Structural Health Monitoring of Thin Shell Structures

Ihtisham Khalid; Zahid Ahmed Qureshi; Faisal Siddiqui; Selda Oterkus; Erkan Oterkus

doi:10.1002/msd2.12141

International Journal of Mechanical System Dynamics ›› 2025, Vol. 5 ›› Issue (1) : 20 -39. DOI: 10.1002/msd2.12141

RESEARCH ARTICLE

Structural Health Monitoring of Thin Shell Structures

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Abstract

Thin plate and shell structures are extensively used in aerospace, naval, and energy sectors due to their lightweight and efficient load-bearing properties. Structural Health Monitoring (SHM) implementations are becoming increasingly important in these industries to reduce maintenance costs, improve reliability, and ensure safe operations. This study presents an efficient triangular inverse shell element for thin shell structures, developed using discrete Kirchhoff assumptions within the inverse finite element method (iFEM) framework. The proposed inverse formulation is efficient and requires fewer strain sensors to achieve accurate and reliable displacement field reconstruction than existing inverse elements based on the First Order Shear Deformation Theory (FSDT). These features are critical to iFEM-based SHM strategies for improving real-time efficiency while reducing project costs. The inverse element is rigorously validated using benchmark problems under in-plane, out-of-plane, and general loading conditions. Also, its performance is compared to an existing competitive inverse shell element based on FSDT. The inverse formulation is further evaluated for robust shape-sensing capability, considering a real-world structural configuration under a practicable sparse sensor arrangement. Additional investigation includes defect characterization and structural health assessment using damage index criteria. This research contributes toward developing more reliable and cost-effective monitoring solutions by highlighting the potential application of the proposed inverse element for SHM frameworks designed for thin shell structures.

Keywords

defect / iFEM / inverse shell element / shape sensing / structural health monitoring / thin plate and shell

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Ihtisham Khalid, Zahid Ahmed Qureshi, Faisal Siddiqui, Selda Oterkus, Erkan Oterkus. Structural Health Monitoring of Thin Shell Structures. International Journal of Mechanical System Dynamics, 2025, 5(1): 20-39 DOI:10.1002/msd2.12141

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	S. Hassani and U. Dackermann, “A Systematic Review of Advanced Sensor Technologies for Non-Destructive Testing and Structural Health Monitoring,” Sensors 23, no. 4 (2023): 2204.

[2]	H. Guo, X. Zhuang, and T. Rabczuk, “A Deep Collocation Method for the Bending Analysis of Kirchhoff Plate,” Computers, Materials & Continua 59, no. 2 (2019): 433–456.

[3]	E. Samaniego, C. Anitescu, S. Goswami, et al., “An Energy Approach to the Solution of Partial Differential Equations in Computational Mechanics via Machine Learning: Concepts, Implementation and Applications,” Computer Methods in Applied Mechanics and Engineering 362 (2020): 112790.

[4]	X. Zhuang, H. Guo, N. Alajlan, H. Zhu, and T. Rabczuk, “Deep Autoencoder Based Energy Method for the Bending, Vibration, and Buckling Analysis of Kirchhoff Plates With Transfer Learning,” European Journal of Mechanics - A/Solids 87 (2021): 104225.

[5]	C. Wang, Q. Xiao, Z. Zhou, et al., “A Data-Assisted Physics-Informed Neural Network (DA-PINN) for Fretting Fatigue Lifetime Prediction,” International Journal of Mechanical System Dynamics 4 (2024): 361–373.

[6]	W. L. Ko, W. L. Richards, and V. T. Tran, Displacement Theories for In-Flight Deformed Shape Predictions of Aerospace Structures (NASA, 2007).

[7]	W. L. Ko, W. L. Richards, and V. T. Fleischer, Applications of Ko Displacement Theory to the Deformed Shape Predictions of the Doubly-Tapered Ikhana Wing (NASA, 2009).

[8]	G. Foss and E. Haugse, “ Using Modal Test Results to Develop Strain to Displacement Transformations.” in Proceedings of the 13th International Modal Analysis Conference, Vol. 2460 (NASA, 1995), 112.

[9]	M. Gopinathan, G. A. Pajunen, P. S. Neelakanta, and M. Arockaisamy, “Recursive Estimation of Displacement and Velocity in a Cantilever Beam Using a Measured Set of Distributed Strain Data,” Journal of Intelligent Material Systems and Structures 6, no. 4 (1995): 537–549.

[10]	A. C. Pisoni, C. Santolini, D. E. Hauf, and S. Dubowsky, “ Displacements in a Vibrating Body by Strain Gage Measurements,” in Proceedings—SPIE the International Society for Optical Engineering (Citeseer, 1995), 119.

[11]	S. Shkarayev, An Inverse Interpolation Method Utilizing In-flight Strain Measurements for Determining Loads and Structural Response of Aerospace Vehicles (NASA, 2001). 3rd int. Workshop on Structural Health Monitoring.

