it is the distance of force
A single fixed pulley provides a mechanical advantage of 1, meaning the distance the effort rope must move is equal to the distance the resistance is raised. Therefore, the effort rope must move 4 meters to raise the resistance 4 meters when using a single fixed pulley.
Other way to say effort force Force = Kilograms * meters / (second squared) in other words mass times acceleration.
You could halve the effort required by moving the load closer to the fulcrum. Placing the load 0.5 meters from the fulcrum would reduce the effort needed to lift it. This is based on the principle of a lever, where the effort needed is inversely proportional to the distance of the load from the fulcrum.
You would have traveled a total distance of 65 meters (100 meters forward - 35 meters back).
The total displacement of the ball is the difference between the uphill distance (5 meters) and the downhill distance (9 meters), as displacement considers the final position relative to the initial position. Therefore, the displacement of the ball is 9 meters (downhill distance) - 5 meters (uphill distance) = 4 meters.
A single fixed pulley provides a mechanical advantage of 1, meaning the distance the effort rope must move is equal to the distance the resistance is raised. Therefore, the effort rope must move 4 meters to raise the resistance 4 meters when using a single fixed pulley.
Distance * Weight (in Newton meters)
If air resistance can be ignored, the distance in meters is 4.9t2. Note that 4.9 is half the numerical value of Earth's acceleration (9.8 meters per second square).
15% incline means that every 100 meters horizontally, you have 15 meters vertically. Take a scientific calculator - you can use the one that comes with Windows - and calculate tan(15). Then you can compare. (Make sure the angular measurement is in degrees. As a verification, cos(90) should give you zero.)
Other way to say effort force Force = Kilograms * meters / (second squared) in other words mass times acceleration.
19 meters or 60 something feet
The distance of 20 meters is the same as the distance of 65.6 ft or 787.4 inches.
faggio
You could halve the effort required by moving the load closer to the fulcrum. Placing the load 0.5 meters from the fulcrum would reduce the effort needed to lift it. This is based on the principle of a lever, where the effort needed is inversely proportional to the distance of the load from the fulcrum.
A distance of 3.2 kilometers = 3,200 meters
The distance from the sun is 150E9 meters, 150 Giga meters.
45 feet = 13.72 meters