Why is this Plastic Bracket not easy to bend or break?

In terms of material selection, this Plastic Bracket uses high-quality engineering plastics, such as ABS (acrylonitrile-butadiene-styrene copolymer), PC (polycarbonate) or PBT (polybutylene terephthalate) plus glass fiber and other high-strength materials. These materials themselves have excellent physical properties, such as high strength, high toughness, good heat resistance and weather resistance.
ABS material has excellent processing performance and surface gloss, and has certain impact resistance and wear resistance. PC material has extremely high impact strength and toughness, and has good transparency and thermal stability. PBT plus glass fiber material combines the advantages of PBT's heat resistance, weather resistance and good electrical properties. By adding glass fiber, its strength and rigidity are enhanced, making the bracket more stable when subjected to external forces. These materials can also be specially treated as needed during the manufacturing process, such as adding reinforcing fibers, fillers, etc., to further improve their strength and hardness.
In terms of structural design, this Plastic Bracket fully considers its stress conditions and use environment. Through reasonable structural layout and size design, the bracket can evenly distribute stress when subjected to external force, avoiding bending or breaking caused by stress concentration. Reinforcement ribs are set at key parts of the bracket, such as hooks and joints. These reinforcement ribs not only improve the strength and rigidity of the bracket, but also increase its stability. By optimizing the design of the support structure, the bracket can better disperse stress when subjected to external force, thereby avoiding bending or breaking caused by excessive local stress.
In terms of manufacturing process, this Plastic Bracket adopts injection molding technology. Injection molding technology is an efficient and precise manufacturing method that can ensure the dimensional accuracy and shape stability of the bracket. During the injection molding process, the internal structure and performance of the bracket can be optimized by controlling parameters such as injection temperature, pressure and time. For example, appropriate injection temperature can ensure sufficient melting and uniform distribution of the material; appropriate injection pressure can ensure tight filling of the material and accurate replication of the mold; appropriate injection time can ensure sufficient cooling and solidification of the material. After injection molding, the bracket also needs to undergo a series of post-processing processes, such as annealing, tempering, etc. These post-processing processes can eliminate stress inside the bracket and improve the uniformity and stability of the material, thereby further improving its strength and durability.