Determining the Thickness Coating of Grinding Powders of Synthetic Diamond Based on a Specific-Surface Approach and using an Extrapolation-Affine 3D Model of Grain

Grigrii A. Petasyuk

doi:10.6000/2369-3355.2022.09.03

Authors

Grigrii A. Petasyuk V. Bakul Institute for Superhard Materials, National Academy of Sciences of Ukraine, 2 Avtozavodskaya Str., Kiev, 04074 Ukraine

DOI:

https://doi.org/10.6000/2369-3355.2022.09.03

Keywords:

Synthetic diamond powders, coating, thickness, indirect method, 3D model

Abstract

: Methodological features of indirect determining of thickness coating of grains grinding powders of synthetic diamond are analyzed. A newly revised classification of known methods for determining the thickness of the coating is proposed. The prospects of the methods based on the application of an external specific surface are noted. A positive feature is the proposal to determine the thickness of the coating separately for each grain of the sample, followed by the generalization of the results by calculating the arithmetic mean. This calculation scheme allows you to get more reliable information about the thickness of the coating. The expediency of using an extrapolation-affine 3D grain model in such a calculation scheme is substantiated. Using the extrapolation-affininе 3D grain model allows for determining the thickness of the coating of diamond powder grains without the traditional assumption about the spherical shape of their grains and with less error. For an example of grinding powder AC125 400/315, the advantage of such a 3D model compared to a 3D model in the form of a sphere is proved. The method proposed on the basis of such methodical innovation can be used for powders of other abrasive materials.

References

Lavrinenko VI. Superhard materials (Nadtverdi materialy), Kyiv: Akademperiodyka; 2018 (in Ukrainian).

Sedov VS, Khomich AA, Ralchenko VG, et al. Growth of Si-doped Polycrystalline Diamond Films on AlN Substrates by Microwave Plasma Chemical Vapor Deposition. Journal of Coating Science and Technology 2015; 2 (2) 38-45. https://doi.org/10.6000/2369-3355.2015.02.02.1

Sun Y, He L, Zhang C, et al. Enhanced tensile strength and thermal conductivity in copper diamond composites with B4C coating. Scientific Reports 2017; 7: art. 10727. 1-10. https://doi.org/10.1038/s41598-017-11142-y

Sun Y, Zhang C, He L, et al. Enhanced bending strength and thermal conductivity in diamond/Al composites with B4C coating. Scientific Reports 2018; 8: Art. 11104. 1-12. https://doi.org/10.1038/s41598-018-29510-7

Radkevych OI, Chumalo HV, Yurkevych RM. Corrosion-mechanical behavior of the protective coatings of check valves of the oil-and-gas field equipment, Materials Science 2009; 45(6): 893-898. https://doi.org/10.1007/s11003-010-9255-7

George P, George A, Labrini S, et al. Protection of Aluminum Foils against Environmental Corrosion with Graphene-Based Coatings. Journal of Coating Science and Technology 2021; 8: 18-28. https://doi.org/10.6000/2369-3355.2021.08.02

Hsu C-H, Liu H-T, Huang W-C, et al. Effect of Post Heated TiN Coating on Pitting Corrosion of Austenitic Stainless Steel. Journal of Coating Science and Technology 2015; 2: 93-99. https://doi.org/10.6000/2369-3355.2015.02.03.4

Paustovs’kyi ОV, Novikova VІ, Tymofeeva ІІ, et al. Electric-spark alloying of VT22 alloy by chromium and tungsten electrode materials. Materials Science 2011; 47(1): 120123. https://doi.org/10.1007/s11003-011-9377-6

Mallik AK, Roy S, Balla VK, et al. Characteristics of CVD Grown Diamond Films on Langasite Substrates. Journal of Coating Science and Technology 2019; 6: 41-51. https://doi.org/10.6000/2369-3355.2019.06.02.2

Sknar Yu, Amirulloeva NV, Sknar IV, et al. influence of methylsulfonate anions on the structure of electrolytic cobalt coatings. Materials Science 2016; 52(3): 396-401. https://doi.org/10.1007/s11003-016-9970-9

Kumar S, Sharma S. Sliding Wear Study of Flame Sprayed Co-Base Powder Coatings. Journal of Coating Science and Technology 2014; 1: 130-136. https://doi.org/10.6000/2369-3355.2014.01.02.5

Novikov MV, Mechnyk VA, Bondarenko MO, et al. Composite materials of diamond (Co–Cu–Sn) system with improved mechanical characteristics. Part 1. The influence of hot re_pressing on the

structure and properties of diamond–(Co–Cu–Sn) composite. J Superhard Mater 2015; 37(6): 402-417. https://doi.org/10.3103/S1063457615060052

