Tension in the rope needed to pull the object of mass 100 kg with an acceleration of 1 m/s^2 is 100 N. Since the force is the product of mass and acceleration. So 100 x 1.0 = 100 N
With this force of 100 N the body is moved through a distance of 5.0 m and hence work done will be 500 joule. Since the formula for the work done is F s cos @
Here F = 100 N ; s = 5.0 m ; @ = 0 as tension and the displacement in the same direction. Hence the value of work done is 500 joule.
The work done by the tension force is calculated as the product of the force exerted by the tension and the distance over which it acts. The force exerted by the tension is given by the mass times the acceleration plus the force due to gravity. Work = force * distance = (mass * acceleration + mass * gravity) * distance. Plug in the values to find the work done by the tension force.
In physics, the formula for tension in a string or rope is T = mg + ma, where T is the tension force, m is the mass of the object, g is the acceleration due to gravity, and a is the acceleration of the object. This formula takes into account both the weight of the object and any additional forces causing acceleration.
Tension is directly related to velocity in a system with a mass being pulled by a rope or string. As velocity increases, the tension in the rope also increases due to the acceleration and force required to move the object.
Force tension is the force experienced by an object when it is pulled or stretched. It is a type of force that occurs in a rope, cable, or any object that is being stretched or pulled. The magnitude of tension is equal to the force applied to stretch or pull the object.
Tension is a force that is transmitted through a rope, cable, or other similar object when it is pulled tight. It is always directed along the axis of the object experiencing the tension.
The force that pulls an object apart is called tension. Tension occurs when a material is stretched or pulled in opposite directions, causing it to become elongated.
In physics, the formula for tension in a string or rope is T = mg + ma, where T is the tension force, m is the mass of the object, g is the acceleration due to gravity, and a is the acceleration of the object. This formula takes into account both the weight of the object and any additional forces causing acceleration.
The mass of the object is 50 kilogram. The acceleration due to gravity on earth is 9.8m/s2. So the force experienced by the object will be F=mass * acceleration =50*9.8 =490N
tension strength is the strength that works under pressure while a object is being pulled to a constant side , its the tightness being placed on an object
weight is a function of (mass * acceleration due to gravity) and is a force acting toward the earths centre (vertically down) . if your pulling force is horizontal, then it wont affect the weight
The acceleration due to gravity of a falling object is constant and independent of the slope. The slope of the surface affects the component of gravity parallel to it, but the acceleration due to gravity remains the same, causing the object to accelerate downward at a constant rate regardless of the slope.
Neglecting friction, its speed will grow with the least acceleration. Considering friction, it may not move at all.
Rocks being pulled apart are under tension. This is found at divergent plate boundaries. It is a tension fault.
A TENSION FORCE is pulling one end of of an object and and the other end of an object in opposite directions.ex. playing tug of war O - PERSON 1 X - PERSON 2O Xrope
Force=mass*acceleration 80N=10kg*acceleration 80N/10kg=acceleration 8m/s2=acceleration The acceleration is 8m/s2.
The acceleration in the block will be 4.59 m/s2
a catapult has a elastic so it can be pulled back and when u let go it the item in it will go far.the catapult uses tension to give it its power .when the tension on elastics it created by pulling back the lever. it is released by letting go and the object will fly
The resulting force when matter is pulled or stretched is called tension. It is a pulling force that occurs within the body of a material when it is subjected to external loading.