In this case, you simply multiply the force times the distance. This assumes the 15 Newtons are applied exactly in the direction of the movement; otherwise, you take the component in that direction. Result is in Newton-meter, also called Joule.
In this case, you simply multiply the force times the distance. This assumes the 15 Newtons are applied exactly in the direction of the movement; otherwise, you take the component in that direction. Result is in Newton-meter, also called Joule.
In this case, you simply multiply the force times the distance. This assumes the 15 Newtons are applied exactly in the direction of the movement; otherwise, you take the component in that direction. Result is in Newton-meter, also called Joule.
In this case, you simply multiply the force times the distance. This assumes the 15 Newtons are applied exactly in the direction of the movement; otherwise, you take the component in that direction. Result is in Newton-meter, also called Joule.
In this case, you simply multiply the force times the distance. This assumes the 15 Newtons are applied exactly in the direction of the movement; otherwise, you take the component in that direction. Result is in Newton-meter, also called Joule.
The work done can be calculated using the formula: work = force x distance. Therefore, the work done in this case would be 30N x 3M = 90 Joules.
A constant force of 100 N moving through 3 m performs 300 joules of work.
the answer is 300 j
90 j
90 Joules
In a machine with a mechanical advantage of 3, the output force is exerted over a shorter distance compared to the distance over which the input force is exerted. The output force is three times greater than the input force but is exerted over a third of the distance traveled by the input force due to the principle of work conservation.
velocity
The product of the input force and the distance through which it is exerted is called work. Work is a measure of energy transfer that occurs when a force moves an object over a distance in the same direction as the force. The formula for work is Work = Force x Distance.
When a machine shortens the distance over which a force is exerted, the size of the force must increase in order to conserve energy. This is governed by the principle of work-energy relationship, where the work done remains constant, and therefore, force and distance are inversely proportional in a simple machine.
When a force is exerted on an object causing it to move, work is done on the object. Work is defined as force acting over a distance in the direction of the force.
The work done is calculated as force multiplied by distance. Therefore, the work done when a 100N force is applied over 5m is 500 Joules (100N * 5m = 500J).
The work done is equal to the product of the force applied and the distance moved in the direction of the force. In this case, the work done would be 15 N * 6 m = 90 Joules.
a smaller force is exerted over a longer distance.
When a machine shortens the distance over which a force is exerted, the size of the force must increase in order to conserve energy. This is governed by the principle of work-energy relationship, where the work done remains constant, and therefore, force and distance are inversely proportional in a simple machine.
a smaller force is exerted over a longer distance
because you need the force to move it over some distance
because you need the force to move it over some distance
all forces are either a push or a pull. even over a distance. gravity is a pull and its opposing force, upthrust, is a push or for ipc its work
The output force exerted by a rake must be less than the input force due to energy conservation principles. Some of the input force is used to overcome friction and other resistive forces, resulting in a decrease in the output force available for actual work.
cheeseburger
Pressure
This is the definition of pressure. Pressure is measured in units of force per unit area, such as pounds per square inch (psi) or pascals (Pa). It quantifies how force is distributed over a given area.