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Tytuł artykułu

Protective coatings for aluminium die casting moulds and continuous casting moulds: a review

Wybrane pełne teksty z tego czasopisma
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Warianty tytułu
PL
Powłoki stosowane do ochrony powierzchni krystalizatorów i form do odlewania stopów aluminium
Języki publikacji
EN
Abstrakty
EN
The article presents an overview of currently used coatings for the surface protection of die casting moulds and continuous casting moulds against liquid Al. The analysis of literature data indicates that coatings based on CrN, TiN nitrides, carbonitrides and carbides (TiC), as well as multilayer coatings are most commonly used. Various PVD and CVD processes are used for their production. Coatings produced by thermal spraying processes are also of great importance. The results described in the literature are divergent, which hinders the selection of a protective coating for new applications and determines the performance of experimental studies.
PL
W artykule przedstawiono przegląd obecnie stosowanych powłok do ochrony powierzchni kokili do odlewania ciśnieniowego oraz krystalizatorów do ciągłego odlewania przed oddziaływaniem ciekłego aluminium. Analiza danych literaturowych wskazuje, że najczęściej stosowane są powłoki oparte na azotkach CrN, TiN, węglikoazotkach i węglikach (TiC) oraz wielowarstwowe. Do ich wytwarzania stosuje się różne procesy PVD i CVD. Duże znaczenie mają też powłoki wytwarzane w procesach natryskiwania cieplnego. Wyniki opisane w literaturze są rozbieżne co utrudnia dobór powłoki ochronnej dla nowych zastosowań i determinuje przeprowadzenie badań eksperymentalnych.
Rocznik
Tom
Strony
216--219
Opis fizyczny
Bibliogr. 42 poz.
Twórcy
autor
  • Research and Development Laboratory for Aerospace Materials, Rzeszow University of Technology, Department of Materials Science, Powstancow Warszawy 12, 35-959 Rzeszow, Poland
  • Research and Development Laboratory for Aerospace Materials, Rzeszow University of Technology, Department of Materials Science, Powstancow Warszawy 12, 35-959 Rzeszow, Poland
Bibliografia
  • [1] Yan M., Fan Z. 2011. “Review, Durability of materials in molten aluminum alloys”. Journal of Materials Science 36 : 285-295.
  • [2] Mizuno H., Kitamura J. 2007. “MoB/CoCr Cermet coatings by HVOF Spraying against Erosion by Molten Al-Zn Alloy”. Journal of Thermal Spray Technology 16 (3) : 404-413.
  • [3] Kan F. F., Bae G., Kang K., Na H., Kim J., Jeong T., Lee Ch. 2011. “Evaluation of Die-Soldering and Erosion Resistance of High Velocity Oxy-Fuel Sprayed Mob-Based Cermet Coatings”. Journal of Thermal Spray Technology 20 (5) : 1023-1034.
  • [4] Sanz A. 2001. “Tribological behavior of coatings for continuous casting of steel”. Surface and Coatings Technology 146-147 : 55-64.
  • [5] Salman A., Gabbitas, B.I., Cao P., Zhang D.I. 2011. “The performance of thermally sprayed based composite coatings in molten aluminium”. Surface and Coatings Technology 205 : 5000-5008.
  • [6] Lopez A.J., Rams J. 2015. “Protection of carbon steel against molten aluminum attack and high temperature corrosion using high velocity oxygen- fuel WC-Co coatings”. Surface and Coatings Technology 262 : 123-133.
  • [7] Pang, X., Huang, M., Wang, C., Shi, X., Zhang, W. 2019. “Effect of high temperature diffusion on microstructure and properties of HVOF sprayed NiCrBSi mold coating”. Jinshu Rechuli/Heat Treatment of Metals 44 : 181- 186.
  • [8] Peter I., Rosso M., Gobber F. S. 2015. “Study of protective coatings for aluminium die casting molds”. Applied Surface Science 358 : 563-571.
  • [9] Khan F.F., Bae G., Kang K.,Kumar S., Jeong T., Lee Ch. 2009. “Development of cermet coatings by kinetic spray technology for the application of die-soldering and erosion resistance”. Surface and Coatings Technology 204 : 345-352.
