As one of the three major elements of the materials genome, high-throughput technologies for materials aim to change the traditional sequential iterative methods in material research into parallel or efficient serial experiments through high-throughput preparation and characterization, thereby accelerating the efficient screening and optimization of materials. Functional inorganic glass materials are a typical class of amorphous materials that have attracted attention in high-tech fields due to their special and excellent properties. The composition of inorganic glass materials often consists of multiple components. The optimization of traditional inorganic glass material is usually based on "one furnace, one crucible" preparation mode, which has the drawbacks of lengthy trial cycles and low efficiency. Therefore, it has great theoretical and practical significance to introduce high-throughput preparation methods and concepts into the development and optimization of new glass materials. This article summarizes the high-throughput and efficient preparation technologies that may be suitable for inorganic glass materials in existing technologies and analyzes the feasibility and directions for improvement of each technology in the application of inorganic glass materials, so as to provide certain references for the future high-throughput preparation of inorganic glass materials.