Fe-shell/Cu-core encapsulated metallic phase change materials prepared by aerodynamic levitation method

Applied Energy

Volumn 132, Issue , 2014, Pages 568-574

  Ma, Bingqian ^a,b   Li, Jianqiang ^a   Xu, Zhe ^a   Peng, Zhijian ^b  

^a INSTITUTE OF PROCESS ENGINEERING   (China)

^b CHINA UNIVERSITY OF GEOSCIENCES   (China)

Author keywords

Aerodynamic levitation; Fe Cu; Immiscible alloys; Metallic phase change materials

Indexed keywords

AERODYNAMICS; COPPER ALLOYS; HEAT STORAGE; IRON OXIDES; LEVITATION MELTING; LIQUIDS; METALS; PACKAGING MATERIALS; PHASE SEPARATION; THERMAL CONDUCTIVITY; WEAR RESISTANCE;

AERODYNAMIC LEVITATION; HIGH ENERGY DENSITIES; HIGH THERMAL CONDUCTIVITY; LATENT HEAT STORAGE SYSTEM; LIQUID PHASE FRACTION; LIQUID PHASE SEPARATION; PACKAGING TECHNOLOGIES; PHASE CHANGE TEMPERATURE;

PHASE CHANGE MATERIALS;

EID: 84946735334     PISSN: 03062619     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.apenergy.2014.07.054     Document Type: Article

References (23)

1. Sun, J.Q., Zhang, R.Y., Liu, Z.P., Lu, G.H., Thermal reliability test of Al–34%Mg–6%Zn alloy as latent heat storage material and corrosion of metal with respect to thermal cycling. Energy Convers Manage 48 (2007), 619–624.
2. Liu, M., Bruno, F., Saman, W., Review on storage materials and thermal performance enhancement techniques for high temperature phase change thermal storage systems. Renew Sustain Energy Rev 16 (2012), 2118–2132.
3. Hoshi, A., Mills, D.R., Bitter, A., Saitoh, T.S., Screening of high melting point phase change materials (PCM) in solar thermal concentrating technology based on CLFR. Sol Energy 79 (2005), 332–339.
4. Sun, J.Q., Zhang, R.Y., Review of thermal energy storage with metal phase change materials. Mater Rev 19 (2005), 99–105.
5. Yagi, J., Akiyama, T., Storage of thermal energy for effective use of waste heat from industries. J Mater Process Technol 48 (1995), 793–804.
6. Sugo, H., Kisi, E., Cuskelly, D., Miscibility gap alloys with inverse microstructures and high thermal conductivity for high energy density thermal storage applications. Appl Therm Eng 51 (2013), 1345–1350.
7. Park, J.J., Butt, D.P., Beard, C.A., Review of liquid metal corrosion issues for potential containment materials for liquid lead and lead–bismuth eutectic spallation targets as a neutron source. Nucl Eng Des 196 (2000), 315–325.
8. Wang, C.P., Liu, X.J., Ohnuma, I., Kainuma, R., Ishida, K., Formation of immiscible alloy powders with egg-type microstructure. Science 297 (2002), 990–993.
9. Wang, C.P., Liu, X.J., Takaku, Y., Ohnuma, I., Kainuma, R., Ishida, K., Formation of core-type macroscopic morphologies in Cu–Fe base alloys with liquid miscibility gap. Metall Mater Trans A 35A (2004), 1243–1253.
10. Wang, C.P., Liu, X.J., Ohnuma, I., Kainuma, R., Ishida, K., Self-formed pencil-like bulk composite materials consisting of copper alloy and stainless steel. J Mater Res 23 (2008), 933–940.
11. Luo, B.C., Liu, X.R., Wei, B.B., Macroscopic liquid phase separation of Fe–Sn immiscible alloy investigated by both experiment and simulation. J Appl Phys, 106, 2009, 053523.
12. Wang, N., Zhang, L., Zheng, Y.P., Yao, W.J., Shell phase selection and layer number of core–shell structure in monotectic alloys with stable miscibility gap. J Alloys Compd 538 (2012), 224–229.
13. Lu, X.Y., Cao, C.D., Wei, B.B., Microstructure evolution of undercooled iron–copper hypoperitectic alloy. Mater Sci Eng A313 (2001), 198–206.
14. He, J., Zhao, J.Z., Ratke, L., Solidification microstructure and dynamics of metastable phase transformation in undercooled liquid Cu–Fe alloys. Acta Mater 54 (2006), 1749–1757.
15. Archibold, A.R., Gonzalez-Aguilar, J., Rahman, M.M., Goswami, D.Y., Romero, M., Stefanakos, E.K., The melting process of storage materials with relatively high phase change temperatures in partially filled spherical shells. Appl Energy 116 (2014), 243–252.
16. Wall, J.J., Weber, R., Kim, J., Liaw, P.K., Choo, H., Aerodynamic levitation processing of a Zr-based bulk metallic glass. Mater Sci Eng A 445–446 (2007), 219–222.
17. Wille, G., Millot, F., Rifflet, J.C., Thermophysical properties of containerless liquid iron up to 2500 K. Int J Thermophys 23 (2002), 1197–1206.
18. Chen, Q., Jin, Z.P., The Fe–Cu system: a thermodynamic evaluation. Metall Mater Trans A 26A (1995), 417–426.
19. Ma, B.Q., Li, J.Q., Peng, Z.J., Zhang, G.C., Structural morphologies of Cu–Sn–Bi immiscible alloys with varied compositions. J Alloys Compd 535 (2012), 95–101.
20. Brandes, E.A., Brook, G.B., Smithells, C.J., Smithells metals reference book. 7th ed., 1998, Butterworth-Heinemann, University of Virginia.
21. Wang HP. Thermophysical properties and core-shell solidification microstructure of highly undercooled alloy melts. A Thesis for the Master's Degree of Engineering. Northwestern Polytechnical University, Xi'an, P.R. China, 2004.
22. Powell, R.W., Further measurements of the thermal and electrical conductivity of iron at high temperatures. Proc Phys Soc 51 (1939), 407–418.
23. Jozwiak, W.K., Kaczmarek, E., Maniecki, T.P., Ignaczak, W., Maniukiewicz, W., Reduction behavior of iron oxides in hydrogen and carbon monoxide atmospheres. Appl Catal A: Gen 326 (2007), 17–27.