[1] |
GONG X, WANG J, FENG H. Lateral powder transport model with Gaussian distribution in laser cladding[J]. The International Journal of Advanced Manufacturing Technology, 2019, 102: 3747-3756.
|
[2] |
LU Y, HUANG G, WANG Y, et al. Crack-free Fe-based amorphous coating synthesized by laser cladding[J]. Materials Letters, 2018, 210: 46-50.
|
[3] |
CHAKRABORTY S S, DUTTA S. Estimation of dilution in laser cladding based on energy balance approach using regression analysis[J]. Sādhanā, 2019, 44: 150.
|
[4] |
ZHANG Z, KOVACEVIC R. Laser cladding of iron-based erosion resistant metal matrix composites[J]. Journal of Manufacturing Processes, 2019, 38: 63-75.
|
[5] |
BAX B, RAJPUT R, KELLET R, et al. Systematic evaluation of process parameter maps for laser cladding and directed energy deposition[J]. Additive Manufacturing, 2018, 21: 487-494.
|
[6] |
FERNANDEZ E, CADENAS M, GONZALEZ R, et al. Wear behaviour of laser clad NiCrBSi coating[J]. Wear, 2005, 259: 870-875.
|
[7] |
RIO G D, GARRIDO M A, FERNANDEZ J E, et al. Influence of the deposition techniques on the mechanical properties and microstructure of NiCrBSi coatings[J]. Journal of Materials Processing Technology, 2008, 204: 304-312.
|
[8] |
ZHAI L L, BAN C Y, ZHANG J W. Microstructure, microhardness and corrosion resistance of NiCrBSi coatings under electromagnetic field auxiliary laser cladding[J]. Surface and Coatings Technology, 2019, 358: 531-538.
|
[9] |
WANG X H, ZHANG M, LIU X M, et al. Microstructure and wear properties of TiC/FeCrBSi surface composite coating prepared by laser cladding[J]. Surface and Coatings Technology, 2008, 202(15): 3600-3606.
|
[10] |
BAI H, ZHONG L, SHANG Z, et al. Microstructure and mechanical properties of TiC-Fe surface gradient coating on a pure titanium substrate prepared in situ[J]. Journal of Alloys and Compounds, 2019, 771: 406-417.
|
[11] |
GU D, ZHANG H, DAI D, et al. Laser additive manufacturing of nano-TiC reinforced Ni-based nanocomposites with tailored microstructure and performance[J]. Composites Part B: Engineering, 2019, 163: 585-597.
|
[12] |
SHEN M Y, TIAN X J, LIU D, et al. Microstructure and fracture behavior of TiC particles reinforced Inconel 625 composites prepared by laser additive manufacturing[J]. Journal of Alloys and Compounds, 2018, 734: 188-195.
|
[13] |
BAKKAR A, AHMED M M Z, ALALEH N A, et al. Microstructure, wear, and corrosion characterization of high TiC content Inconel 625 matrix composites[J]. Journal of Materials Research and Technology, 2019, 8(1): 1102-1110.
|
[14] |
MAKAROV A V, SOBOLEVA N N, MALYGINA I Y, et al. The tribological performances of a NiCrBSi-TiC laser-clad composite coating under abrasion and sliding friction[J]. Diagnostics, Resource and Mechanics of Materials and Structures, 2015(3): 83-97.
|
[15] |
WEN P, FENG Z, ZHENG S. Formation quality optimization of laser hot wire cladding for repairing martensite precipitation hardening stainless steel[J]. Optics & Laser Technology, 2015, 65: 180-188.
|
[16] |
RAGAVENDRAN M, CHANDRASEKHAR N, RAVIKUMAR R, et al. Optimization of hybrid laser-TIG welding of 316LN steel using response surface methodology (RSM)[J]. Optics and Lasers in Engineering, 2017, 94: 27-36.
|
[17] |
SAFEEN W, HUSSAIN S, WASIM A, et al. Predicting the tensile strength, impact toughness, and hardness of friction stir-welded AA6061-T6 using response surface methodology[J]. The International Journal of Advanced Manufacturing Technology, 2016, 87: 1765-1781.
|
[18] |
ALTARAZI S, HIJAZI L, KAISER E. Process parameters optimization for multiple-inputs-multiple-outputs pulsed green laser welding via response surface methodology[C]// 2016 IEEE International Conference on Industrial Engineering and Engineering Management (IEEM).Piscataway: IEEE, 2016: 1041-1045.
|
[19] |
CUI C, GUO Z, WANG H, et al. In situ TiC particles reinforced grey cast iron composite fabricated by laser cladding of Ni-Ti-C system[J]. Journal of Materials Processing Technology, 2007, 183: 380-385.
|
[20] |
EMAMIAN A, CORBIN S F, KHAJEPOUR A. Effect of laser cladding process parameters on clad quality and in-situ formed microstructure of Fe-TiC composite coatings[J]. Surface and Coatings Technology, 2010, 205(7): 2007-2015.
|
[21] |
LEI Y, SUN R, TANG Y, et al. Numerical simulation of temperature distribution and TiC growth kinetics for high power laser clad TiC/NiCrBSiC composite coatings[J]. Optics & Laser Technology, 2012, 44(4): 1141-1147.
|
[22] |
MUVVALA G, KARMAKAR D P, NATH A K. Online assessment of TiC decomposition in laser cladding of metal matrix composite coating[J]. Materials & Design, 2017, 121: 310-320.
|
[23] |
PRZYBYLOWICZ J, KUSINSKI J. Structure of laser cladded tungsten carbide composite coatings[J]. Journal of Materials Processing Technology, 2001, 109: 154-160.)
