PL EN


Preferencje help
Widoczny [Schowaj] Abstrakt
Liczba wyników
Tytuł artykułu

Mechanical and Thermal Properties of Aluminum Foams Manufactured by Investment Casting Method

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
A method for the open-cell aluminum foams manufacturing by investment casting was presented. Among mechanical properties, compressive behaviour was investigated. The thermal performance of the fabricated foams used as heat transfer enhancers in the heat accumulator based on phase change material (paraffin) was studied during charging-discharging working cycles in terms of temperature distribution. The influence of the foam on the thermal conductivity of the system was examined, revealing a two-fold increase in comparison to the pure PCM. The proposed castings were subjected to cyclic stresses during PCM’s subsequent contraction and expansion, while any casting defects present in the structure may deteriorate their durability. The manufactured heat transfers enhancers were found suitable for up to several dozen of cycles. The applied solution helped to facilitate the heat transfer resulting in more homogeneous temperature distribution and reduction of the charging period’s duration.
Rocznik
Strony
37--42
Opis fizyczny
Bibliogr. 25 poz., fot., rys., tab., wykr.
Twórcy
autor
  • Wrocław University of Science and Technology, Faculty of Mechanical Engineering, Poland
autor
  • Wrocław University of Science and Technology, Faculty of Mechanical Engineering, Poland
autor
  • Wrocław University of Science and Technology, Faculty of Mechanical Engineering, Poland
Bibliografia
  • [1] Bisht, A., Patel, V.K. & Gangil, B. (2019). Future of metal foam materials in automotive industry. In Jitendra K. K., Shantanu B., Vinay K. P. & Vikram K. (Eds.), Automotive Tribology, (pp. 51-63). Springer, Singapore, DOI:10.1007/978-981-15-0434-1_4.
  • [2] Almonti, D., Baiocco, G., Mingione, E. & Ucciardello, N. (2020). Evaluation of the effects of the metal foams geometrical features on thermal and fluid-dynamical behavior in forced convection. The International Journal of Advanced Manufacturing Technology. 111(3), 1157-1172. DOI:10.1007/S00170-020-06092-1.
  • [3] Sivasankaran, S. & Mallawi, F.O.M. (2021). Numerical study on convective flow boiling of nanoliquid inside a pipe filling with aluminum metal foam by two-phase model. Case Studies in Thermal Engineering. 26, 101095. DOI:10.1016/J.CSITE.2021.101095.
  • [4] Anglani, A., Pacella, M. (2021). Binary Gaussian Process classification of quality in the production of aluminum alloys foams with regular open cells. In 14th CIRP Conference on Intelligent Computation in Manufacturing Engineering, 15-17 July 2020 (pp. 307–312). Gulf of Naples, Italy: The International Academy for Production Engineering.
  • [5] Anglani, A., Pacella, M. (2018). Logistic Regression and Response Surface Design for Statistical Modeling of Investment Casting Process in Metal Foam Production. In 11th CIRP Conference on Intelligent Computation in Manufacturing Engineering, 19-21 July 2017 (pp. 504–509). Gulf of Naples, Italy: The International Academy for Production Engineering.
  • [6] Kryca, J., Iwaniszyn, M., Piątek, M., Jodłowski, P.J., Jędrzejczyk, R., Pędrys, R., Wróbel, A., Łojewska, J., Kołodziej, A. (2016). Structured foam reactor with CuSSZ-13 catalyst for SCR of NOx with ammonia. Topics in Catalysis. 59(10), 887-894. DOI:10.1007/S11244-016-0564-4.
  • [7] Alamdari, A. (2015). Performance assessment of packed bed reactor and catalytic membrane reactor for steam reforming of methane through metal foam catalyst support. Journal of Natural Gas Science and Engineering. 27, 934-944. DOI:10.1016/J.JNGSE.2015.09.037.
  • [8] Vilniškis, T., Januševičius, T. & Baltrėnas, P. (2020). Case study: Evaluation of noise reduction in frequencies and sound reduction index of construction with variable noise isolation. Noise Control Engineering Journal. 68(3), 199-208. DOI:10.3397/1/376817.
  • [9] Hua, L., Sun, H. & Gu Jiangsu, J. (2016). Foam metal metamaterial panel for mechanical waves isolation. Conference: SPIE Smart Structures and Materials + Nondestructive Evaluation and Health Monitoring. DOI:10.1117/12.2219470.
