Roughness of metal surface after finishing using ceramic brush tools

Salacinski, T.; Chmielewski, T.; Winiarski, M.; Cacko, R.; Świercz, R.

doi:10.1515/adms-2017-0024

Artykuł - szczegóły

Tytuł artykułu

Roughness of metal surface after finishing using ceramic brush tools

Autorzy

Salacinski T. , Chmielewski T. , Winiarski M. , Cacko R. , Świercz R.

Wybrane pełne teksty z tego czasopisma

http://content.sciendo.com/view/journals/adms/adms-overview.xml

Identyfikatory

DOI

10.1515/adms-2017-0024

Warianty tytułu

Języki publikacji

Abstrakty

The paper describes processes of metal parts edges deburring and surface of metal samples polishing with ceramic tools based on fibre aluminium oxide. It presents the construction of basic types of tools and their practical industrial applications, and evaluates the influence of machining parameters on surface roughness. An important advantage of the used tools is the possibility of deburring and machining of external flat and shaped surfaces as well as internal surfaces and even deep drilled holes. These tools can be practically used for machining all construction materials. The results of machining of selected engineering materials, such as aluminium 5052 and 2017A, Inconel 718, non-alloy steel, in various variants of machining parameters are presented. The influence of machining parameters on machined surface roughness was described.

Słowa kluczowe

cutting tools brush ceramic tools deburring

narzędzia tnące szczotkowe narzędzia ceramiczne gratowanie

Wydawca

Politechnika Gdańska

Czasopismo

Advances in Materials Science

Rocznik

2018

Tom

Vol. 18, nr 1(55)

Strony

20--27

Opis fizyczny

Bibliogr. 16 poz., rys., tab.

Twórcy

autor

Salacinski T.

Warsaw University of Technology, Faculty of Production Engineering, Institute of Manufacturing Technologies, 85 Narbutta Str. 02-524 Warsaw, Poland

autor

Chmielewski T.

t.chmielewski@wip.pw.edu.pl

Warsaw University of Technology, Faculty of Production Engineering, Institute of Manufacturing Technologies, 85 Narbutta Str. 02-524 Warsaw, Poland

autor

Winiarski M.

Warsaw University of Technology, Faculty of Production Engineering, Institute of Manufacturing Technologies, 85 Narbutta Str. 02-524 Warsaw, Poland

autor

Cacko R.

Warsaw University of Technology, Faculty of Production Engineering, Institute of Manufacturing Technologies, 85 Narbutta Str. 02-524 Warsaw, Poland

autor

Świercz R.

Warsaw University of Technology, Faculty of Production Engineering, Institute of Manufacturing Technologies, 85 Narbutta Str. 02-524 Warsaw, Poland

Bibliografia

1. Burakowski T., Wierzchoń T., Inżynieria powierzchni metali. WNT, Warsaw, 1995.
2. LOESER company materials.
3. Iwaszko J., Kudła K., Szafarska M., Remelting treatment of the non-conductive oxide coatings by means of the modified GTAW method, Surface and Coatings Technology, 206, (2012), 2845-2850.
4. Górka J., Czupryński A., The properties and structure of arc sprayed coatings alloy of Fe-Cr-Ti-Si-Mn, International Journal of Modern Manufacturing Technologies, 8 (2016), 35-40.
5. Czupryński A., Selected properties of the thermally sprayed oxide ceramic coatings, Advances in Materials Science, 15 (3) (2015), 17-32.
6. Pan S., Wang N., Xiong D., Deng Y., Shi Y., Fabrication of superhydrophobic coating via spraying method and its applications in anti-icing and anti-corrosion, Applied Surface Science, 389 (2016), 547-553.
7. Czupryński A., Górka J., Adamiak M., Tomiczek B., Testing of flame sprayed Al2O3 matrix coatings containing TiO2, Archives of Metallurgy and Materials, 61 (3) (2016), 1363-1370.
8. Bartmański M., Berk A., Wójcik A., The determinants of morphology and properties of the nanohydroxyapatite coating deposited on the Ti13Zr13Nb alloy by electrophoretic technique, Advances in Materials Science, 16 (3) (2016), 56-66.
9. Świercz R., Oniszczuk-Świercz D., Experimental investigation of surface layer properties of high thermal conductivity tool steel after electrical discharge machining, Metals, 7 (2017), 550.
10. Samardžiová M., Neslušan M., Roughness improvement in hard turning when changing cutting parameters and using differently shaped ceramic tools, Applied Mechanics and Materials, 474 (2014), 345-350.
11. Swiatkowski K., Cacko R., Investigation of new wax-based model materials simulating metal working process, Journal of Materials Processing Technology, 72 (1997), 267-271.
12. Makarov V.F., Vinogradov A.V., Nurtdinov A.V., Automated polishing of sharp edges on gas-turbine components by abrasive polymer brushes, Russian Engineering Research, 32 (2012), 102-107.
13. Bańkowski D., Spadło S., Influence of the Smoothing Conditions in Vibro-Abrasive for Technically Dry Friction the Parts Made of Steel X160CRMOV121, Proceedings of 25th International Conference on Metallurgy and Materials, METAL 2016, 1019-1024.
14. Chmielewski T., Golański D., Włosiński W., Zimmerman J., Utilizing the energy of kinetic friction for the metallization of ceramics, Bulletin of the Polish Academy of Sciences - Technical Sciences, 63 (1) (2015), 201-207.
15. Dou W., Nitzan A., Subotnik J.E., Frictional effects near a metal surface, The Journal of Chemical Physics, 143 (2015) 054103.
16. Chmielewski T., Golański D., Włosiński W., Metallization of ceramic materials based on the kinetic energy of detonation waves Bulletin of the Polish Academy of Sciences - Technical Sciences, 63 (2) (2015), 449-456.

Uwagi

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-85f7e2c9-04f0-470e-bf60-bccbf11bdf14