EVALUATION OF THE INFLUENCE OF THE LASER ALLOYING WITH Cr, B AND Ni OF GREY IRON PARTS ON THEIR WEAR RESISTANCE

Marta Paczkowska

Politechnika Poznańska


Abstrakt

The aim of this research was to evaluate the influence of the laser alloying with Cr, Cr+B+Ni and B+Ni on the wear resistance of grey iron. Agricultural component (coulter flap) exposed on friction wear (as well as corrosion) in the soil has been take into account as a tested machine part. Even 85% decrease of mass loss of the coulter flap with laser alloyed layer (with nickel and boron) after wear test in comparison to mass loss of flap without laser treatment was achieved. In case of alloying with chromium it was 44% and in case of nickel, boron and chromium this decrease was 58%. Laser alloying in each perormed variant caused formation of the modified surface layer consisting of fine grains of mainly martensite enriched with alloy elements, increase of hardness of the surface layer and reduction of roughness parameters of the treated surface in comparison to the base surface.


Słowa kluczowe:

laser alloying, wear resistance, grey iron


BURAKOWSKI T., WIERZCHOŃ T. 1995. Inżynieria powierzchni metali. Wydawnictwo Naukowo-Techniczne, Warszawa.   Google Scholar

CATALÁN N., RAMOS-MOORE E., BOCCARDO A., CELENTANO D. 2022. Surface Laser Treatment of Cast Irons: A Review. Metals, 12(4): 562. https://doi.org/10.3390/met12040562   Google Scholar

COSTA A.R. DA, VILAR R. 1997. Erosion by Solid Particle Impingement: Experimental Results with Cast-Iron, Laser-Treated Surface. Tribology Letters, 3(4): 379–385.   Google Scholar

FELDSHTEIN E., DEVOJNO O., PATALAS-MALISZEWSKA J., KARDAPOLAVA M., KASIAKOVA I. 2023. Effect of Processing Parameters on the Formation of Alloyed Surface Layer and Its Properties on the Efficiency of Laser Alloying of Grey Cast Iron with Tungsten and Silicon Carbides. Materials, 16(18): 6230.   Google Scholar

FELDSHTEIN E., DEVOJNO O., WOJCIECHOWSKI S., KARDAPOLAVA M., KASIAKOVA I. 2022. On the Microstructure, Microhardnessand Wear Behavior of Gray Cast Iron Surface Layer After Laser Strengthening. Materials, 15: 1-12.   Google Scholar

JANICKI D. 2020. Effect of Chromium and Molybdenum Addition on the Microstructure of in Situ Tic-Reinforced Composite Surface Layers Fabricated on Ductile Cast Iron by Laser Alloying. Materials, 13: 1-17.   Google Scholar

JANICKI D., CZUPRYŃSKI A., GÓRKA J., MATUS K. 2024. Effect of Cooling Rate on Microstructure of in Situ Tic-Reinforced Composite Surface Layers Synthesized on Ductile Cast Iron by Laser Alloying. Materials, 17(4): 932.   Google Scholar

KOTARSKA A. 2021. The Laser Alloying Process of Ductile Cast Iron Surface with Titanium. Metals, 11(2): 282. https://doi.org/10.3390/met11020282   Google Scholar

KUSIŃSKI J. 2000. Lasery i ich zastosowanie w inżynierii materiałowej. Akapit, Kraków.   Google Scholar

LONT A., GÓRKA J., JANICKI D., MATUS K. 2022. The Laser Alloying Process of Ductile Cast Iron Surface with Titanium Powder in Nitrogen Atmosphere. Coatings, 12(2): 227. https://doi.org/10.3390/coatings12020227   Google Scholar

MINLIN Z., WENJIN L., HONGJUN Z. 2006. Corrosion and Wear Resistance Characteristics of Nicr Coating by Laser Alloying with Powder Feeding on Grey Iron Liner. Wear, 260(11-12): 1349-1355.   Google Scholar

NAPIÓRKOWSKI J., LEMECHA M., KONAT Ł. 2019. Forecasting the Wear of Operating Parts in an Abrasive Soil Mass using the Holm-Archard Model. Materials, 12: 2180.   Google Scholar

PACZKOWSKA M. 2008. Możliwości modyfikacji struktury i własności warstwy powierzchniowej elementów maszyn przez borowanie laserowe. Inżynieria Materiałowa, 29(6): 585-590.   Google Scholar

PACZKOWSKA M. 2013. The Possibility of Selected Surface Layer Modification of Nodular Iron Engine Parts by Laser Boronizing. Vehicle Engineering (VE), Science and Engineering Publishing Company, 1(3): 64.   Google Scholar

PACZKOWSKA M. 2016a. The Evaluation of the Influence of Laser Treatment Parameters on the Type of Thermal Effects in the Surface Layer Microstructure of Gray Irons. Optics and Laser Technology, 76: 143-148.   Google Scholar

PACZKOWSKA M. 2016b. The Importance of Operating Conditions and Parameters on Laser Alloying with Silicon During Surface Layer Modification of Nodular Iron. Lasers in Engineering, 33(4-6): 305-326.   Google Scholar

PACZKOWSKA M., RATUSZEK W., WALIGÓRA W. 2010. Microstructure of Laser Boronized Nodular Iron. Surface & Coatings Technology, 205: 2542-2545.   Google Scholar

PACZKOWSKA M., SELECH J. 2022. Microstructure and Soil Wear Resistance of Grey Cast Iron with Ni and Cr. Materials, 15(9): 3153-1-3153-14.   Google Scholar

PACZKOWSKA M., WOJCIECHOWSKI Ł. 2007. Adhesive Wear Tests of Nodular Iron Parts after Laser Boronizing. Tribologia, 3-4: 71-83.   Google Scholar

WEI L. DENG L. 1998. Laser Alloying on Chromium Coated Surface of Nodular Cast Iron. Transactions of Nonferrous Metals Society of China, 8(3): 496-499.   Google Scholar

XIN T., HONG Z., LUQUAN R., ZHIHUI Z., REN-DONG C., WEI Z. 2008. Thermal Fatigue Characteristics of Grey Cast Iron with Non-Smooth Surface Treated by Laser Alloying of Cr Powder. Surface and Coatings Technology, 202(12): 2527-2534.   Google Scholar


Opublikowane
13-06-2024

Cited By /
Share

Paczkowska, M. (2024). EVALUATION OF THE INFLUENCE OF THE LASER ALLOYING WITH Cr, B AND Ni OF GREY IRON PARTS ON THEIR WEAR RESISTANCE. Technical Sciences, 27(27), 127–141. https://doi.org/10.31648/ts.10064

Marta Paczkowska 
Politechnika Poznańska



Licencja

Creative Commons License

Utwór dostępny jest na licencji Creative Commons Uznanie autorstwa 4.0 Międzynarodowe.





-->