  • [10] Barella S., Gruttadauria A., Mapelli C., Mombelli D. 2014. “Investigation of failure and damages on a continuous casting copper mould”. Engineering Failure Analysis 36 : 432-438.
  • [11] Hsu Ch-H, Huang D-H., Ho W-Y., Huang L-T, Chang Ch-L. 2006. “Characteristics and performance of Cr2O3/CrN double layered coatings deposited by cathodic arc plasma deposition”. Materials Science and Engineering A429 : 212-218.
  • [12] Bobzin K., Brogelmann T., Brugnara R.H., Kruppe N.C. 2015. “CrN/AlN and CrN/AlN/Al2O3 coatings deposited by pulsed cathodic arc for aluminum die casting applications”. Surface and Coatings Technology 284 : 222-229.
  • [13] Ho W-Y., Hsu Ch-H., Huang D-H., Cheng Y-P., Lin Y-Ch, Chang Ch-L. 2004. “Oxygen effect on the mechanical behaviours of Cr(N,O)/CrN double-layered coatings by cathodic arc evaporation” Surface and Coatings Technology 188-189 : 129-134.
  • [14] Ho W.-Y., Huang D-H, Huang L-T., Hsu Ch-H., Wang D-Y. 2004. “Study of characteristics of Cr2O3/CrN duplex coatings for aluminum die casting applications”. Surface and Coatings Technology 177-178 : 172-177.
  • [15] Lousa A., Romero j., Martinez E., Estreve J., Montala F., Carreras L. 2001. “Miltilayered chromium/chromium nitride coatings for use in pressure die-casting”. Surface and Coatings Technology 146-147 : 268-273.
  • [16] Pessoa A., Bergstrom J., Burman Ch., Hogmark S. 2001. “Influence of deposition temperature and time during PVD coating of CrN on corrosive wear in liquid aluminium”. Surface and Coatings Technology, 146-147 : 42-47.
  • [17] Lorusso M., Ugues D., Oliva C., Ghisleni R. 2013. Failure modes of PVD coatings in molten alloy contact. Acta Metallurgica Slovaca 19 : 1, 30-42.
  • [18] Heim D., Holler F., Mitterer C. 1999. “Hard coatings produced by PACVD applied to aluminium die casting”. Surface and Coatings Technology 116- 119 : 530-536.
  • [19] Bobzin K., Brogelmann T., Hartmann U., Kruppe N.C. 2016. “Analysis of CrN/ AlN/Al2O3 and two industrially used coatings deposited on die casting cores after application in an aluminum die casting machine”. Surface and Coatings Technology 308 : 374-382.
  • [20] Lin C.S. Ke C.S., Peng H. 2001. “Corrosion of CrN and CrN/TiN coated heat resistant steels in molten A356 aluminum alloy”. Surface and Coatings Technology 146-147 : 168-174.
  • [21] Terek P., Kovacevic L., Miletic A., Panjan P., Balos S. 2016. “Effects of die core treatments and surface finishes on the sticking and galling of Al-Si alloy casting during ejection”. Wear 356-357 : 122-134.
  • [22] Gulizia S., Jahedi M.Z., Doyle E.D. 2011. “Performance evaluation of PVD coatings for high pressure die casting”. Surface and Coatings Technology 140 : 200-205.
  • [23] Mitterer C., Holler F., Lugmair C., Nobauer R., Kullmer R., Teichert C. 2001. “Optimization of plasma-assisted chemical vapour deposition hard coatings for their application in aluminium die casting”. Surface and Coatings Technology 142-144 : 1005-1011.
  • [24] Mitterer C., Holler F., Reitberger D., Badisch E., Stoiber M., Lugamir C., Nobauer R., Muller Th., Kullmer R. 2003. “Industrial applications of PACVD hard coatings”. Surface and Coatings Technology 163-164 : 716-722.
  • [25] Strivastava A., Joshi V., Shivpuri R., Bhattacharaya R., Dixit S. 2003. “A multilayer coating architecture to reduce heat checking of die surfaces”. Surface and Coatings Technology 163-164 : 631-636.
  • [26] Salas O., Kearns K., Carrera S., Moore J.J. 2003. “Tribological behavior of candidate coatings for Al die casting dies”. Surface and Coatings Technology 172 : 117-127.
