Impact Force Identification Research Articles

803 少数のセンサーを用いた弾性平板の衝撃荷重同定逆解析に関する検討(OS9-1 解析と設計1,オーガナイズドセッション9 解析と設計)

803 少数のセンサーを用いた弾性平板の衝撃荷重同定逆解析に関する検討(OS9-1 解析と設計1,オーガナイズドセッション9 解析と設計)

711 コア入り圧電ファイバーを用いた衝撃荷重の位置同定

711 コア入り圧電ファイバーを用いた衝撃荷重の位置同定

Wave propagation in inhomogeneous layered media: solution of forward and inverse problems

Wave propagation in anisotropic inhomogeneous layered media due to high frequency impact loading is studied using a new Spectral Layer Element (SLE). The element can model functionally graded materials (FGM), where the material property variation is assumed to follow an exponential function. The element is exact for a single parameter model which describes both moduli and density variation. This novel element is formulated using the method of partial wave technique (PWT) in conjunction with linear algebraic methodology. The matrix structure of finite element (FE) formulation is retained, which substantially simplifies the modeling of a multi-layered structure. The developed SLE has an exact dynamic stiffness matrix as it uses the exact solution of the governing elastodynamic equation in the frequency domain as its interpolation function. The mass distribution is modeled exactly, and, as a result, the element gives the exact frequency response of each layer. Hence, one element may be as large as one complete layer which results in a system size being very small compared to conventional FE systems. The Fast-Fourier Transform (FFT) and Fourier series are used for the inversion to the time/space domain. The formulated element is further used to study the stress distribution in multi-layered media. As a natural application, Lamb wave propagation in an inhomogeneous plate is studied and the time domain description is obtained. Further, the advantage of the spectral formulation in the solution of inverse problems, namely the force identification and system identification is investigated. Constrained nonlinear optimization technique is used for the material property identification, whereas the transfer function approach is taken for the impact force identification.

Impact Force Identification of CFRP Laminated Plates Using PZT Piezoelectric Sensors (2nd Report, Experimental Verification)

The present paper shows an experimental verification of the impact force identification method developed in the author's previous paper. First, the outline of the impact force identification method based on the relationship between an impact force and the corresponding strain responses is described. In order to discuss the validity of the present method, an impact force identification system is constructed for CFRP laminated plates with PZT piezoelectric sensors. Once an impact acts on the plates, the system that consists of several sensor networks and signal processors can identify both the location and the history of the impact. The experimental results with the plates under two different support conditions are reported. According to the identified results of force location and history, the validity of the present method is verified, and the influence of the modeling error in the finite element model is also discussed.

Impact Force Identification of CFRP Laminated Plates Using PZT Piezoelectric Sensors (1st Report, Identification Method and Numerical Simulation)

The information of impact force acting on composite structures is useful in assessment of their integrity. In this paper, an identification method of impact force acting on CFRP plates is presented. First, a relationship between a force history and the induced strain responses is formulated based on the finite element method. For identifying force location, two methods are presented in this paper. The first method uses an optimization procedure with a reciprocal relationship of strain responses. In the second method, minimizing an error between measured strain responses and analytical ones gives a true force location. The force history identification can be achieved by solving an inverse problem where a penalty on the force history is imposed. Finally, the present method is verified through numerical simulations using CFRP laminated square plates with embedded PZT piezoelectric sensors. According to the results of impact force identification, the validity of the present method is verified.

221 センサの最適配置によるモードセンサの構築法と平板の衝撃荷重同定への応用(材料力学IV)

221 センサの最適配置によるモードセンサの構築法と平板の衝撃荷重同定への応用(材料力学IV)

512 モードセンサによる複合材構造の衝撃荷重同定

512 モードセンサによる複合材構造の衝撃荷重同定

Blind Identification of Impact Forces From Multiple Remote Vibratory Measurements

Blind Identification of Impact Forces From Multiple Remote Vibratory Measurements

