Beam bending is the deformation of a beam under the application of external loads, causing the beam to bend or curve. This can occur when a beam is subjected to a force or moment, and it can result in both tensile and compressive stresses within the beam.
The neutral axis of a beam is an imaginary line that runs through the center of the beam and experiences no stress or strain when the beam is subjected to bending. It is the point at which the beam is neither compressed nor stretched.
The position of the neutral axis is determined by the shape and size of the cross-section of the beam. It is usually located at the centroid - the geometric center - of the cross-section. However, in asymmetric beams or beams with varying cross-sections, the neutral axis may be located at a different point.
The neutral axis is important in beam bending because it is the dividing line between the compressed and stretched regions of a beam. It experiences no stress or strain, and therefore, it is where the beam is most resistant to bending.
The position of the neutral axis can greatly affect the strength of a beam. A beam with a larger cross-sectional area above the neutral axis will have a greater resistance to bending, while a beam with a larger cross-sectional area below the neutral axis will be weaker. This is because the material above the neutral axis experiences compressive stresses, which are easier to resist, while the material below experiences tensile stresses, which are more likely to cause failure.