ArticleName |
Improvement of zinc castings surface quality by laminated protective coating |
ArticleAuthorData |
Kazan National Research Technical University named after A. N. Tupolev — KAI, Kazan, Russia:
R. V. Gavariev, Senior Lecturer of a Chair “Design and Manufacturing Provision of Mechanical Engineering Productions”, e-mail: Gavarievr@mail.ru I. A. Savin, Assistant Professor, Head of a Chair “Design and Manufacturing Provision of Mechanical Engineering Productions”
Nizhny Novgorod State Technical University, Nizhny Novgorod, Russia:
I. O. Leushin, Professor, Head of a Chair “Metallurgical Technologies and Equipment” |
Abstract |
Nowadays, the special ways of casting take the leading place in the global production of mold precision casting. There are many special ways of casting all over the world but injection moulding is the most urgent and has many advantages including: largest production capacity; high quality of castings with complex configuration of outer surface and highest material ratio (to 99.5%). However in special cases, the castings producers have to meet the low quality indicators of the surface of the produced castings, which makes this method economically inefficient. The used method of improvement of castings quality is usually connected with expensive complex-alloyed steels with various ways of chemical and thermal treatment of mold details (nitriding is the less expensive one). This used method is widely applied for injection moulding of aluminium and copper alloys, but requires the alternative in case of usage of zinc alloys with much lower fusion temperatures. This paper solves the urgent problem of insufficient quality of zinc castings surface, obtained by injection moulding and laminated protective coatings on forming surfaces of molds by cathode-ion bombardment. We give the results of experimental investigations which are the basis of comparison of various types of coating alloys, looking at roughness of the surface of obtained coatings. We also give the equation for the forecasting of roughness of obtained castings depending on coating parameters. |
References |
1. Gavariev R. V., Savin I. A., Leushin I. O. Impact of the functional coating on service durability of injection molds for the zinc alloys pressure casting. Tsvetnye Metally. 2016. No. 1. pp. 66–70. DOI: 10.17580/tsm.2016.01.11 2. Goryunov I. I. Molds for injection moulding. Leningrad : Mashinostroenie, 1973. 256 p. 3. Pankratov D. L., Gavariev R. V., Gavarieva K. N. Influence of multilayer coatings on the operational stability of molds for injection molding. IOP Conference Series: Materials Science and Engineering. 2016. Vol. 134, No. 1. DOI: 10.1088/1757-899X/134/1/012031 4. Shaparev A., Savin I. Calculation of the amount of the reduction required for the formation of compound layers during cold rolling of bimetals. Materials Science Forum. 2016. Vol. 870. pp. 328–333. DOI: 10.4028/www.scientific.net/MSF.870.328 5. State Standard GOST 25140–93. Zinc alloys for casting. Grades. Introduced: 1995–01–01. 6. Shin S.-S., Lim K.-M., Park I.-M. Characteristics and microstructure of newly designed Al – Zn-based alloys for the die-casting process. Journal of Alloys and Compounds. 2016. Vol. 671. pp. 517–526. 7. Rollez D., Pola A., Prenger F. Zinc alloy family for foundry purposes. World of Metallurgy – ERZMETALL. 2015. Vol. 68 (6). pp. 354–358. 8. Yan S., Xie J., Liu Z., Wang W., Wang A., Li J. Influence of different Al contents on microstructure, tensile and wear properties of Zn-based alloy. Journal of Materials Science and Technology. 2010. Vol. 26 (7). pp. 648–652. DOI: 10.1016/S1005-0302(10)60100-4 9. Çuvalci H., Çelik H. S. Investigation of the abrasive wear behaviour of ZA-27 alloy and CuSn10 bronze. Journal of Materials Science. 2011. Vol. 46 (14). pp. 4850–4857. DOI: 10.1007/s10853-011-5396-9 10. Kapranos P., Brabazon D., Midson S. P., Naher S., Haga T. Advanced casting methodologies: inert environment vacuum casting and solidification, die casting, compocasting, and roll casting, casting, semi-solid forming and hot metal forming. Comprehensive Materials Processing. 2014. Vol. 5. pp. 3–37. 11. Hekimolu A. P., Savakan T. Effects of contact pressure and sliding speed on the unlubricated friction and wear properties of Zn – 15Al – 3Cu – 1Si alloy. Tribology Transactions. 2016. Vol. 59 (6). pp. 1114–1121. DOI: 0.1080/10402004.2016.1141443 12. Yang L. J. The effect of casting temperature on the properties of squeeze cast aluminium and zinc alloys. Journal of Materials Processing Technology. 2003. Vol. 140. pp. 391–396. DOI: 10.1016/S0924-0136(03)00763-5 13. Jayal A. D., Badurdeen F., Dillon Jr. O. W., Jawahir I. S. Sustainable manufacturing: Modeling and optimization challenges at the product, process and system levels. CIRP Journal of Manufacturing Science and Technology. 2010. Vol. 2 (3). pp. 144–152. DOI: 10.1016/j.cirpj.2010.03.006 14. Dornfeld D. A. Moving towards green and sustainable manufacturing. International Journal of Precision Engineering and Manufacturing — Green Technology. 2014. Vol. 1 (1). pp. 63–66. DOI: 10.1007/s40684-014-0010-7 15. Dawal S. Z. M., Tahriri F., Jen Y. H., Case K., Tho N. H., Zuhdi A., Mousavi M., Amindoust A., Sakundarini N. Empirical evidence of AMT practices and sustainable environmental initiatives in malaysian automotive SMEs. International Journal of Precision Engineering and Manufacturing. 2015. Vol. 16 (6). pp. 1195–1203. DOI: 10.1007/s12541-015-0154-6 16. Pankratov D. L., Kashapova L. R. Methodology development for the sustainability process assessment of sheet metal forming of complexshaped products. Materials Science and Engineering. 2015. Vol. 86, No. 1. 012003. |