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Metal foams as structural packing in the construction of process equipment

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Warianty tytułu
PL
Piany metalowe jako wypełnienia strukturalne w budowie aparatury przemysłowej
Języki publikacji
EN
Abstrakty
EN
The paper presents possibilities of the application of open-cell metal foams in the construction of process equipment. The article also describes results of own experimental studies on hydrodynamic and thermal phenomena occurring during fluid flow through channels packed with aluminium alloy foams. The collected experimental data enabled to determine, among others, pressure drops and the heat transfer coefficient, and to indicate main gas–liquid flow patterns.
PL
W artykule przedstawiono możliwości wykorzystania otwartokomórkowych pian metalowych w budowie aparatury przemysłowej. Opisano wyniki własnych badań doświadczalnych dotyczących zjawisk hydrodynamicznych i cieplnych zachodzących podczas przepływu płynu przez kanały wypełnione pianami ze stopów aluminium. Zebrane dane eksperymentalne pozwoliły określić m.in. wartości oporów przepływu i współczynnika wnikania ciepła oraz wskazać podstawowe struktury przepływu gaz–ciecz.
Rocznik
Strony
165--178
Opis fizyczny
Bibliogr. 23 poz. il., tab., wz., wykr.
Twórcy
autor
  • Department of Chemical and Process Engineering, Faculty of Mechanical Engineering, Opole University of Technology
Bibliografia
  • [1] Boomsma K., Poulikakos D., Zwick F., Metal foams as compact high performance heat exchangers, Mechanics of Materials, 35, 2003, 1161–1176.
  • [2] Cha J.S., Ghiaasiaan S.M., Kirkconnell C.S., Longitudinal hydraulic resistance Parameters of cryocooler and stirling Regenerators in periodic flow, Advances in Cryogenic Engineering: Transactions of the Cryogenic Engineering Conference – CEC, 53, 2008, 259–266.
  • [3] Cookson E.J., Floyd D.E., Shih A.J., Design, manufacture, and analysis of metal foamelectrical resistance heather, Int. J. Mechanical Sciences, 48, 2006, 1314–1322.
  • [4] Dyga R., Płaczek M., Heat transfer through metal foam–fluid system, Experimental Thermal and Fluid Science, Vol. 65, 2015, 1–12.
  • [5] Dyga R., Płaczek M., Przepuszczalność i współczynnik inercji pian aluminiowych o komórkach otwartych, Inżynieria i Aparatura Chemiczna, 4, 2013, 300–301.
  • [6] Hu H., Zhu Y., Ding G, Sun S., Effect of oil on two-phase pressure drop of refrigerant flow boiling inside circular tubes filled with metal foam, International Journal of Refrigeration, 36, 2013, 516–526.
  • [7] Incera Garrido G., Patcas F.C., Lang S., Kraushaar-Czarnetzki B., Mass transfer and pressure drop in ceramic foams: Adescription for differentporesizesand porosities, Chemical Engineering Science, Vol. 63, 2008, 5202–5217.
  • [8] Ji W.-T., Qu Z.-G., Li Z.-Y., Guo J.-F., Zhang D.-C., Tao W.-Q., Pool boiling heat transfer of R134a on single horizontal tube surfaces sintered with open-celled copper foam, International Journal of Thermal Sciences, 50, 2011, 2248–2255.
  • [9] Kamath P.M., Balaji C., Venkateshan S.P., Experimental investigation of flow assisted mixed convection in high porosity foams in vertical channels, International Journal of Heat and Mass Transfer, 54, 2011, 5231–5241.
  • [10] Lévêque J., Rouzineau D., Prévost M., Meyer M., Hydrodynamic and mass transfer efficiency of ceramic foam packing applied to distillation, Chemical Engineering Science, 64, 2009, 2607–2616.
  • [11] Ozmat B., Leyda B., Benson B., Thermal applications of open cell metal foams, Character and Manufacturing Processes, Vol. 19(5), 2004, 839–862.
  • [12] Pangarkar K.,Schildhauer T.J., van Ommen J.R., Nijenhuis J., Moulijn J.A., Kapteijn F., Heat transport in structured packings with co-current downflow of gas and liquid, Chemical Engineering Science, 65, 2010, 420–426.
  • [13] Paserin V., Marcuson S., Shu J., Wilkinson D.S., The chemical vapor deposition technique for Inco nickel foam production–manufacturing benefits and potential applications, Cellular Metalls and Foaming Technology, 2003, ftp://207.102.129.71/Richard/stuff/Ni-MH/metfoam_03_paper.pdf (access: 17.11.2013).
  • [14] Ribeiro G.B., Barbosa Jr.J.R., Comparison of metal foam and louvered fins as air-side heat transfer enhancement media for miniaturized condensers, Applied Thermal Engineering, 51, 2013, 334–337.
  • [15] Stemmet C.P., Meeuwse M., van der Schaaf J., Kuster B.F.M., Schouten J.C., Gas–liquid mass transfer and axial dispersion in solid foam packings, Chemical Engineering Science, 62, 2007, 5444–5450.
  • [16] Sertkaya A.A., Altınısık K., Dincer K., Experimental investigation of thermal performance of aluminum finned heat exchangers and open-cell aluminum foam heat exchangers, Experimental Thermal and Fluid Science, 36, 2012, 86–92.
  • [17] Tadrist L., Miscevic M., Rahli O., Topin F., About the use of fibrous materials in compact heat exchangers, Experimental Thermal and Fluid Science, 28, 2004, 193–199.
  • [18] Tian Y., Zhao C.Y., Thermal and exergetic analysis of Metal Foam-enhanced Cascaded Thermal Energy Storage (MF-CTES), International Journal of Heat and Mass Transfer, 58, 2013, 86–96.
  • [19] Tschentscher R., Schubert M., Bieberle A., Nijhuis T.A., van der Schaaf J., Hampel U., Schouten J.C., Tomography measurements of gas holdup in rotating foam reactors with Newtonian, non-Newtonian and foaming liquids, Chemical Engineering Science, 66, 2011, 3317–3327.
  • [20] Vadwala P.H., Thermal Energy Storage in Copper Foams filled with Paraffin Wax, Master of Applied Science, Mechanical & Industrial Engineering University of Toronto, 2011.
  • [21] Wang K., Ju Y.L., Lu X.S., Gu A.Z., On the performance of copper foaming metal in the heat exchangers of pulse tube refrigerator, Cryogenics, 47, 2007, 19–24.
  • [22] Wang P., Liu D.Y., Xu C., Numerical study of heat transfer enhancement in the receiver tube of direct steam generation with parabolic trough by inserting metal foams, Applied Energy, 102, 2013, 449–460.
  • [23] Xu Z.G., Qu Z.G., Zhao C.Y., Tao W.Q., Pool boiling heat transfer on open-celled metallic foam sintered surface under saturation condition, International Journal of Heat and Mass Transfer, 54, 2011, 3856–3867.
Uwagi
EN
Section "Mechanics"
PL
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017)
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-f78422f5-0cc3-44df-898f-8771eca6395c
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