Fatoba, OSPopoola, APIFedetova, TPityana, Sisa L2017-04-102017-04-102016-03Fatoba, O.S., Popoola, A.P.I., Fedetova, T. and Pityana, S.L. 2016. Improved corrosion and wear resistance of laser alloyed Zn-Sn-Ti composite coatings on UNS G10150 steel in 0.5 M H2SO4 solution. In: 2nd International Conference on Smart Materials & Structures, 29 February-2 March 2016, Philadelphia, Pennsylvania, USAhttp://hdl.handle.net/10204/89982nd International Conference on Smart Materials & Structures, 29 February-2 March 2016, Philadelphia, Pennsylvania, USASurface deterioration by corrosion is one of the complications associated with ageing facilities and components especially under some service environments. The research work examines the corrosion behavior of laser alloyed UNS-G10150 steel; coatings have been obtained by laser surface alloying technique. Ternary combinations of Zn-Sn-Ti metallic powders were mixed and injected onto the surface of UNSG10150 mild steel substrate under different laser processing parameters. The steel alloyed samples were cut to corrosion coupons, immersed in sulfuric acid (0.5M H(SUB2)SO(SUB4)) solution at 300 C using electrochemical technique and investigated for its corrosion behavior. The morphologies and microstructures of the developed coatings and uncoated samples were characterized by Optic Nikon Optical microscope (OPM) and scanning electron microscope (SEM/EDS). Moreover, X-ray diffractometer (XRD) was used to identify the phases present. The improved properties were attributed to the formation of new corrosion phases ((Zn(OH)(SUB2), ZnO, ZnSn(OH)(SUB6), Ecandrewsite, syn(ZnTiO(SUB3)), Anatase, syn(TiO2), Romarchite, syn(SnO), Zinc Tin Oxide (Zn(SUB2)SnO(SUB4)), Chinese white(ZnO), and fine eutectic microstructures. An improvement of 6.9-times the hardness of the steel substrate was achieved at high scanning speed which may be attributed to the fine microstructure, dislocations and the high degree of saturation of solid solution brought by the high scanning speed. The polarization resistance Rp (5388300 O.cm(SUP2)) was 337,803-times the polarization of the UNSG10150 substrate and significant reduction in the corrosion rate was also achieved. In addendum, Response Surface Model [RSM] and Artificial Neural Network Model [ANN] were used for the optimization and modeling of the laser parameters since processing parameters played an important role in the quality of alloyed coating produced. Corresponding experimental results show a good qualitative conformity with the numerical model predictions.enSmart materialsSmart structuresSurface corrosionLaser surface alloying techniqueConference PresentationFatoba, O., Popoola, A., Fedetova, T., & Pityana, S. L. (2016). Improved corrosion and wear resistance of laser alloyed Zn-Sn-Ti composite coatings on UNS G10150 steel in 0.5 M H2SO4 solution. http://hdl.handle.net/10204/8998Fatoba, OS, API Popoola, T Fedetova, and Sisa L Pityana. "Improved corrosion and wear resistance of laser alloyed Zn-Sn-Ti composite coatings on UNS G10150 steel in 0.5 M H2SO4 solution." (2016): http://hdl.handle.net/10204/8998Fatoba O, Popoola A, Fedetova T, Pityana SL, Improved corrosion and wear resistance of laser alloyed Zn-Sn-Ti composite coatings on UNS G10150 steel in 0.5 M H2SO4 solution; 2016. http://hdl.handle.net/10204/8998 .TY - Conference Presentation AU - Fatoba, OS AU - Popoola, API AU - Fedetova, T AU - Pityana, Sisa L AB - Surface deterioration by corrosion is one of the complications associated with ageing facilities and components especially under some service environments. The research work examines the corrosion behavior of laser alloyed UNS-G10150 steel; coatings have been obtained by laser surface alloying technique. Ternary combinations of Zn-Sn-Ti metallic powders were mixed and injected onto the surface of UNSG10150 mild steel substrate under different laser processing parameters. The steel alloyed samples were cut to corrosion coupons, immersed in sulfuric acid (0.5M H(SUB2)SO(SUB4)) solution at 300 C using electrochemical technique and investigated for its corrosion behavior. The morphologies and microstructures of the developed coatings and uncoated samples were characterized by Optic Nikon Optical microscope (OPM) and scanning electron microscope (SEM/EDS). Moreover, X-ray diffractometer (XRD) was used to identify the phases present. The improved properties were attributed to the formation of new corrosion phases ((Zn(OH)(SUB2), ZnO, ZnSn(OH)(SUB6), Ecandrewsite, syn(ZnTiO(SUB3)), Anatase, syn(TiO2), Romarchite, syn(SnO), Zinc Tin Oxide (Zn(SUB2)SnO(SUB4)), Chinese white(ZnO), and fine eutectic microstructures. An improvement of 6.9-times the hardness of the steel substrate was achieved at high scanning speed which may be attributed to the fine microstructure, dislocations and the high degree of saturation of solid solution brought by the high scanning speed. The polarization resistance Rp (5388300 O.cm(SUP2)) was 337,803-times the polarization of the UNSG10150 substrate and significant reduction in the corrosion rate was also achieved. In addendum, Response Surface Model [RSM] and Artificial Neural Network Model [ANN] were used for the optimization and modeling of the laser parameters since processing parameters played an important role in the quality of alloyed coating produced. Corresponding experimental results show a good qualitative conformity with the numerical model predictions. DA - 2016-03 DB - ResearchSpace DP - CSIR KW - Smart materials KW - Smart structures KW - Surface corrosion KW - Laser surface alloying technique LK - https://researchspace.csir.co.za PY - 2016 T1 - Improved corrosion and wear resistance of laser alloyed Zn-Sn-Ti composite coatings on UNS G10150 steel in 0.5 M H2SO4 solution TI - Improved corrosion and wear resistance of laser alloyed Zn-Sn-Ti composite coatings on UNS G10150 steel in 0.5 M H2SO4 solution UR - http://hdl.handle.net/10204/8998 ER -