Damage Quantitative Detection of Curved Composite Laminates Based on Improved Particle Swarm Optimization Algorithm

• Published in: Materials Vol. 18; no. 10; p. 2317
• Main Authors: Tian, Shuxia, Wang, Shunqiang, Chen, Zhenmao, Hao, Ran, Qin, Zhihui, Ma, Jiangdong, Xu, Linfeng
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 16.05.2025; MDPI
• Subjects: Accuracy; Algorithms; Analysis; Composite materials; Convergence; Damage detection; Error detection; Fiber composites; Finite element analysis; Flexibility; Laminated materials; Laminates; Mathematical analysis; Mathematical optimization; Methods; Modulus of elasticity; Numerical models; Optimization algorithms; Optimization techniques; Particle swarm optimization; Structural vibration; Swarm intelligence; Vibration analysis; Vibration mode; swarm intelligence optimization; damage quantification; curved fiber-reinforced composites; finite difference method; structural damage assessment
• ISSN: 1996-1944; 1996-1944
• DOI: 10.3390/ma18102317

In order to solve the problem of damage identification of composite laminates during processing and service, a quantitative damage detection method based on swarm intelligence optimization was proposed for structural damage detection of curved composite laminates. Firstly, the structural damage element was defined by the method of reducing the elastic modulus of the element, and the modal parameters of the numerical model of the laminate under different damage conditions were obtained by analyzing the structural vibration characteristics. Secondly, the objective function was constructed from the vibration data, and the precise location and degree of damage were quantitatively calculated by the swarm intelligence optimization algorithm. In order to prevent the particles from falling into the local optimal, the boundary rebound strategy was used to process the boundary, and the MS operator was introduced to greatly accelerate the convergence speed of the algorithm. The numerical results indicate that without the influence of noise, the algorithm was not affected by the quantity, location or size of the damage and could effectively detect damage in curved fiber-reinforced composites, with the detection error rates being within 0.5%. After adding 1% and 5% noise to the frequency and vibration mode, respectively, the convergence speed of the algorithm slowed down, and the convergence times obviously increased. However, it could still accurately locate the damage, and the calculation error of the damage degree was less than 6%. Finally, the effectiveness of the proposed algorithm was verified through experimental tests.