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  • A Novel Spring-Based Model for Damage Investigation of Functionally Graded Beams

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کد مقاله : JSM-2104-1690 (R1) بازدید : 208 صفحه: 345 - 360

10.22034/jsm.2021.1928249.1690

20.1001.1.20083505.2022.14.3.5.9

نوع مقاله: پژوهشی

A Novel Spring-Based Model for Damage Investigation of Functionally Graded Beams

محورهای موضوعی : Structural Mechanics

S Karimi 1 , M Bozorgnsab 2 , R Taghipour 3 , M.M Alipour 4

1 - Department of Civil Engineering, Faculty of Engineering and Technology, University of Mazandaran, Babolsar, Iran
2 - Department of Civil Engineering, Faculty of Engineering and Technology, University of Mazandaran, Babolsar, Iran
3 - Department of Civil Engineering, Faculty of Engineering and Technology, University of Mazandaran, Babolsar, Iran
4 - Department of Mechanical Engineering, Faculty of Engineering and Technology, University of Mazandaran, Babolsar, Iran

تاریخ دریافت : 1401/03/08 تاریخ پذیرش : 1401/04/14 تاریخ انتشار : 1401/06/10

کلید واژه: Damage Detection, spring, Free vibration analysis, Functionally graded beam, First-order shear deformation theory,

چکیده مقاله :

In this paper, free vibration analysis of damaged functionally graded beams based on the first-order shear deformation theory (FSDT) is carried out. In this regard, a new model of springs is introduced to model the damaged elements of the beam. The proposed model is achieved from stress resultants. The springs equations for homogeneous and functionally graded (FG) beams are presented; furthermore, equations for equivalent springs are also provided which can be used for both homogeneous and FG beams. The proposed method can be applied for the analysis of structures with fewer computation costs and high accuracy. To show the accuracy of the proposed model, the natural frequencies of the beams with real elements and the ones which are modeled by the proposed springs are compared considering various support conditions. Good agreement has been observed. Thereafter, the model is used to detect the damaged elements. The result shows that the model can properly detect the damage location.

چکیده انگلیسی:

منابع و مأخذ:


