A stable and efficient meshfree Galerkin method with consistent integration schemes for strain gradient thin beams and plates

A stable and efficient meshfree Galerkin method with consistent integration schemes for strain gradient thin beams and plates

© 2020 Elsevier Ltd The strain gradient (SG) theory, incorporating with thin beam and plate models, can effectively describe size effects of micro- and nano-structures. However, since these models are determined by a sixth-order partial differential equation that requires the C2 continuity of de...

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Bibliographic Details
Main Authors: Wang, B.B., Lu, Chunsheng, Fan, C.Y., Zhao, M.H.
Format: Journal Article
Language:English
Published: ELSEVIER SCI LTD 2020
Subjects:
Science & Technology
Technology
Engineering, Civil
Engineering, Mechanical
Mechanics
Engineering
Strain gradient
Thin beam and plate
Meshfree
Integration constraint
Smoothed derivative
POINT INTERPOLATION METHOD
QUADRATIC EXACTNESS
NONLINEAR VIBRATION
NODAL INTEGRATION
ELEMENT
FORMULATION
ELASTICITY
DEFORMATION
PLASTICITY
SURFACE
Online Access:http://hdl.handle.net/20.500.11937/80195
Description
Summary:© 2020 Elsevier Ltd The strain gradient (SG) theory, incorporating with thin beam and plate models, can effectively describe size effects of micro- and nano-structures. However, since these models are determined by a sixth-order partial differential equation that requires the C2 continuity of deflection in a Galerkin weak form, it is difficult to make stable and efficient numerical analysis. In this paper, a meshfree Galerkin method is presented for SG thin beams and plates. To satisfy the continuity and convergence requirement, moving least square or reproducing kernel shape functions are employed with cubic approximation bases. To pass the patch test, integration constraints are derived and consistent integration schemes are proposed with nodal smoothed derivatives instead of standard ones on evaluating points. Numerical results show that consistent integration is superior to the standard Gauss integration in convergence, accuracy and efficiency.

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