Technology for the production of nanostructured coatings from nanoparticles of tungsten carbide and metal chromium

This paper presents results of a study of complex processes for producing composite powder materials from tungsten carbide and metallic chromium. Technological methods for the formation of functionally gradient coatings with high microhardness up to 426 HV through microplasma spraying technology are disclosed.

plasma chemical synthesis, spray drying method, granulation method using a binder material, microplasma spraying method, microhardness

1. Beloglazov, I.N., Syrkov, A.G., Khimiko-fizicheskie osnovy i metody polucheniya poverkhnostno-strukturirovannykh metallov [Chemical-physical bases and methods for producing surface-structured metals], St Petersburg: SPbGU (Mining University), 2011.

2. Zhabrev, V.A., Kalinnikov, V.T., Margolin, V.I., Nikolaev, A.I., Tupik, V.A., Fiziko-khimicheskie protsessy sinteza nanorazmernykh obektov [Physicochemical processes for the synthesis of nanoscale objects], St Petersburg: Elmor, 2012.

3. Suzdalev, I.P., Nanotekhnologiya: fiziko-khimiya nanoklasterov, nanostruktur i nanomaterialov [Nanotechnology: physical chemistry of nanoclusters, nanostructures and nanomaterials], St Petersburg: LIBROKOM, 2008.

4. Sholkin, S.E., Yurkov, M.A., Sozdanie upravlyaemoy nanostruktury v pokrytii, poluchennom metodami gazotermicheskogo napyleniya [Creating a controlled nanostructure in a coating obtained by thermal spraying], Voprosy Materialovedeniya, 2010, No 2 (62), pp. 68–74.

5. Gang, J., Marnilori, J., Grosdidier, T., Nanostructures in thermal spray coatings, Scripta Materials, 2003, V. 48, pp. 1599–1604.

6. Margolin, V.I., Potapov, A.A., Farmakovsky, B.V., Kuznetsov, P.A., Razvitie nanotekhnologiy na osnove nanokompozitov [The development of nanotechnology based on nanocomposites], St Petersburg: LETI, 2016.

7. Bobkova, T.I., Deev, A.A., Bystrov, R.Yu., Farmakovsky, B.V., Nanesenie iznosostoykikh pokrytiy s reguliruyemoy tverdostyu s pomoshchyu sverkhzvukovogo kholodnogo gazodinamicheskogo napyleniya [Deposition of wear-resistant coatings with adjustable hardness using supersonic cold gas-dynamic spraying], Metalloobrabotka, 2012, No 5–6 (71–72), pp. 45–49.

8. Gerashchenkova, E.Yu., Samodelkin, E.A., Kuznetsov, P.A., Pervukhina, M.S., Yakovleva, N.V., Issledovanie mekhanizma sverkhskorostnoy universalnoy dezintegratorno-aktivatornoy obrabotki dlya polucheniya magnitomyagkikh poroshkovykh materialov na osnove amorfnoy lenty splava sistemy Fe–Cu–Nb–Si–B [Investigation of the mechanism of ultra-high-speed universal disintegrator-activator treatment for obtaining soft magnetic powder materials based on an amorphous alloy strip of the Fe–Cu–Nb– Si–B system], Voprosy Materialovedeniya, 2013, No 1 (73), pp. 102–112.

9. Gorynin, I.V., Oryshchenko, A.S., Farmakovsky, B.V., Kuznetsov, P.A., Perspektivnye issledovaniya i razrabotki nauchnogo nanotekhnologicheskogo tsentra FGUP TSNII KM Prometey v oblasti nanomaterialov [Promising research and development of the scientific nanotechnology center of FSUE Central Research Institute of SM Prometey in the field of nanomaterials], Voprosy Materialovedeniya, 2014, No 2(78), pp. 118–126.

10. Bobkova, T.I., Razrabotka materialov i tekhnologii polucheniya iznosostoykikh gradientnykh pokrytiy na baze nanostrukturirovannykh kompozitsionnykh poroshkov [Development of materials and technology for the production of wear-resistant gradient coatings based on nanostructured composite powders], Abstract of the Cand. Sc. (Eng) Dissertation, St Petersburg, 2017.