Abstract
With the continuous improvement of material performance requirements in the field of mechanical engineering, the design and manufacturing process optimization of high-performance materials has become an important link to achieve product quality and function improvement. This paper discusses how to improve the performance of high-performance materials in flexible structures through advanced material design methods and manufacturing process optimization. Optimized design of materials based on computer-aided design (CAD), the way to predict and improve material properties through simulation software. Combined with the application of advanced manufacturing technologies, how 3D printing, laser cutting and other technologies can improve the mechanical properties of flexible materials through process parameter optimization. , such as surface self-cleaning, antimicrobial properties, anti-icing, corrosion protection, and fluid drag reduction. With the development of new materials and the emergence of innovative processing technologies, superhydrophobic surface preparation methods have become more efficient and diverse. It is foreseeable that flexible materials with woven superhydrophobic properties will have greater applications in biomedicine, biomimetic sensors, flexible solar cells and other fields. The combination of the performance of material properties in practical applications and optimization effects with real-world applications, especially the potential innovative applications in flexible structures, is demonstrated through specific cases of test validation.
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