Vat photopolymerization has advnatages of smooth fabricated product surface, high precision, and fast manufacture. Vat photopolymerization can be used to fabricate free-form 3D microstructures. Vat photopolymerization can be divided into "top-down" system and "bottom-up" system according to the position of the light source. The "top-down" is more suitable for the manufacture of microstructures because it does not need to consider the force of detachment movement at every layer. However, the "top-down" system relies on the rheological properties of the photosensitive resin to coat the platform. When printing microstructures, the thickness of each layer is micron size, so the resin cannot coat the platform, resulting in defects at the bottom of the model. If carbon nanotubes are added to the photosensitive resin to print nanocomposite materials, the viscosity of the resin will increase, making it impossible to use the "top-down" system to manufacture models. This study developed a recoating mechanism to improve the shortcomings of the "top-down" system, and tested parameters such as exposure time, resin formulation, and layer thickness. The octet-truss lattice microstructure and nanocomposite microstructure were successfully fabricated by this system. The finite element method was used to analyze the stress distribution and failure position of the octet-truss lattice microstructure. Finally, the thesis studied on the technical limitations of the recoating mechanism and the possible ways in which the microstructure was damaged when the recoating mechanism was operating.