References
- You, H., Zhang, L., Lin, X., Tang, P., Du, Q., Stress concentration characteristics and coefficient modification for DC04 steel with holes of finite thickness. Frontiers in Materials, 12, Article 1692324, (2025).
- Lavrentev, S. Y., Mokryakov, V. V., Chentsov, A. V., Effective elastic moduli of perforated plates containing a rectangular lattice of circular holes. Mechanics of Solids, 56(3), pp. 296-300, (2021).
- Mengsha, S., Chunyu, Z., Yuheng, C., Wang, W., Experimental and theoretical evaluation of influence of hole size on deformation and fracture of elastic perforated plate. Mechanics of Materials, 187, Article 104841 (2023).
- Tang, H., Wen, T., Zhou, Y., You, J., Ma, D., Study on the wrinkling behavior of perforated metallic plates using uniaxial tensile tests. Thin-Walled Structures, 167, Article 108132, (2021).
- Wang, F., Yan, R., Li, M., Sun, J., Study on Ultimate Tensile Strength of Carbon/Glass Hybrid Composite Perforated Plate. Wuhan Ligong Daxue Xuebao (Jiaotong Kexue Yu Gongcheng Ban)/Journal of Wuhan University of Technology (Transportation Science and Engineering), 48(5), pp. 923-928 (2024).
- Hu, B., Chen, X., Deng, F., Sun, X., Evaluation of failure criteria for residual tensile strength of composite laminates with circular holes. Vibroengineering Procedia, vol. 49, pp. 212-219, (2023).
- Jing, L., Peng, S., Li, X., Li, S., Yan, Y., Jing, W., Uniaxial failure test and simulation of plate with circular hole containing single crack. China Mining Magazine, 31(7), pp. 174-182 (2022).
- Scherer, J. M., Brach, S., Bleyer, J., An assessment of anisotropic phase-field models of brittle fracture. Computer Methods in Applied Mechanics and Engineering, 395, Article 115036 (2022).
- Kinoshita, K., Suzuki, Y., Kumagai, T., Watanabe, O., Matsuda, A., Multiple crack extension and temperature effect of perforated plate in elevated temperature fatigue test. in American Society of Mechanical Engineers, ASME 2013 Pressure Vessels and Piping Conference, vol. 6 A, Article number: PVP2013-97871 (2013).
- Chen, B., Wang, Y., Ye, J., Lim, J. B. P., & Hai, L., Shear resistance of perforated QN1803 high-strength stainless steel plate girders through experimental testing and numerical analysis. Thin-Walled Structures, 196, Article 111505 (2024).
- Saad-Eldeen, S., Garbatov, Y., Experimental and Numerical Analysis of Structural Capacity of Perforated Stiffened Plates. Journal of Marine Science and Engineering, 11(4), Article 842, (2023).
- Huang, B. T., Dai, J. G., Weng, K. F., Zhu, J. X., Shah, S. P., Flexural Performance of UHPC-Concrete-ECC Composite Member Reinforced with Perforated Steel Plates. Journal of Structural Engineering, 147(6), Article 04021065 (2021).
- Granum, H., Aune, V., Borvik, T., Hopperstad, O. S., Aluminium plates with pre-formed slits subjected to blast loading. EPJ Web of Conferences, vol. 183, Article Number 01032, (2018).
- Munemoto, S., Sonoda, Y., An analytical study on the dynamic strength of perforated steel plate shear connectors. 10th International Conference on Shock and Impact Loads on Structures - Singapore, Singapore, pp. 433-440, (2013).
- Leminen, V., Tanninen, P., Pesonen, A., Varis, J., Effect of mechanical perforation on the press-forming process of paperboard. Procedia Manufacturing, vol. 38, pp. 1402-1408, (2019).
- Lecompte, D., Smits, A., Sol, H., Vantomme, J., van Hemelrijck, D., Mixed numerical-experimental technique for orthotropic parameter identification using biaxial tensile tests on cruciform specimens. International Journal of Solids and Structures, 44(5), pp. 1643-1656 (2007).