prentice Hall p. 252-6
13. W.F. Stoecker, and J.W. Jones Refrigeration and air conditioning 2nd ed. 1982 McGraw-Hill Inc. pp. 24-35
14. R.J. Dossat Principles of refrigeration 3rd ed. 1991 Prentice Hall pp. 167-78
15. R. Chatenever Air conditioning and refrigeration for the professional 1988 John Wiley & Sons, Inc. p. 445-8
16. H.M. Chou, and K.L. Wong Heat transfer characteristics of an insulated regular polygonal pipe by using a wedge thermal resistance model Energy Convers. Manage. 44 2003 629 645
17. H.M. Chou, and K.L. Wong Heat transfer characteristics of an insulated regular cubic tank by using a solid wedge thermal resistance model Energy Convers Manage. 44 2003 1983 1997
18. K.L. Wong, and H.M. Chou Heat transfer characteristics of an insulated regular polyhedron by using a regular polygon-top solid wedge thermal resistance model Energy Convers Manage. 44 2003 3015 3036
19. M.S. Soylemez, and M. Unsal Optimum insulation thickness for refrigeration applications Energy Convers Manage. 40 1999 13 21
20. H.M. Chou The optimum interior area thermal resistance model to analyze the heat transfer characteristics of an insulated pipe with arbitrary shape Energy Convers Manage. 44 2003 2915 2939
21. Wong KL, Chou HM, Li, YH. The optimum interior area thermal resistance model to analyze the heat transfer characteristics of an insulated container with arbitrary shape. Energy Convers Manage 2004;45:963-82
22. Wong KL, Chou HM, Li, YH. Complete heat transfer solutions of an insulated regular cubic tank with an SSWT model. Energy Convers Manage 2004;45: 1705-24
23. Wong KL, Chou HM, Her, BS, Yeh, HC. The complete heat transfer solutions of an insulated regular cubic tank with a SSWT model. Energy Convers Manage [accepted]
24. Spiegel MR. Schaum's outline series. Theory and problems of vector analysis. The Southeast Book Company. McGraw Hill Book Company; 1959. p. 125-6