|
[1] |
GONG X, WANG J, FENG H. Lateral powder transport model with Gaussian distribution in laser cladding[J]. The International Journal of Advanced Manufacturing Technology, 2019, 102: 3747-3756.
|
[2] |
LU Y, HUANG G, WANG Y, et al. Crack-free Fe-based amorphous coating synthesized by laser cladding[J]. Materials Letters, 2018, 210: 46-50.
|
[3] |
CHAKRABORTY S S, DUTTA S. Estimation of dilution in laser cladding based on energy balance approach using regression analysis[J]. Sādhanā, 2019, 44: 150.
|
[4] |
ZHANG Z, KOVACEVIC R. Laser cladding of iron-based erosion resistant metal matrix composites[J]. Journal of Manufacturing Processes, 2019, 38: 63-75.
|
[5] |
BAX B, RAJPUT R, KELLET R, et al. Systematic evaluation of process parameter maps for laser cladding and directed energy deposition[J]. Additive Manufacturing, 2018, 21: 487-494.
|
[6] |
FERNANDEZ E, CADENAS M, GONZALEZ R, et al. Wear behaviour of laser clad NiCrBSi coating[J]. Wear, 2005, 259: 870-875.
|
[7] |
RIO G D, GARRIDO M A, FERNANDEZ J E, et al. Influence of the deposition techniques on the mechanical properties and microstructure of NiCrBSi coatings[J]. Journal of Materials Processing Technology, 2008, 204: 304-312.
|
[8] |
ZHAI L L, BAN C Y, ZHANG J W. Microstructure, microhardness and corrosion resistance of NiCrBSi coatings under electromagnetic field auxiliary laser cladding[J]. Surface and Coatings Technology, 2019, 358: 531-538.
|
[9] |
WANG X H, ZHANG M, LIU X M, et al. Microstructure and wear properties of TiC/FeCrBSi surface composite coating prepared by laser cladding[J]. Surface and Coatings Technology, 2008, 202(15): 3600-3606.
|
[10] |
BAI H, ZHONG L, SHANG Z, et al. Microstructure and mechanical properties of TiC-Fe surface gradient coating on a pure titanium substrate prepared in situ[J]. Journal of Alloys and Compounds, 2019, 771: 406-417.
|
[11] |
GU D, ZHANG H, DAI D, et al. Laser additive manufacturing of nano-TiC reinforced Ni-based nanocomposites with tailored microstructure and performance[J]. Composites Part B: Engineering, 2019, 163: 585-597.
|
[12] |
SHEN M Y, TIAN X J, LIU D, et al. Microstructure and fracture behavior of TiC particles reinforced Inconel 625 composites prepared by laser additive manufacturing[J]. Journal of Alloys and Compounds, 2018, 734: 188-195.
|
[13] |
BAKKAR A, AHMED M M Z, ALALEH N A, et al. Microstructure, wear, and corrosion characterization of high TiC content Inconel 625 matrix composites[J]. Journal of Materials Research and Technology, 2019, 8(1): 1102-1110.
|
[14] |
MAKAROV A V, SOBOLEVA N N, MALYGINA I Y, et al. The tribological performances of a NiCrBSi-TiC laser-clad composite coating under abrasion and sliding friction[J]. Diagnostics, Resource and Mechanics of Materials and Structures, 2015(3): 83-97.
|
[15] |
WEN P, FENG Z, ZHENG S. Formation quality optimization of laser hot wire cladding for repairing martensite precipitation hardening stainless steel[J]. Optics & Laser Technology, 2015, 65: 180-188.
|
[16] |
RAGAVENDRAN M, CHANDRASEKHAR N, RAVIKUMAR R, et al. Optimization of hybrid laser-TIG welding of 316LN steel using response surface methodology (RSM)[J]. Optics and Lasers in Engineering, 2017, 94: 27-36.
|
[17] |
SAFEEN W, HUSSAIN S, WASIM A, et al. Predicting the tensile strength, impact toughness, and hardness of friction stir-welded AA6061-T6 using response surface methodology[J]. The International Journal of Advanced Manufacturing Technology, 2016, 87: 1765-1781.
|
[18] |
ALTARAZI S, HIJAZI L, KAISER E. Process parameters optimization for multiple-inputs-multiple-outputs pulsed green laser welding via response surface methodology[C]// 2016 IEEE International Conference on Industrial Engineering and Engineering Management (IEEM).Piscataway: IEEE, 2016: 1041-1045.
|
[19] |
CUI C, GUO Z, WANG H, et al. In situ TiC particles reinforced grey cast iron composite fabricated by laser cladding of Ni-Ti-C system[J]. Journal of Materials Processing Technology, 2007, 183: 380-385.
|
[20] |
EMAMIAN A, CORBIN S F, KHAJEPOUR A. Effect of laser cladding process parameters on clad quality and in-situ formed microstructure of Fe-TiC composite coatings[J]. Surface and Coatings Technology, 2010, 205(7): 2007-2015.
|
[21] |
LEI Y, SUN R, TANG Y, et al. Numerical simulation of temperature distribution and TiC growth kinetics for high power laser clad TiC/NiCrBSiC composite coatings[J]. Optics & Laser Technology, 2012, 44(4): 1141-1147.
|
[22] |
MUVVALA G, KARMAKAR D P, NATH A K. Online assessment of TiC decomposition in laser cladding of metal matrix composite coating[J]. Materials & Design, 2017, 121: 310-320.
|
[23] |
PRZYBYLOWICZ J, KUSINSKI J. Structure of laser cladded tungsten carbide composite coatings[J]. Journal of Materials Processing Technology, 2001, 109: 154-160.)
|