The type of bone tissue that gives a bone its strength is called cortical or compact bone tissue. This type of bone tissue is dense and forms the outer layer of most bones in the body, providing strength, support, and protection. Cortical bone tissue contains mineralized collagen fibers that are arranged in a parallel fashion, giving the bone its characteristic strength and resistance to bending or breaking.
Compact bone tissue is adapted to support weight and withstand tension stress due to its dense structure and arrangement of osteons. These osteons are aligned in the direction of stress to provide strength and stability to the bone. This compact arrangement makes it ideal for weight-bearing and resisting tension.
Plants have various structures adapted for support, such as rigid cell walls in stems and trunks, woody tissues for strength, and specialized structures like tendrils, thorns, and aerial roots that help anchor the plant. Additionally, plants use mechanisms like turgor pressure in cells and the production of lignin to maintain upright growth and withstand environmental stress.
Collagen is the strong tissue that forms tendons and ligaments in the body. It provides structure and support to these connective tissues, enabling them to withstand tension and stress during movement and physical activity. Collagen fibers are arranged in a parallel manner to enhance their strength and flexibility.
A plant with thick stems typically indicates strong structural support, which can help it withstand environmental factors like wind or rain. Thick stems may also suggest that the plant has adapted to store water or nutrients in its tissues, providing reserves for periods of stress or drought. Additionally, plants with thick stems often exhibit vigorous growth and can support heavy foliage or flowers.
Collagen is the protein substance that forms the glistening inelastic fibers of connective tissue such as tendons, ligaments, and fascia. It provides strength, structure, and support to these tissues, contributing to their ability to withstand tension and stress.
Compact bone tissue is adapted to support weight and withstand tension stress due to its dense structure and arrangement of osteons. These osteons are aligned in the direction of stress to provide strength and stability to the bone. This compact arrangement makes it ideal for weight-bearing and resisting tension.
Compact Bone
Cranial bones develop within fibrous membranes. Cranial bone tissues are adapted to support weight and withstand the tension and stress of the skull.
Emotional tension is stress
Sinews and tendons are tissues that connect muscles to bones and can withstand tension or stress. They are different names for the same thing, so yes, they are the same thing.
Plants have various structures adapted for support, such as rigid cell walls in stems and trunks, woody tissues for strength, and specialized structures like tendrils, thorns, and aerial roots that help anchor the plant. Additionally, plants use mechanisms like turgor pressure in cells and the production of lignin to maintain upright growth and withstand environmental stress.
Yes stress is a tension thing. It causes the person to take tension. It causes one to think negatively.
Tension or tensile stress is what you described in the question.
Flexural compression refers to the type of stress that occurs in a beam or structural member when it is subjected to a bending load. This compression stress acts on the upper portion of the beam, while tension occurs on the lower portion. It is important to consider both compression and tension when designing structural elements to ensure they can withstand bending loads.
if you mean whene you give some one lots of tension <><><><><> Tension is stress, or voltage, to name just two. tension-is stress that streches or pull rocks apart
The maximum stress in a ring under tension occurs at the point on the ring that is farthest from the center. This is because the force of the tension is distributed evenly around the circumference of the ring, and the points on the ring that are farthest from the center have to support more of the tension due to their greater distance from the center. As a result, the stress is highest at these points and decreases towards the center of the ring. For more visit this site: π₯π±π±ππ°://π΄π΄π΄.π‘π¦π€π¦π°π±π¬π―π’24.π π¬πͺ/π―π’π‘π¦π―/394659/ππ²π΄ππ«ππ₯ππ―ππ«/
The capacity to withstand repeated stress