Numerical Study of Large Defection of Functionally Graded Beam with Geometry Nonlinearity

A. Soleimani; M. Saadatfar

doi:10.4028/www.scientific.net/AMR.403-408.4226

Paper Titles

A CMOS MEMS Resonant Magnetic Field Sensor with Differential Electrostatic Actuation and Capacitive Sensing
p.4205

Flood Submergence Processes Simulation Based on Virtual Reality
p.4210

Optimization Design and Motion Simulation of Offset Slider-Crank Mechanism
p.4216

Study on Design for Rolling Die of Feed Granulator
p.4221

Numerical Study of Large Defection of Functionally Graded Beam with Geometry Nonlinearity
p.4226

An Electromagnetic Frequency Increased Vibration Energy Harvester
p.4231

A Theoretical and Experimental Study on Temperature Dependent Characteristics of Silicon MEMS Gyroscope Drive Mode
p.4237

A Micro-Machined Silicon Vibrating Ring Gyroscope
p.4244

Research and Test of the Digital Phase Locked Loop Drive Technology for Silicon Micro-Machined Gyroscope
p.4252

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 403-408Numerical Study of Large Defection of Functionally...

Numerical Study of Large Defection of Functionally Graded Beam with Geometry Nonlinearity

Abstract:

The equation of large deflection of functionally graded beam subjected to arbitrary loading condition is derived. In this work assumed that the elastic modulus varies by power function in longitudinal direction. The nonlinear derived equation has not exact solution so shooting method has been proposed to solve the nonlinear equation of large deflection. Results of shooting method are validated with finite element solutions. The method will be useful toward the design of compliant mechanisms driven by smart actuators. Finally the effect of different elastic modulus functions and loading conditions are investigated and discussed.