The Spectral Element Method in Structural Dynamics

Preface. Part One Introduction to the Spectral Element Method and Spectral Analysis of Signals. 1 Introduction. 1.1 Theoretical Background. 1.2 Historical Background. 2 Spectral Analysis of Signals. 2.1 Fourier Series. 2.2 Discrete Fourier Transform and the FFT. 2.3 Aliasing. 2.4 Leakage. 2.5 Picket-Fence Effect. 2.6 Zero Padding. 2.7 Gibbs Phenomenon. 2.8 General Procedure of DFT Processing. 2.9 DFTs of Typical Functions. Part Two Theory of Spectral Element Method. 3 Methods of Spectral Element Formulation. 3.1 Force-Displacement Relation Method. 3.2 Variational Method. 3.3 State-Vector Equation Method. 3.4 Reduction from the Finite Models. 4 Spectral Element Analysis Method. 4.1 Formulation of Spectral Element Equation. 4.2 Assembly and the Imposition of Boundary Conditions. 4.3 Eigenvalue Problem and Eigensolutions. 4.4 Dynamic Responses with Null Initial Conditions. 4.5 Dynamic Responses with Arbitrary Initial Conditions. 4.6 Dynamic Responses of Nonlinear Systems. Part Three Applications of Spectral Element Method. 5 Dynamics of Beams and Plates. 5.1 Beams. 5.2 Levy-Type Plates. 6 Flow-Induced Vibrations of Pipelines. 6.1 Theory of Pipe Dynamics. 6.2 Pipelines Conveying Internal Steady Fluid. 6.3 Pipelines Conveying Internal Unsteady Fluid. Appendix 6.A: Finite Element Matrices: Steady Fluid. Appendix 6.B: Finite Element Matrices: Unsteady Fluid. 7 Dynamics of Axially Moving Structures. 7.1 Axially Moving String. 7.2 Axially Moving Bernoulli-Euler Beam. 7.3 Axially Moving Timoshenko Beam. 7.4 Axially Moving Thin Plates. Appendix 7.A: Finite Element Matrices for Axially Moving String. Appendix 7.B: Finite Element Matrices for Axially Moving Bernoulli-Euler Beam. Appendix 7.C: Finite Element Matrices for Axially Moving Timoshenko Beam. Appendix 7.D: Finite Element Matrices for Axially Moving Plate. 8 Dynamics of Rotor Systems. 8.1 Governing Equations. 8.2 Spectral Element Modeling. 8.3 Finite Element Model. 8.4 Numerical Examples. Appendix 8.A: Finite Element Matrices for the Transverse Bending Vibration. 9 Dynamics of Multi-Layered Structures. 9.1 Elastic-Elastic Two-Layer Beams. 9.2 Elastic-Viscoelastic-elastic-Three-Layer (PCLD) Beams. Appendix 9.A: Finite Element Matrices for the Elastic-Elastic Two-Layer Beam. Appendix 9.B: Finite Element Matrices for the Elastic-VEM-Elastic Three-Layer Beam. 10 Dynamics of Smart Structures. 10.1 Elastic-Piezoelectric Two-Layer Beams. 10.2 Elastic-Viscoelastic-Piezoelctric Three-Layer (ACLD) Beams. 11 Dynamics of Composite Laminated Structures. 11.1 Theory of Composite Mechanics. 11.2 Equations of Motion for Composite Laminated Beams. 11.3 Dynamics of Axial-Bending-Shear Coupled Composite Beams. 11.4 Dynamics of Bending-Torsion-Shear Coupled Composite Beams. Appendix 11.A: Finite Element Matrices for Axial-Bending-Shear Coupled Composite Beams. Appendix 11.B: Finite Element Matrices for Bending-Torsion-Shear Coupled Composite Beams. 12 Dynamics of Periodic Lattice Structures. 12.1 Continuum Modeling Method. 12.2 Spectral Transfer Matrix Method. 13 Biomechanics: Blood Flow Analysis. 13.1 Governing Equations. 13.2 Spectral Element Modeling: I. Finite Element. 13.3 Spectral Element Modeling: II. Semi-Infinite Element. 13.4 Assembly of Spectral Elements. 13.5 Finite Element Model. 13.6 Numerical Examples. Appendix 13.A: Finite Element Model for the 1-D Blood Flow. 14 Identification of Structural Boundaries and Joints. 14.1 Identification of Non-Ideal Boundary Conditions. 14.2 Identification of Joints. 15 Identification of Structural Damage. 15.1 Spectral Element Modeling of a Damaged Structure. 15.2 Theory of Damage Identification. 15.3 Domain-Reduction Method. 16 Other Applications. 16.1 SEM-FEM Hybrid Method. 16.2 Identification of Impact Forces. 16.3 Other Applications. References. Index.

Remote Identification of Impact Forces on Loosely Supported Tubes: Analysis of Multi-Supported Systems