[12]	J. S. Alexander Tessler A Variational Principle for Reconstruction of Elastic Deformations in Shear Deformable Plates and Shells (Report Number: NASA/TM-2003-2 12445), (NASA, 2003).

[13]	M. Gherlone, P. Cerracchio, and M. Mattone, “Shape Sensing Methods: Review and Experimental Comparison on a Wing-Shaped Plate,” Progress in Aerospace Sciences 99 (2018): 14–26.

[14]	A. Tessler and J. L. Spangler, Inverse Fem for Full-field Reconstruction of Elastic Deformations in Shear Deformable Plates and Shells. 2nd European Workshop on Structural Health Monitoring (NASA, 2004).

[15]	A. Kefal, E. Oterkus, A. Tessler, and J. L. Spangler, “A Quadrilateral Inverse-Shell Element With Drilling Degrees of Freedom for Shape Sensing and Structural Health Monitoring,” Engineering Science and Technology, an International Journal 19, no. 3 (2016): 1299–1313.

[16]	A. Kefal, “An Efficient Curved Inverse-Shell Element for Shape Sensing and Structural Health Monitoring of Cylindrical Marine Structures,” Ocean Engineering 188 (2019): 106262.

[17]	I. Khalid, Z. A. Qureshi, H. A. Khan, S. Oterkus, and E. Oterkus, “A Quadrilateral Inverse Plate Element for Real-Time Shape-Sensing and Structural Health Monitoring of Thin Plate Structures,” Computers & structures 305 (2024): 107551.

[18]	A. Kefal and E. Oterkus, “Isogeometric iFEM Analysis of Thin Shell Structures,” Sensors 20, no. 9 (2020): 2685.

[19]	Y. Dirik, S. Oterkus, and E. Oterkus, “Isogeometric Mindlin-Reissner Inverse-Shell Element Formulation for Complex Stiffened Shell Structures,” Ocean Engineering 305 (2024): 118028.

[20]	C. De Mooij, M. Martinez, and R. Benedictus, “iFEM Benchmark Problems for Solid Elements,” Smart Materials and Structures 28, no. 6 (2019): 065003.

[21]	A. Kefal, A. Tessler, and E. Oterkus, “An Enhanced Inverse Finite Element Method for Displacement and Stress Monitoring of Multilayered Composite and Sandwich Structures,” Composite Structures 179 (2017): 514–540.

[22]	I. Khalid, Z. A. Qureshi, H. Q. Ali, S. Oterkus, and E. Oterkus, “Structural Health Monitoring of Pre-Cracked Structures Using an Inplane Inverse Crack Tip Element,” International Journal of Mechanical System Dynamics 4 (2024): 406–426.

[23]	O. Eugenio, Structural Analysis With the Finite Element Method: Linear Statics, 1st ed. (Springer, 2009).

[24]	J. L. Batoz, K. J. Bathe, and L. W. Ho, “A Study of Three-Node Triangular Plate Bending Elements,” International Journal for Numerical Methods in Engineering 15, no. 12 (1980): 1771–1812.

[25]	D. J. Allman, “A Compatible Triangular Element Including Vertex Rotations for Plane Elasticity Analysis,” Computers & Structures 19, no. 1–2 (1984): 1–8.

[26]	M. A. Abdollahzadeh, H. Q. Ali, M. Yildiz, and A. Kefal, “Experimental and Numerical Investigation on Large Deformation Reconstruction of Thin Laminated Composite Structures Using Inverse Finite Element Method,” Thin-Walled Structures 178 (2022): 109485.

[27]	E. J. Miller, R. Manalo, and A. Tessler, Full-Field Reconstruction of Structural Deformations and Loads From Measured Strain Data on a Wing Using the Inverse Finite Element Method (NASA, 2016).

[28]	D. J. Allman, “A Quadrilateral Finite Element Including Vertex Rotations for Plane Elasticity Analysis,” International Journal for Numerical Methods in Engineering 26, no. 3 (1988): 717–730.

[29]	A. Ibrahimbegovic, R. L. Taylor, and E. L. Wilson, “A Robust Quadrilateral Membrane Finite Element With Drilling Degrees of Freedom,” International Journal for Numerical Methods in Engineering 30, no. 3 (1990): 445–457.

[30]	S. Timoshenko and J. Goodier, Theory of Elasticity, Vol. 1 (New York: Inc., 1951), 35–39.

[31]	T. Belytschko, H. Stolarski, W. K. Liu, N. Carpenter, and J. S. J. Ong, “Stress Projection for Membrane and Shear Locking in Shell Finite Elements,” Computer Methods in Applied Mechanics and Engineering 51, no. 1–3 (1985): 221–258.

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2025 The Author(s). International Journal of Mechanical System Dynamics published by John Wiley & Sons Australia, Ltd on behalf of Nanjing University of Science and Technology.