Experimental Shape Sensing and Load Identification on a Stiffened Panel: A Comparative Study

Abstract: The monitoring of loads and displacements during service life is proving to be crucial for developing a modern Structural Health Monitoring framework. The continuous monitoring of these physical quantities can provide fundamental information on the actual health status of the structure and can accurately guide pro-active condition-based maintenance operations, thus reducing the maintenance costs and extending the service life of the monitored structures. Pushed by these needs and by the simultaneous developmen… Show more

“…For each sensorized element, only strain sensors located at the centroid of the element are considered, according to the scheme adopted in Ref. [32]. Fiber-optic sensors are also used in this case, as shown by the blue dotted lines of the sensor configuration in Figure 11.…”

“…This inverse element repository has been successfully applied for various numerical and experimental shape-sensing studies featuring metallic and composite structures. The structures investigated include wing-shaped geometries [6,28,29], stiffened panels [30][31][32], wing boxes [33], and marine structures [34,35]. Moreover, the application of iFEM has been extended to geometrically non-linear problems in [36,37].…”

Hybrid Shell-Beam Inverse Finite Element Method for the Shape Sensing of Stiffened Thin-Walled Structures: Formulation and Experimental Validation on a Composite Wing-Shaped Panel

“…For each sensorized element, only strain sensors located at the centroid of the element are considered, according to the scheme adopted in Ref. [32]. Fiber-optic sensors are also used in this case, as shown by the blue dotted lines of the sensor configuration in Figure 11.…”

“…This inverse element repository has been successfully applied for various numerical and experimental shape-sensing studies featuring metallic and composite structures. The structures investigated include wing-shaped geometries [6,28,29], stiffened panels [30][31][32], wing boxes [33], and marine structures [34,35]. Moreover, the application of iFEM has been extended to geometrically non-linear problems in [36,37].…”

Hybrid Shell-Beam Inverse Finite Element Method for the Shape Sensing of Stiffened Thin-Walled Structures: Formulation and Experimental Validation on a Composite Wing-Shaped Panel

“…where k f and c f are the stiffness and damping coefficients of the foundation, and q is the lateral distributed load. Upon substitution of Equations ( 5)- (7) into Equation (4), and performing necessary integration by parts on the time variable, the Hamilton's principle can be written as: Where K, U, and V are the kinetic energy, strain energy, and the work conducted by the external loads, respectively. The variation in these quantities for the plate of Figure 1 is defined as:…”

“…where f k and f c are the stiffness and damping coefficients of the foundation, and q is the lateral distributed load. Upon substitution of Equations ( 5)- (7) into Equation (4), and performing necessary integration by parts on the time variable, the Hamilton's principle can be written as:…”

“…Analysis of beams and plates resting on an elastic or viscoelastic foundation has many important applications in mechanical and aerospace engineering [1]. While direct analysis of plates under different conditions is still an active area of research [2][3][4], inverse analysis of plates for identification of applied loads has attracted the attention of many researchers [5][6][7]. Identification of a moving load can be carried out by a suitable inverse analysis and using measurement of dynamic structural responses such as displacement, velocity, or acceleration at some sampling points.…”

Identification of Time Variations of Moving Loads Applied to Plates Resting on Viscoelastic Foundation Using a Meshfree Method

Shape Sensing of Stiffened Plates Using Inverse FEM Aided by Virtual Strain Measurements