  • [10] Wang, Y., Jiang, S., Wu, Z., Shao, H., Wang, K. & Wang, L. (2018). Study on the inhibition influence on gas explosions by metal foam based on its density and coal dust. Journal of Loss Prevention in the Process Industries. 56, 451-457. DOI:10.1016/J.JLP.2018.09.009.
  • [11] Marx, J. & Rabiei, A. (2017). Overview of composite metal foams and their properties and performance. Advanced Engineering Materials. 19(11), 1600776. DOI:10.1002/ADEM.201600776.
  • [12] Tong, X., Shi, Z., Xu, L., Lin, J., Zhang, D., Wang, K., Li, Y., Wen, C. (2020). Degradation behavior, cytotoxicity, hemolysis, and antibacterial properties of electro-deposited Zn–Cu metal foams as potential biodegradable bone implants. Acta Biomaterialia. 102, 481-492. DOI:10.1016/J.ACTBIO.2019.11.031
  • [13] Banhart, J. (2001). Manufacture, characterisation and application of cellular metals and metal foams. Progress in Materials Science. 46, 559-632. DOI:10.1016/S0079- 6425(00)00002-5.
  • [14] Schüler, P., Fischer, S.F., Bührig-Polaczek, A. & Fleck, C. (2013). Deformation and failure behaviour of open cell Al foams under quasistatic and impact loading. Materials Science and Engineering: A, 587, 250-261. DOI:10.1016/J.MSEA.2013.08.030.
  • [15] Schüler, P., Frank, R., Uebel, D., Fischer, S.F., Bührig Polaczek, A. & Fleck, C. (2016). Influence of heat treatments on the microstructure and mechanical behaviour of open cell AlSi7Mg0.3 foams on different lengthscales. Acta Materialia. 109, 32-45. DOI:10.1016/J.ACTAMAT.2016.02.041.
  • [16] Luksch, J., Bleistein, T., Koenig, K., Adrien, J., Maire, E. & Jung, A. (2021). Microstructural damage behaviour of Al foams. Acta Materialia. 208, 116739. DOI:10.1016/J.ACTAMAT.2021.116739.
  • [17] Sathaiah, S., Dubey, R., Pandey, A., Gorhe, N.R., Joshi, T. C., Chilla, V., Muchhala, D., Mondal, D.P. (2021). Effect of spherical and cubical space holders on the microstructural characteristics and its consequences on mechanical and thermal properties of open-cell aluminum foam. Materials Chemistry and Physics. 273, 125115. DOI:10.1016/j.matchemphys.2021.125115
  • [18] Qu, Z. (2018). Heat transfer enhancement technique of pcms and its lattice Boltzmann modeling. In Mohsen Sheikholeslami Kandelousi (Eds.), Thermal Energy Battery with Nano-enhanced PCM. IntechOpen Limited, London, UK. DOI:10.5772/INTECHOPEN. 80574
  • [19] Tian, Y. & Zhao, C.Y. (2011). A numerical investigation of heat transfer in phase change materials (PCMs) embedded in porous metals. Energy. 36, 5539-5546. DOI:10.1016/j.energy.2011.07.019.
  • [20] Novak, N., Vesenjak, M., Duarte, I., Tanaka, S., Hokamoto, K., Krstulović-Opara, L., Guo, B., Chen, P., Ren, Z. (2019). Compressive behaviour of closed-cell aluminium foam at different strain rates. Materials. 12(24), 4108. DOI:10.3390/MA12244108.
  • [21] Naplocha, K., Dmitruk, A., Mayer, P. & Kaczmar, J.W. (2019). Design of honeycomb structures produced by investment casting. Archives of Foundry Engineering. 19(4), 76-80. DOI:10.24425/AFE.2019.129633.
  • [22] Zhou, J. & Soboyejo, W.O. (2004). Compression– compression fatigue of open cell aluminum foams: macro- /micro- mechanisms and the effects of heat treatment. Materials Science and Engineering A. 369(1-2), 23-35. DOI:10.1016/J.MSEA.2003.08.009.
  • [23] Jang, W.Y. & Kyriakides, S. (2009). On the crushing of aluminum open-cell foams: Part I. Experiments. International Journal of Solids and Structures. 46(3-4), 617-634. DOI:10.1016/J.IJSOLSTR.2008.09.008.
  • [24] Krstulović-Opara, L., Vesenjak, M., Duarte, I., Ren, Z. & Domazet, Z. (2016). Infrared thermography as a method for energy absorption evaluation of metal foams. Materials Today: Proceedings. 3(4), 1025-1030. DOI:10.1016/J.MATPR.2016.03.041.
  • [25] Naplocha, K., Koniuszewska, A., Lichota, J. & Kaczmar, J. W. (2016). Enhancement of heat transfer in PCM by vellular Zn-Al structure. Archives of Foundry Engineering. 16(4), 91- 94. DOI:10.1515/AFE-2016-0090.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-60fdeb59-3fd9-49e3-91ec-fcc4510c14c1
JavaScript jest wyłączony w Twojej przeglądarce internetowej. Włącz go, a następnie odśwież stronę, aby móc w pełni z niej korzystać.