  1.  Rytter A., 1993, Vibrational Based Inspection of Civil Engineering Structures, D. thesis, Department of Building Technology and Structural Engineering, Aalborg University.
    2.
  2.  Wu J.S., Huang C.G., 1995, Free and forced vibrations of a Timoshenko beam with any number of translational and rotationalsprings and lumped masses, Communications in Numerical Methods in Engineering 11(9): 743-756.
    3.
  3.  Chondros T., Dimarogonas A., Yao J., 1998, A continuous cracked beam vibration theory, Journal of Sound and Vibration 215(1): 17-34.
    4.
  4.  Li W.L., 2000, Free vibrations of beams with general boundary conditions, Journal of Sound and Vibration 237(4): 709-725.
    5.
  5.  Patil D., Maiti S., 2003, Detection of multiple cracks using frequency measurements, Engineering Fracture Mechanics 70(12): 1553-1572.
    6.
  6.  Lu C-F., Chen W., 2005, Free vibration of orthotropic functionally graded beams with various end conditions,  Structural Engineering and Mechanics 20(4): 465-476.
    7.
  7.  Aydogdu M., Taskin V., 2007, Free vibration analysis of functionally graded beams with simply supported edges, Materials & Design 28(5): 1651-1656.
    8.
  8.  Sina S., Navazi H., Haddadpour H., 2009, An analytical method for free vibration analysis of functionally graded beams, Materials & Design 30(3): 741-747.
    9.
  9.  Şimşek M., 2010, Vibration analysis of a functionally graded beam under a moving mass by using different beam theories, Composite Structures 92(4): 904-917.
    10.
  10.  Moradi S., Razi P., Fatahi L., 2011, On the application of bees algorithm to the problem of crack detection of beam-type structures, Computers & Structures 89(23-24): 2169-2175.
    11.
  11.  Manoach E., Samborski S., Mitura A., Warminski J., 2012, Vibration based damage detection in composite beams under temperature variations using Poincaré maps, International Journal of Mechanical Sciences 62(1): 120-132.
    12.
  12.  Pradhan K., Chakraverty S., 2013, Free vibration of Euler and Timoshenko functionally graded beams by Rayleigh–Ritz method, Composites Part B: Engineering 51: 175-184.
    13.
  13.  Wattanasakulpong N., Ungbhakorn V., 2014, Linear and nonlinear vibration analysis of elastically restrained ends FGM beams with porosities, Aerospace Science and Technology 32(1): 111-120.
    14.
  14.  Shariyat M., Alipour M. M., 2011, Differential transform vibration and modal stress analyses of circular plates made of two-directional functionally graded materials resting on elastic foundations, Archive of Applied Mechanics 81: 1289-1306.
    15.
  15.  Shariyat M., Alipour M. M., 2013, A power series solution for vibration and complex modal stress analyses of variable thickness viscoelastic two-directional FGM circular plates on elastic foundations, Applied Mathematical Modelling 37: 3063-3076.
    16.
  16.  Alipour M. M., Shariyat M., 2010, Stress analysis of two-directional FGM moderately thick constrained circular plates with non-uniform load and substrate stiffness distributions, Journal of Solid Mechanics 2: 316-331.
    17.
  17.  Alipour M. M., Shariyat M., 2011, A power series solution for free vibration of variable thickness Mindlin circular plates with two-directional material heterogeneity and elastic foundations, Journal of Solid Mechanics 3: 183-197.
    18.
  18.  Yazdanpanah O., Seyedpoor S., 2015, A new damage detection indicator for beams based on mode shape data, Structural Engineering and Mechanics 53(4): 725-744.
    19.
  19.  Chen D., Yang J., Kitipornchai S., 2016, Free and forced vibrations of shear deformable functionally graded porous beams, International Journal of Mechanical Sciences 108: 14-22.
    20.
  20.  Pagani A., Carrera E., 2017, Large-deflection and post-buckling analyses of laminated composite beams by Carrera Unified Formulation, Composite Structures 170: 40-52.
    21.
  21.  Wang Y.Q., Zu J.W., 2017, Vibration behaviors of functionally graded rectangular plates with porosities and moving in thermal environment, Aerospace Science and Technology 69: 550-562.
    22.
  22.  Wang Y.Q., Zu J.W., 2017, Nonlinear steady-state responses of longitudinally traveling functionally graded material plates in contact with liquid, Composite Structures 164:130-144.
    23.
  23.  Nakhaei A.M., Dardel M., Ghasemi M.H., 2018, Modeling and frequency analysis of beam with breathing crack, Archive of Applied Mechanics 88(10): 1743-1758.
    24.
  24.  Wang Y.Q., 2018, Electro-mechanical vibration analysis of functionally graded piezoelectric porous plates in the translation state, Acta Astronautica 143: 263-271.
    25.
  25.  Navabian N., Taghipour R., Bozorgnasab M., Ghasemi J., 2018, Damage evaluation in plates using modal data and firefly optimisation algorithm, International Journal of Structural Engineering 9(1): 50-69.
    26.
  26.  Mottaghian F., Darvizeh A., Alijani A., 2018, Extended finite element method for statics and vibration analyses on cracked bars and beams, Journal of Solid Mechanics10(4): 902-928.
    27.
  27.  Soncco K., Jorge X., Arciniega R., 2019, Postbuckling analysis of functionally graded beams, IOP Conference Series: Materials Science and Engineering.
    28.
  28.  Mottaghian F., Darvizeh A., Alijani A. A., 2019, Novel finite element model for large deformation analysis of cracked beams using classical and continuum-based approaches, Archive of Applied Mechanics 89: 195-230
    29.
  29.  Wang Y.Q., Ye C., Zu J.W., 2019, Nonlinear vibration of metal foam cylindrical shells reinforced with graphene platelets, Aerospace Science and Technology 85: 359-370.
    30.
  30.  Li H-C., Ke L-L., Yang J., Kitipornchai S., Wang Y-S., 2020, Free vibration of variable thickness FGM beam submerged in fluid, Composite Structures 233: 111582.
    31.
  31.  Wang Y., Xie K., Fu T., 2020, Vibration analysis of functionally graded graphene oxide-reinforced composite beams using a new Ritz-solution shape function, Journal of the Brazilian Society of Mechanical Sciences and Engineering 42(4): 1-14.
    32.
  32.  Salmalian K., Alijani A., Azarboni H. R., 2021, A lagrange multiplier-based technique within the nonlinear finite element method in cracked columns, Periodica Polytechnica Civil Engineering65(1): 84-98.
    33.
  33.  Mindlin R.D., 1951, Influence of rotatory inertia and shear on flexural motions of isotropic, elastic plates, Journal of Applied Mechanics 18: 31-38.
    34.
  34.  Navabian N., Bozorgnasab M., Taghipour R., Yazdanpanah O., 2016, Damage identification in plate-like structure using mode shape derivatives, Archive of Applied Mechanics 86(5): 819-830.
    35.
  35.  Wahab M.A., De Roeck G., 1999, Damage detection in bridges using modal curvatures: application to a real damage scenario, Journal of Sound and Vibration 226(2): 217-235.
    36.

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