Impact forces are useful information in field monitoring of many industrial components, such as heat exchangers, condensers, etc. In two previous papers we presented techniques—based on vibratory measurements remote from the actual impact locations—for the experimental identification of isolated impacts (Arau´jo et al., 1996) and complex rattling forces (Antunes et al., 1997). In both papers a single gap support was assumed. Those results concern systems which are simpler than the actual multi-supported tube bundles found in heat exchangers. Impact force identification is a difficult problem for such systems, because 1) when sensed by the remote motion transducers, the traveling waves generated at several impact supports are mixed, and there is no obvious way to isolate the contribution of each support; 2) multi-supported tubes may be quite long, with significant dissipative effects (by interacting flows or by frictional phenomena at the clearance supports), leading to some loss of the information carried by the traveling waves; 3) in multi-supported systems, some of the supports are often in permanent contact, leading to nonimpulsive forces which are difficult to identify. In this paper, we move closer towards force identification under realistic conditions. Only the first problem of wave isolation is addressed, assuming that damping effects are small and also that all clearance supports are impacting. An iterative multiple-identification method is introduced, which operates in an alternate fashion between the time and frequency domains. This technique proved to be effective in isolating the impact forces generated at each gap support. Experiments were performed on a long beam with three clearance supports, excited by random forces. Beam motions were planar, with complex rattling at the supports. Experimental results are quite satisfactory, as the identified impact forces compare favorably with the direct measurements.

Proposition of Simple Identification Method for Multiple Impact Forces on Orthotropic Laminated Plates.

In this paper we propose a simple method for identification of multiple impact forces on a simply supported orthotropic laminated plate. Acceleration responses at several points in the interior of the plate are measured in order to determine locations and histories of the impact forces. The present method can identify the impact forces at any arbitrary locations of the plate with every measurement of acceleration. First, the identification algorithm is shown for single and double impact forces at arbitrary locations on the plate. Next, through the numerical examples we examine the effect of the number of measurement points on the identified results and the measurement errors are also taken into consideration in the identification. The validity of the present method is shown by comparing the present results with exact ones for locations and histories of impact forces.

A wavelet deconvolution method for impact force identification

The inverse problem of solving for impact force history using experimentally measured structural responses tends to be ill conditioned. A computationally efficient deconvolution method with similarities to Fourier analysis and wavelet analysis is introduced. Force reconstructions obtained using measured acceleration responses from beam and plate models are used to verify the method.

Identification of impact force and location using distributed sensors

An impact load identification method using distributed built-in sensors for detecting foreign object impact is proposed. The identification system consists of a system model and a response comparator. The system model characterizes the dynamic response of the structure subject to a known impact force. The comparator compares the measured sensor outputs with the estimated measurements from the model and predicts the location and force history of the impact. The method has been developed for beams containing distributed piezoelectric sensors. The identification system was tested using simulated conditions. For all of the cases considered, the estimation errors fell well within the prespecified limit.

Impact force identification from wave propagation responses

The inverse problem of solving for the impact force history using experimentally measured structural responses tends to be ill-conditioned. This paper uses a frequency domain deconvolution method to help clarify some of the fundamental difficulties and issues involved in this problem. Force reconstructions obtained using experimentally measured acceleration responses from four example structures are used to illustrate the points.

Identification of impact forces at multiple locations on laminated plates

Identification of impact forces at multiple locations on laminated plates

Transient Response of an Impacted Beam and Indirect Impact Force Identification Using Strain Measurements

The impulse response functions (force-strain relations) for Euler–Bernoulli and Timoshenko beams are considered. The response of a beam to a transverse impact force, including reflection at the boundary, is obtained with the convolution approach using the impulse response function obtained by a Laplace transform and a numerical scheme. Using this relation, the impact force history is determined in the time domain and results are compared with those of Hertz's contact law. In the case of an arbitrary impact, the location of the impact force and the time history of the impact force can be found. In order to verify the proposed algorithm, measurements were taken using an impact hammer and a drop test of a steel ball. These results are compared with simulated ones.

Transient Response of an Impacted Beam and Indirect Impact Force Identification Using Strain Measurements

The impulse response functions (force-strain relations) for Euler–Bernoulli and Timoshenko beams are considered. The response of a beam to a transverse impact force, including reflection at the boundary, is obtained with the convolution approach using the impulse response function obtained by a Laplace transform and a numerical scheme. Using this relation, the impact force history is determined in the time domain and results are compared with those of Hertz's contact law. In the case of an arbitrary impact, the location of the impact force and the time history of the impact force can be found. In order to verify the proposed algorithm, measurements were taken using an impact hammer and a drop test of a steel ball. These results are compared with simulated ones.

Impact force identification using the general inverse technique

The general inverse technique has been applied to the problem of impact force identification. The force identification problem can be stated as follows: ‘Given the response of a structure, what impact force is required to produce this response?’ Experimental measurement data was used to describe the velocity response of an impacted cantilever beam. The inverse technique used these measurements to predict the impact force which resulted in the beam response. A spectrum analyzer was used to measure the beam accelerations within 40 μs time intervals. The accelerations were integrated so that the response was in suitable velocity form for use in the inverse algorithm. The analyzer and impact hammer also allowed the measurement of the actual dynamic load, and thus provided a means of comparison against the predicted impact force given by the inverse technique.