期刊
MECHANISM AND MACHINE THEORY
卷 192, 期 -, 页码 -出版社
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.mechmachtheory.2023.105517
关键词
Geometrically nonlinear Euler Bernoulli beam theory; Beam Constraint Model; Body frame (Frenet frame); Linearization
Researchers proposed a new modeling method, namely Body-frame Beam Constraint Model (BBCM), to predict and optimize the design of high-precision compliant mechanisms (CMs).
Compliant Mechanisms (CMs) have presented their inherently advantageous properties since the nature of CMs is to utilize elastic deformation of the built-in elementary flexible members to transfer motion, force and energy. To predict the performances of CMs and optimize their designs, modeling CMs turns out to be a major concern in this field, particularly, such as high-precision flexure-based CMs. Reported in the literature, the well-known Beam Constraint Model (BCM) expressed in Cartesian coordinate system serves as an effective tool to model the deflection of flexures. Inspired by BCM, in this paper, we take one step further to propose a Body-frame Beam Constraint Model (BBCM) to handle buckling and intermediate range deflections under typical beam-end loading conditions. Numerical and analytical analysis also proves that BBCM can also provide reliable accuracy in complex loading conditions and complex beam geometries within small-to-intermediate-range deflections and may accurately characterize large deflections under some specific loading conditions as well.
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