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ROLE OF METAL FOAM IN SOLAR HEAT TECHNOLOGY
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Adzhiev, V., Kartasheva, E., Kunii, T. Cellularfunctional modeling of heterogeneous objects Proceedings of theseventh. In: ACM Symposium on Solid Modeling and Applications 2002.
Schroeder, C., Reglia, W., Shokoufandeh, A., Sun W. Computer-aided design of porous artifacts. Computer-aided design no. 37, 2005.
Darcy, H. Les fontaines publiques de la ville de Dijon. Paris: Dalmont, 1856.
Kruger, E. Die Grundwasserbewegung, Internationale Mitteilungen fur Bodenkunde, 8 (105), 1918.
Khayargoli, P., Loya, V., Lefebvre, L., Medraj, M. The impact of microstructure on the permeability of metal foams. CSME Forum, 2004.
Davis, P. A. et al., Application of a validation strategy to Darcy’s experiment, Advances in Water Resources, 15: 175-180, 1992.
Boomsma, K., Poulikakos, D. “The effects of Compres sion and Pore Size Variations on the Liquid Flow Characteristics in Metal Foams” J. of Fluid Engineering, 124: 263-272, 2002.
Beckermann, C., Viskanta, R., ‘‘Forced convection boundary layer flow and heat transfer along a flat plate embedded in a porous me dium,’’ Int. J. of Heat and Mass Transfer, 30: 1547– 1551, 1986.
Mostafid, A., Entrance and Exit Effects on Flow through Metallic Foams. Thesis. The department of Mechanical Engineering Concordia University, Montreal 2007.
Solidworks Flow Simulation 2009 Technical References. SolidWorks CORP, 2009.
Boomsma, K., Poulikakos, D., Zwick, F. Metal foams as compact high performance heat exchangers. Mechanics of Materials 35 (2003) 1161–1176.
Hening, M.: Solar-thermal absorber, has metal foam thermally and conductively connected with cover on side turned toward incident sunlight after installation, where cover is coated with black color, Patentový spis DE102009040039(A1). 28. 8. 2009.
Yongxin Zheng Fan, L.: Double-pipe high-efficiency foam metal heat exchanger, Patentový spis CN201392115 (Y). 17. 03. 2009.
Rybár, R.: Inovačné riešenia v odvetví solárnej tepelnej techniky ako nástroj rozvoja OZE. Habilitačná práca. FBERG TU v Košiciach, Košice 2006.
Rybár, R. - Tauš, P. - Cehlár, M.: Solárna energia a heliotechnika 1. vyd - Košice : FBERG TU, - 2009. - 147 s. - ISBN 978-80-553-0216-4.
Rybár, R. - Horodníková, J. - Perunko, S.: Vývoj nekovového strednoteplotného solárneho kolektora. In: Energie 21. Vol. 4, no. 1 (2011), p. 34-35. - ISSN 1803-0394
Rybár, R. - Horodníková, J. - Kudelas, D. - Beer, M.: Posúdenie možnosti uplatnenia štruktúr na báze kovových pien v konštrukcii absorbéra solárneho kolektora. In: ALER 2011 : Alternatívne zdroje energie : 7. ročník vedecko-odbornej konferencie s medzinárodnou účasťou : Lipt ovský Ján, 6. - 7. októbra 2011. - Žilina : EDIS, 2011 S. 18-25. - ISBN 978-80-554-0427-1
Adzhiev, V., Kartasheva, E., Kunii, T. Cellularfunctional modeling of heterogeneous objects Proceedings of theseventh. In: ACM Symposium on Solid Modeling and Applications 2002.
Schroeder, C., Reglia, W., Shokoufandeh, A., Sun W. Computer-aided design of porous artifacts. Computer-aided design no. 37, 2005.
Darcy, H. Les fontaines publiques de la ville de Dijon. Paris: Dalmont, 1856.
Kruger, E. Die Grundwasserbewegung, Internationale Mitteilungen fur Bodenkunde, 8 (105), 1918.
Khayargoli, P., Loya, V., Lefebvre, L., Medraj, M. The impact of microstructure on the permeability of metal foams. CSME Forum, 2004.
Davis, P. A. et al., Application of a validation strategy to Darcy’s experiment, Advances in Water Resources, 15: 175-180, 1992.
Boomsma, K., Poulikakos, D. “The effects of Compres sion and Pore Size Variations on the Liquid Flow Characteristics in Metal Foams” J. of Fluid Engineering, 124: 263-272, 2002.
Beckermann, C., Viskanta, R., ‘‘Forced convection boundary layer flow and heat transfer along a flat plate embedded in a porous me dium,’’ Int. J. of Heat and Mass Transfer, 30: 1547– 1551, 1986.
Mostafid, A., Entrance and Exit Effects on Flow through Metallic Foams. Thesis. The department of Mechanical Engineering Concordia University, Montreal 2007.
Solidworks Flow Simulation 2009 Technical References. SolidWorks CORP, 2009.
Boomsma, K., Poulikakos, D., Zwick, F. Metal foams as compact high performance heat exchangers. Mechanics of Materials 35 (2003) 1161–1176.
Hening, M.: Solar-thermal absorber, has metal foam thermally and conductively connected with cover on side turned toward incident sunlight after installation, where cover is coated with black color, Patentový spis DE102009040039(A1). 28. 8. 2009.
Yongxin Zheng Fan, L.: Double-pipe high-efficiency foam metal heat exchanger, Patentový spis CN201392115 (Y). 17. 03. 2009.
Rybár, R.: Inovačné riešenia v odvetví solárnej tepelnej techniky ako nástroj rozvoja OZE. Habilitačná práca. FBERG TU v Košiciach, Košice 2006.
Rybár, R. - Tauš, P. - Cehlár, M.: Solárna energia a heliotechnika 1. vyd - Košice : FBERG TU, - 2009. - 147 s. - ISBN 978-80-553-0216-4.
Rybár, R. - Horodníková, J. - Perunko, S.: Vývoj nekovového strednoteplotného solárneho kolektora. In: Energie 21. Vol. 4, no. 1 (2011), p. 34-35. - ISSN 1803-0394
Rybár, R. - Horodníková, J. - Kudelas, D. - Beer, M.: Posúdenie možnosti uplatnenia štruktúr na báze kovových pien v konštrukcii absorbéra solárneho kolektora. In: ALER 2011 : Alternatívne zdroje energie : 7. ročník vedecko-odbornej konferencie s medzinárodnou účasťou : Lipt ovský Ján, 6. - 7. októbra 2011. - Žilina : EDIS, 2011 S. 18-25. - ISBN 978-80-554-0427-1
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