In physics:
Axial Stress: A tension or compression stress created in a structural member by the application of a lengthwise axial load.
Definition Copyright ©1989 CRC Press LLC. All rights reserved.
Examples of tensile axial stress include a chain carrying a load and tension cables on a bridge. Examples of compressive axial stress include decorative columns in architecture and the steel structure of a high rise building.
(pie*d2/4)*stress
Just like axial stress, shear stress is force divided by area. The area is the surface the force acts over. For example, imagine two wood blocks that are nailed together. If you apply a force to the top block orthogonal to the longitudinal axis of the nail and the same force in the opposite direction to the bottom block, the shear stress (𝝉) in the nail is 𝝉 = F/A or F/(πr2) where r is the radius of the nail.
Shear force is a load (pounds, or newtons) in plane of the object which produces shear stress ( pounds per sq inch, or Pascals). Shear force is related to shear stress as STRESS = FORCE/AREA
Centrifugal force of the fan results in an increase in static force. The blades of the axial flow fans force air to move parallel to them.
The maximum stress induced in a body due to suddenly applied load is twice the stress induced when the same load is applied gradually
When a helical compression spring is subjected to axial compressive force, the type of stress induced in the spring wire is primarily compressive stress. This stress is caused by the load that the spring is supporting, leading to a reduction in the length of the spring along its axial direction.
Axial Stress: A tension or compression stress created in a structural member by the application of a lengthwise axial load.Definition Copyright ©1989 CRC Press LLC. All rights reserved.Examples of tensile axial stress include a chain carrying a load and tension cables on a bridge. Examples of compressive axial stress include decorative columns in architecture and the steel structure of a high rise building.Read more: What_is_axial_stressLongitudinal Stress: In continum mechanics, stress is a measure of the average force per unit area of a surface within a deformable body on which internal forces
Longitudinal stress is the stress experienced by a material when it is subjected to forces that act along its length, typically due to tension or compression. This type of stress is calculated as the force applied per unit area and can lead to deformation, such as stretching or shortening, depending on the nature of the applied load. It is crucial in engineering and materials science for analyzing the behavior of structures and components under axial loads.
Axial Thrust is a force that is generated in an axial direction which is by definition along the shaft
For calculating the collapse pressure of a pipe, you first need to calculate the Hoop stress, which is given by :- Stress = Circumferencial Force/(radial thickness*axial length) If the stress crosses this value the pipe would collapse.
2.1.2. Compressive StressIf the bar is subjected to axial compression instead of axial tension, the stress developed at x-x is specifically called compressive stress pc.pc =R/A= P/A.Under compressive stress the bar suffers shortening.
In materials science, strain refers to the deformation or change in shape of a material, while stress is the force applied to the material causing the strain. Strain is the result of stress, and they are related but distinct concepts in understanding the behavior of materials under external forces.
Axial Force is the y direction. Shear Force is the x direction. Axial force is either in compression or tension, hence compressive and tensile. Shear force is like a splice it cuts right through the object.
We knew from Hook's law- "stress is proportional to strain." So, stress = k * strain [here, k is a constant] or, stress/strain= k Now, if the stress and strain occurs due to axial force then k is known as modulus of elasticity and it is denoted by E. if the stress and strain occurs due to shear force then k is known as modulus of rigidity and it is denoted by G.
(pie*d2/4)*stress
Torque=.2*F*Bolt Maj. Dim. F=axial force
In physics, stress is the force applied to a material, while strain is the resulting deformation or change in shape. The relationship between stress and strain in materials is explained by the concept of elasticity, which describes how materials respond to stress by deforming and returning to their original shape when the stress is removed. This relationship is typically represented by a stress-strain curve, which shows how a material deforms under different levels of stress.