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1 CHAP 4 FINITE ELEMENT ANALYSIS OF BEAMS AND FRAMES FINITE ELEMENT ANALYSIS AND DESIGN Nam-Ho Kim Audio: Raphael Haftka.

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Presentation on theme: "1 CHAP 4 FINITE ELEMENT ANALYSIS OF BEAMS AND FRAMES FINITE ELEMENT ANALYSIS AND DESIGN Nam-Ho Kim Audio: Raphael Haftka."— Presentation transcript:

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2 1 CHAP 4 FINITE ELEMENT ANALYSIS OF BEAMS AND FRAMES FINITE ELEMENT ANALYSIS AND DESIGN Nam-Ho Kim Audio: Raphael Haftka

3 2 INTRODUCTION We learned Direct Stiffness Method in Chapter 2 –Limited to simple elements such as 1D bars we will learn Energy Method to build beam finite elements –Structure is in equilibrium when the potential energy is minimum Potential energy: Sum of strain energy and potential of applied loads Interpolation scheme: Beam deflection Interpolation function Nodal DOF Potential of applied loads Strain energy

4 3 BEAM THEORY Assumptions for our plane beam element –carries transverse loads –slope can change along the span (x-axis) –Cross-section is symmetric w.r.t. xy-plane –The y-axis passes through the centroid –Loads are applied in xy-plane (plane of loading) L F x y F Plane of loading y z Neutral axis A

5 4 BEAM THEORY cont. Euler-Bernoulli Beam Theory –Plane sections normal to the beam axis remain plane and normal to the axis after deformation (no shear strain) –Transverse deflection (deflection curve) is function of x only: v(x) –Displacement in x-dir is function of x and y: u(x, y) y y(dv/dx)  = dv/dx v(x) L F x y Neutral axis

6 5 BEAM STRESSES AND FORCE RESULTANTS Stresses –Strain along the beam axis: –Strain  xx varies linearly w.r.t. y;Strain  yy = 0 –Curvature: –Can assume plane stress in z-dirbasically uniaxial status Axial force resultant and bending moment Moment of inertia I(x) EA: axial rigidity EI: flexural rigidity

7 6 BEAM LOADING Beam constitutive relation –We assume P = 0 (We will consider non-zero P in the frame element) –Moment-curvature relation: Sign convention –Positive directions for applied loads Moment is proportional to curvature +P +M +V y y x p(x) F1F1 F2F2 F3F3 C1C1 C2C2 C3C3 y x

8 7 BEAM EQUILIBRIUM EQUATIONS –Combining three equations together: –Fourth-order differential equation

9 8 STRESS AND STRAIN Bending stress –This is only non-zero stress component for Euler-Bernoulli beam Transverse shear strain –Euler beam predicts zero shear strain (approximation) –Traditional beam theory says the transverse shear stress is –The approximation that first neglects shear strains and then calculates them from equilibrium is accurate enough for slender beams unless shear modulus is small. Bending stress

10 9 POTENTIAL ENERGY Potential energy Strain energy –Strain energy density –Strain energy per unit length –Strain energy Moment of inertia

11 10 POTENTIAL ENERGY cont. Potential energy of applied loads Potential energy –Potential energy is a function of v(x) and slope –The beam is in equilibrium when  has its minimum value  v v*v*


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