Posuvailo V, Ivasenko I, Veselivska H, et al. Influence of plasma electrolyte coating thickness on the corrosion resistance of D16T alloy. Problems of Corrosion and Corrosion Protection of Materials. Special Issue of Journal "Physicochemical Mechanics of Materials" (Spetsvypusk zhurnalu "Fizyko-khimichna mekhanika materialiv"). 2018; No 12. Lviv: Karpenko Physico-Mechanical Institute (Lviv: KarpenkoPhysico-MechanicalInstitute) 139-143 (in Ukrainian).

Baturin VE, Klebanov YuD, Sumarokov VN. Measurement of the thickness of metal coatings on the grains of diamond and cubic boron nitride. Synthetic Diamonds (Sinteticheskie Almazy) 1973; 3: 13-16 (in Russian).

Galitsky VN, Murovsky VA, Emelyanov BM, et al. The influence of metallized diamonds on the performance of the tool on a metal bundle. Synthetic Diamonds (Sinteticheskie Almazy). 1971; 3: 24-26 (in Russian).

Petasyuk GA. Methodological and Application Aspects of Indirect Analytical Determination of Coating Thickness on Metal-Coated Superabrasive Grits. Journal of Superhard Materials 2019; 41(3): 201-209. https://doi.org/10.3103/S1063457619030080

Petasyuk GA. Indirect determination of the thickness of the coating of synthetic diamond powders using new 3D models of their grain. Physicochemical mechanics of materials (Fizyko-khimichna mekhanika materialiv). 2021; 57(6): 133-136 (in Ukrainian).

Perfetti G, Van de Casteele E, Rieger B, et al. X-ray microtomography and image analysis as complementary methods for morphological characterization and coating thickness measurement of coated particles. Advanced Powder Technology 2010; 21: 663-675. https://doi.org/10.1016/j.apt.2010.08.002

Abyzov AM, Kidalov SV, Shakhov FM. Composite material diamond-copper with high thermal conductivity. Materials Science (Materialovedeniye) 2008; 5: 24-27 (in Russian).

Dewettinck K, Deroo L, Messens W, et al. Agglomeration tendency during top-spray fluidized bed coating with gums. Lebensm.-Wiss. u.-Technol 1998; 31: 576-584. https://doi.org/10.1006/fstl.1998.0421

Chistyakov EM, Kukharenko SA. Determining of the thickness of the nickel coating of diamond grains. Superhard Materials (Sverkhtverdyye Materialy) 1983; 3: 48-50.

Gregg SJ, Sing KSW. Adsorption, Surface Area and Porosity, 2nd ed., London, Academic Press; 1982.

Nikitin YuI, Petasyuk GA. Specific Surface Area Determination Methods, Devices, and Results for Diamond Powders. Journal of Superhard Materials 2008; 30(1): 58-70.

Petasyuk GA, Bogatyreva GP. Extrapolation_Analytical Method for Determination of Outer Specific Surface of Powders of Superhard Materials. Journal of Superhard Materials 2007; 30(6): 375-383. https://doi.org/10.3103/S1063457607060081

DiaInspect.OSM. Automated particle analysis for superabrasives and surface analysis 2010. Operation guide Version 1.2.8 Retrieved from https://vdiamant.de/ languages/diainspect-osm.html

Bakul VN. The number of grains in one carat is one of the most important characteristics of diamond powder. Synthetic Diamonds (Sinteticheskie Almazy) 1976; 4: 22-27.

Lavrinenko VI, Shepelev AA, Petasyuk GA. Models of shape of superabrasive grits. Journal of Superhard Materials 1994; 16(5): 13-16.

Michon GP. Surface Area of an Ellipsoid - Scalene Ellipsoid – Numericana. Available from: http://www.numericana.com/answer/ ellipsoid.htm

Petasyuk GA, Bochechka OO, Lavrinenko VI, et al. The Additive Pycnometric Method for Assessment of the Degree of Coating of Grinding Powders Made of Superhard Materials Using the Extrapolation-Affine 3D-Model of the grain. Journal of Superhard Materials 2020; 42(3): 199-202. https://doi.org/10.3103/S1063457620030077

Petasyuk GA, Sirota YuV. Analytical determination of a number of particles per carat for diamond powders on the basis of an extrapolation-affine 3D grain model. Journal of Superhard Materials 2012; 34(3): 200-208. https://doi.org/10.3103/S1063457612030082