  • [27] Klimek K.S., Gebauer-Teichmann A., Kaestner P., Rie K-T. 2007. “Duplex- PACVD coatings of surfaces for die casting tools”. Surface and Coatings Technology 201 : 5628-5632.
  • [28] Tendradini E.K., Kunrath A.O., Aguzzoli C., Castro M., Moore J. J., Baumvol I.J.R. 2008. “Soldering mechanisms in materials and coatings for aluminum die casting”. Surface and Coatings Technology 202 : 3764-3771.
  • [29] Yan H., Zhang J., Zhang P., Yu Z., Li Ch., Xu P., Lu Y. 2013. “Laser cladding of Co-based alloy/TiC/CaF2 self-lubricating composite coatings on copper for continuous casting mold”. Surface and Coatings Technology 232 : 362- 369.
  • [30] Azadi M., Rouhaghdam A.S., Anhagarani S., Mofidi H.H. 2014. “Mechanical behavior of TiN/TiC multilayer coatings fabricated by plasma assisted chemical vapour deposition on AiSi H13 hot work steel”. Surface and Coatings Technology 245 : 156-168
  • [31] Wang Q., Wang W.J., Liu H.J., Zeng Ch.L. 2017. “Corrosion behavior of zirconium diboride coated stainless steel in molten 6061 aluminum alloy”. Surface and Coatings Technology 313 : 129-135.
  • [32] Mitterer C., Holler F., Ustel F., Heim D. 2000. “Application of Hard Coatings in Aluminum Die Casting-Soldering Erosion and Thermal Fatigue Behavior”. Surface and Coatings Technology 125 : 233-239.
  • [33] Kulkarni K., Srivastava A., Shivpuri R., Bhattacharaya R., Dixit S., Bhat D. 2002. “Thermal cracking behavior of multi-layer LAFAD coatings on nitride die steels in liquid aluminum processing”. Surface and Coatings Technology 149 : 171-178.
  • [34] Yi, Y.Y., Luo, Z.M., Ngai, T.L., Ngai, S., Li, L.J. 2017. “Improving the corrosion resistance of hot-working mold steel against al alloy melt by coating”. Materials Science Forum, 877 : 67-72.
  • [35] Schivpuri R., Chu Y-L., Venkatesan K., Conrad J.R., Sridharan K., Shamim M., Fetherston R.P. 1996. “An evaluation of metallic coatings for erosive wear resistance in die casting applications”. Wear 192 : 49-55.
  • [36] Tang N., Li Y., Koizumi Y., Kurosu Sh., Chiba A. 2013. “Interfacial reaction between Co-Cr-Mo alloy and liquid Al”. Corrosion Science 75 : 262-268.
  • [37] Rosso M., Ugues D., Torres E., Ferucca M., Kapranos P. 2008. “Performance enhancements of die casting tools trough PVD nanocoatings”. International Journal of Material Forming : Suppl 1, 1259-1262.
  • [38] Walkowicz J., Smolik J., Mietnik K., Bujak J. 1997. “Duplex surface treatment of mould for pressure casting of aluminium”. Surface and Coatings Technology 97 : 453-464.
  • [39] Wilczek, A., Morgiel, , Rogal, L., Maziarz, W., Smolik. 2020. “Microstructure and wear of (CrN/CrAlN)/(CrAlN/VN) and (CrN/TiAlN)/(TiAlN/VN) coatings for molds used in high pressure casting of aluminium”. Coatings 10 (3) : 261.
  • [40] Jiang, J., Li, R., Yuan, T., Niu, P., Chen, C., Zhou, K. 2019. “Microstructural evolution and wear performance of the high-entropy FeMnCoCr alloy/ TiC/CaF2 self-lubricating composite coatings on copper prepared by laser cladding for continuous casting mold”. Journal of Materials Research 34 (10) : 1714-1725.
  • [41] Salmaliyan, M., Malek Ghaeni, F., Ebrahimnia, M. 2017. “Effect of electro spark deposition process parameters on WC-Co coating on H13 steel”. Surface and Coatings Technology 321 : 81-89.
  • [42] Wang, K., Wang, H., Zhu, G., Zhu, X. 2017. “Cr13Ni5Si2-based composite coating on copper deposited using pulse laser induction cladding”. Materials 10 (2) : 160.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-97fde74e-d252-4c80-82a0-a796bd2f3dca
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