Optimization design of the in-place-machining tool beam for FRPs bonded repair

Inward-bonded Patch technology is a common method for repairing defects and damage of (Fiber Reinforce Plastics) FRP parts. In the project, there is an urgent need for an in-situ machining machine with a concave step structure in the method. Such thin-walled, weakly rigid parts are easily deformed under pressure. Therefore, the machine beam is lightly designed to reduce the influence of compression deformation on the machining quality. In this paper, the annular (basalt fiber polymer composite) BFPC beam of a certain type of in-situ machining machine prototype is taken as the research object. Firstly, based on the analysis of the prototype working conditions, the comprehensive performance index of the beam is clarified. Using the topology optimization technology, the beam topology of the optimal topology is obtained. Finally, the establishment is established. The multi-objective optimization function with regular structural parameters as variables and minimum beam quality and deformation as the target has obtained the optimal topology and optimal performance of the beam structure.