The beam will deflect in the direction of the load
This is Hooke's law, which states that load is proportional to deflection
the beam gets bend if the load is more then the resisting force of the beam and if the resisting force is more then the load it doesn't bends.
when the load is applied in the beam then deflection takes place. the nature of the deflection depends on the support provided on it
Increasing the force applied to the beam or increasing the distance from the force to the point of interest on the beam will increase the moment in the beam. Additionally, changing the angle of the force relative to the beam will also affect the moment.
If a force is applied to an object, but the object does not move or change its shape, then the force is likely being balanced by an equal and opposite force. This situation is described by Newton's third law of motion, which states that for every action there is an equal and opposite reaction.
The answer depends of the forces applied to the beam: - for a single-directional force, the answer is a hollow rectangular shape (with the force applied on the narrow face); an I-beam is the second best. - For forces applied in two perpendicular directions, the answer is a hollow square section. - For forces applied from any direction, the answer is a hollow circular bar - a pipe.
The object will not move!!!
it increases in direct proportion to the force applied
it increases in direct proportion to the force applied
light is made up of small energy packets known as photons which are massless and as gravity depends on the mass of the particle therefore there is no gravitational force applied on or applied by a beam of light.
Surface Tension happens
Strain shows how much longer a beam becomes after applying a force in a chosen direction.Strain = change of length of the the beam / original length of the beamIn case of Shear Strain force is applied only parallel to the surface of the beam (not normal to it).The same principal can be applied not only to beams, but to other civil engineering components as well.
The object is accelerated in the direction of the net (or resultant) force.