SIMPLY-SUPPORTED BEAM WITH CONCENTRATED COUPLE AT INTERMEDIATE POINT

SI/Metric Units

US Customary Units
INPUT   DATA EXAMPLE Of Input/Output

Title  

Length, L m

    

Loadpoint distance, a m
Modulus of elasticity, E   109N/m2 
Area moment of inertia, I   cm4
Couple applied N.m

     Reset

OUTPUT   VARIABLES   &   GRAPHS

Variables   Values   Units
 ♦  Maximum Shear force, Vmax N Graphs:
 Shear force Vs Distance  
 Bending moment Vs Distance  
 Deflection Vs Distance  
 ♦  Maximum Bending moment, Mmax   N.m  
 ♦  Maximum Deflection, Dmax cm
 ♦  Distance of point of Dmax m
 ♦  Deflection at loadpoint cm
 ♦  Reaction force, R1 N
 ♦  Reaction force, R2 N
 ♦  Slope angle, θ1 °
 ♦  Slope angle, θ2 °
THEORY  &   FORMULAE

Bending Of A Straight Elastic Prismatic Beam

Consider a cantilevered bar, having a concentrated couple acting counter-clockwise at any intermediate point along its length. The following equations describe the distribution of shear force, bending moment and deformation:

    

where
     C = applied couple (moment) about any intermediate point, +ve anticlockwise
     L = length of beam
     a = location of load point from left end of beam
     x = distance from left end of beam
     E = modulus of elasticity of beam material
     I = area moment of inertia of cross-sectional area about axis through centroid
     V = shear force
     M = bending moment
     D = deflection
     R1 = vertical reaction at left end
     R2 = vertical reaction at right end
     θ1 = angle of slope at left end
     θ2 = angle of slope at right end

The delection at load point is given by D=[Ca2/2EI]. The maximum deflection is:
Dmax=[Ca(2L-a)/2EI] occuring at the free end.

Tips

    ◊ Use link EXAMPLE Of Input/Output  to demo data entry expectations and results; you may edit & use it as starting point

BIBLIOGRAPHY