Abstract : To improve the wear resistance of the surface of the cotton picker spindle, a Ni-Co-ZrO 2 composite coating with different ZrO 2 nanoparticle concentrations was prepared using electrodeposition technology on the micro surface of spindle hook teeth, and the morphologies of the surface and cross-section, element contents, grain sizes, microhardness and friction coefficients of the Ni-Co-ZrO 2 composite coating were obtained; a simulated wear test was conducted based on the independently developed spindle hook tooth wear device, and the morphologies and elemental distributions of the composite coating before and after wear were obtained; the effects of different ZrO 2 nanoparticle concentrations (0, 2, 4, 6, 8 g/L) on the morphology, element content, grain size, microhardness, friction coefficient and wear resistance of the coating were discussed. The test results indicated that compared with Ni-Co coatings, Ni-Co-ZrO 2 composite coatings featured a more compact coating structure, a greater coating thickness, and a smaller grain size. The presence of ZrO 2 nanoparticles led to further improvement of the coating’s microhardness, friction coefficient and wear resistance. When the mass concentration of ZrO 2 nanoparticles reached 4 g/L, the microhardness of Ni-Co-ZrO 2 composite coating reached the maximum value, 545.4 Hv 0.1, and the friction coefficient decreased to 0.06. At the same time, in the simulated wear test, the composite coating with this concentration had the smallest wear area and the highest wear resistance. Keywords: ZrO2 nanoparticles; micro surface of spindle hook teeth; electrodeposition; Ni-Co-ZrO2 composite coatings; wear resistance Abstract : To improve the wear resistance of the surface of the cotton picker spindle, a Ni-Co-ZrO 2 composite coating with different ZrO 2 nanoparticle concentrations was prepared using electrodeposition technology on the micro surface of spindle hook teeth, and the morphologies of the surface and cross-section, element contents, grain sizes, microhardness and friction coefficients of the Ni-Co-ZrO 2 composite coating were obtained; a simulated wear test was conducted based on the independently developed spindle hook tooth wear device, and the morphologies and elemental distributions of the composite coating before and after wear were obtained; the effects of different ZrO 2 nanoparticle concentrations (0, 2, 4, 6, 8 g/L) on the morphology, element content, grain size, microhardness, friction coefficient and wear resistance of the coating were discussed. The test results indicated that compared with Ni-Co coatings, Ni-Co-ZrO 2 composite coatings featured a more compact coating structure, a greater coating thickness, and a smaller grain size. The presence of ZrO 2 nanoparticles led to further improvement of the coating’s microhardness, friction coefficient and wear resistance. When the mass concentration of ZrO 2 nanoparticles reached 4 g/L, the microhardness of Ni-Co-ZrO 2 composite coating reached the maximum value, 545.4 Hv 0.1, and the friction coefficient decreased to 0.06. At the same time, in the simulated wear test, the composite coating with this concentration had the smallest wear area and the highest wear resistance. Keywords: ZrO2 nanoparticles; micro surface of spindle hook teeth; electrodeposition; Ni-Co-ZrO2 composite coatings; wear resistance Abstract : To improve the wear resistance of the surface of the cotton picker spindle, a Ni-Co-ZrO 2 composite coating with different ZrO 2 nanoparticle concentrations was prepared using electrodeposition technology on the micro surface of spindle hook teeth, and the morphologies of the surface and cross-section, element contents, grain sizes, microhardness and friction coefficients of the Ni-Co-ZrO 2 composite coating were obtained; a simulated wear test was conducted based on the independently developed spindle hook tooth wear device, and the morphologies and elemental distributions of the composite coating before and after wear were obtained; the effects of different ZrO 2 nanoparticle concentrations (0, 2, 4, 6, 8 g/L) on the morphology, element content, grain size, microhardness, friction coefficient and wear resistance of the coating were discussed. The test results indicated that compared with Ni-Co coatings, Ni-Co-ZrO 2 composite coatings featured a more compact coating structure, a greater coating thickness, and a smaller grain size. The presence of ZrO 2 nanoparticles led to further improvement of the coating’s microhardness, friction coefficient and wear resistance. When the mass concentration of ZrO 2 nanoparticles reached 4 g/L, the microhardness of Ni-Co-ZrO 2 composite coating reached the maximum value, 545.4 Hv 0.1, and the friction coefficient decreased to 0.06. At the same time, in the simulated wear test, the composite coating with this concentration had the smallest wear area and the highest wear resistance. Keywords: ZrO2 nanoparticles; micro surface of spindle hook teeth; electrodeposition; Ni-Co-ZrO2 composite coatings; wear resistance To improve the wear resistance of the surface of the cotton picker spindle, a Ni-Co-ZrO 2 composite coating with different ZrO 2 nanoparticle concentrations was prepared using electrodeposition technology on the micro surface of spindle hook teeth, and the morphologies of the surface and cross-section, element contents, grain sizes, microhardness and friction coefficients of the Ni-Co-ZrO 2 composite coating were obtained; a simulated wear test was conducted based on the independently developed spindle hook tooth wear device, and the morphologies and elemental distributions of the composite coating before and after wear were obtained; the effects of different ZrO 2 nanoparticle concentrations (0, 2, 4, 6, 8 g/L) on the morphology, element content, grain size, microhardness, friction coefficient and wear resistance of the coating were discussed. The test results indicated that compared with Ni-Co coatings, Ni-Co-ZrO 2 composite coatings featured a more compact coating structure, a greater coating thickness, and a smaller grain size. The presence of ZrO 2 nanoparticles led to further improvement of the coating’s microhardness, friction coefficient and wear resistance. When the mass concentration of ZrO 2 nanoparticles reached 4 g/L, the microhardness of Ni-Co-ZrO 2 composite coating reached the maximum value, 545.4 Hv 0.1, and the friction coefficient decreased to 0.06. At the same time, in the simulated wear test, the composite coating with this concentration had the smallest wear area and the highest wear resistance. Keywords: ZrO2 nanoparticles; micro surface of spindle hook teeth; electrodeposition; Ni-Co-ZrO2 composite coatings; wear resistance Keywords: ZrO2 nanoparticles; micro surface of spindle hook teeth; electrodeposition; Ni-Co-ZrO2 composite coatings; wear resistance Keywords: