Fe-based alloy coatings reinforced by Ti( C, N) particles was produced through CO2 laser cladding technology. The microstructure of laser cladding coating was analyzed by means of X-ray diffraction ( XRD ), transm...Fe-based alloy coatings reinforced by Ti( C, N) particles was produced through CO2 laser cladding technology. The microstructure of laser cladding coating was analyzed by means of X-ray diffraction ( XRD ), transmission electron microscopy (TEM) , selected area electron diffraction ( SAED ) , scanning electron microscopy (SEM) and electron probe microscopic analyzer ( EPMA ). The mechanical property of the layer was measured by using microhardness meter. The results show that Ti ( C0. 3 N0. 7 ) panicles are introduced by an in-situ metallurgical reaction between TiN particle and graphite powder during laser cladding process. Titanium carbonitrides particles existed in the layer are fairly fine, ranging from 0. 1 μm to 5.0 μm, and evenly dispersed in the metal α-Fe matrix. Most of them take on nearly rhombus shape, and some of them are irregular in shape. The microhardness of laser cladding layer ranges from 770 HV0. 3 to 850 HV0. 3.展开更多
Fe-based alloy layer reinforced by Ti(C,N) particles was produced on the surface of cast steel. X ray dif fraction (XRD) was used for phase identification in the composite coating. The microstructure of laser clad...Fe-based alloy layer reinforced by Ti(C,N) particles was produced on the surface of cast steel. X ray dif fraction (XRD) was used for phase identification in the composite coating. The microstructure of laser cladding layer was analyzed by means of optical microscope (OM), electron probe microscope analyzer (EPMA), scanning electron microscope (SEM) and transmission electron microscope (TEM). The results show that Ti(C0.3 N0.7 ) particle is in-troduced by an in situ metallurgical reaction of TiN particle and graphite powder in the process of laser cladding. The shape of lots of Ti(C0.3 N0.7) particle is irregular. The sizes of Ti(C0. 3N0. 7) particles range from 0. 1 to 6.0 μm, and they are dispersed evenly in the matrix, which is fine dendritic or cellular crystal. A new kind of phase named Ti(C0.3 N0. 7 ) parti-cles are tightly bonded with α-Fe microstructure, and there is a clean and smooth phase interface between ceramic re-inforcement phase and the matrix.展开更多
文摘Fe-based alloy coatings reinforced by Ti( C, N) particles was produced through CO2 laser cladding technology. The microstructure of laser cladding coating was analyzed by means of X-ray diffraction ( XRD ), transmission electron microscopy (TEM) , selected area electron diffraction ( SAED ) , scanning electron microscopy (SEM) and electron probe microscopic analyzer ( EPMA ). The mechanical property of the layer was measured by using microhardness meter. The results show that Ti ( C0. 3 N0. 7 ) panicles are introduced by an in-situ metallurgical reaction between TiN particle and graphite powder during laser cladding process. Titanium carbonitrides particles existed in the layer are fairly fine, ranging from 0. 1 μm to 5.0 μm, and evenly dispersed in the metal α-Fe matrix. Most of them take on nearly rhombus shape, and some of them are irregular in shape. The microhardness of laser cladding layer ranges from 770 HV0. 3 to 850 HV0. 3.
基金Item Sponsored by Higher Education Fund of Inner Mongolia of China(nyzy11266)
文摘Fe-based alloy layer reinforced by Ti(C,N) particles was produced on the surface of cast steel. X ray dif fraction (XRD) was used for phase identification in the composite coating. The microstructure of laser cladding layer was analyzed by means of optical microscope (OM), electron probe microscope analyzer (EPMA), scanning electron microscope (SEM) and transmission electron microscope (TEM). The results show that Ti(C0.3 N0.7 ) particle is in-troduced by an in situ metallurgical reaction of TiN particle and graphite powder in the process of laser cladding. The shape of lots of Ti(C0.3 N0.7) particle is irregular. The sizes of Ti(C0. 3N0. 7) particles range from 0. 1 to 6.0 μm, and they are dispersed evenly in the matrix, which is fine dendritic or cellular crystal. A new kind of phase named Ti(C0.3 N0. 7 ) parti-cles are tightly bonded with α-Fe microstructure, and there is a clean and smooth phase interface between ceramic re-inforcement phase and the matrix.
