Title :
Langrangian dynamic and static equation of the elastic plane deformation of beams
Author_Institution :
Archit. Eng. Coll., Shanghai Normal Univ., Shanghai, China
Abstract :
Basing on Hamilton´s principle, the second variation principle is deduced under the conditions of generalized coordinator, generalized force and the continuity of deformation. A Lagrangian basic elastic equation about plane deformation problem of beams structure is presented. By applying Hamilton´s function, the inverse problems in the continuum variation principle are avoided, and integration by parts is alternated into the calculation of partial difference. It not only simplifies the solving of direct problem, but also stylizes the solution process. In this paper, a set of dynamic and static partial difference equations and a set of primary and boundary equations are deduced in the cases of analyzing the geometric non-linear Timoshenko beam and Bernoulli-Euler beam under axial pressure.
Keywords :
beams (structures); boundary integral equations; elastic deformation; inverse problems; partial differential equations; Bernoulli-Euler beam; Hamilton´s function; Hamilton´s principle; Lagrangian basic elastic equation; Langrangian dynamic equation; axial pressure; beams structure; boundary equations; continuum variation principle; deformation continuity; elastic plane deformation; generalized coordinator; generalized force; geometric nonlinear Timoshenko beam; inverse problems; partial difference equations; primary equations; second variation principle; static equation; Continuing education; DNA; Difference equations; Educational institutions; Electronic mail; Inverse problems; Lagrangian functions; Nonlinear equations; Personnel; Stress; Bernoulli-Euler Beam; Non-linear; Theory of Hamilton; Timoshenko Beam;
Conference_Titel :
Mechanic Automation and Control Engineering (MACE), 2010 International Conference on
Conference_Location :
Wuhan
Print_ISBN :
978-1-4244-7737-1
DOI :
10.1109/MACE.2010.5536209
