Compression and tension are two types of stress that can act on a material. Compression occurs when forces push inward on the material, while tension occurs when forces pull outward on the material. In the context of structures, compression and tension often work together to maintain stability and strength.
In structural engineering, tension and compression are two types of forces that act on materials. Tension is a pulling force that stretches or elongates a material, while compression is a pushing force that shortens or compresses a material. The main difference between tension and compression is the direction in which the force is applied: tension pulls the material apart, while compression pushes the material together. These forces can affect the stability and strength of structures, so engineers must consider them carefully when designing buildings and bridges.
Compression occurs when an object is squeezed or pressed together, causing it to shorten or compact. Tension, on the other hand, happens when an object is stretched or pulled apart, causing it to elongate or expand. Both compression and tension are types of forces that can act on materials.
Tension and compression are not forces themselves, but rather types of forces that act on objects. Tension is a force that pulls or stretches an object, while compression is a force that pushes or squeezes an object. Both tension and compression are common forces in structural mechanics.
If you pull on a string with both hands, one at either end, the string is in tension. If you pull directly along its axis on any object that is attached to ground you put it in tension. If you push it is in compression
The relationship between the tension in a string and the hanging weights it supports is direct and proportional. As the weight of the hanging objects increases, the tension in the string also increases to support the added weight. This relationship follows the principle of equilibrium in physics.
compression zone is an positive zone,tension zone is an negative zone..
tension streches it compression squeezes it
In structural engineering, tension and compression are two types of forces that act on materials. Tension is a pulling force that stretches or elongates a material, while compression is a pushing force that shortens or compresses a material. The main difference between tension and compression is the direction in which the force is applied: tension pulls the material apart, while compression pushes the material together. These forces can affect the stability and strength of structures, so engineers must consider them carefully when designing buildings and bridges.
Compression occurs when an object is squeezed or pressed together, causing it to shorten or compact. Tension, on the other hand, happens when an object is stretched or pulled apart, causing it to elongate or expand. Both compression and tension are types of forces that can act on materials.
A crack is caused by tension not compression because tension pulls matter apart while compression pushes matter together
1.compression 2.tension 3.torsion 4.shear 5.gravity
it is used to measure the extension or compression in the object after it is subjected to tension or compression test it is used to measure the extension or compression in the object after it is subjected to tension or compression test
Tension and compression are not forces themselves, but rather types of forces that act on objects. Tension is a force that pulls or stretches an object, while compression is a force that pushes or squeezes an object. Both tension and compression are common forces in structural mechanics.
Tension and compression takes place when an object has a force on another object. The tension is when the force is causing a pulling effect on part of the object. The compression is when the force is causing a contracting effect on part of the object.
If you pull on a string with both hands, one at either end, the string is in tension. If you pull directly along its axis on any object that is attached to ground you put it in tension. If you push it is in compression
The relationship between the tension in a string and the hanging weights it supports is direct and proportional. As the weight of the hanging objects increases, the tension in the string also increases to support the added weight. This relationship follows the principle of equilibrium in physics.
it protects from tension and compression