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∙ 11y agoYes, the force applied is calculated by multiplying the force by the distance from the fulcrum. In this case, the torque applied would be 18 Nm (9 N * 2 m). Whether it is enough to lift the weight depends on the weight and the distance from the fulcrum at which it is placed.
Assuming the fulcrum is at the center, the weight would be lifted if the clockwise torque (force x distance) applied by the 9-N force is greater than the counterclockwise torque of the weight. If the weight is closer to the fulcrum, it may not be lifted, even with a 9-N force.
In a lever, the force applied is inversely proportional to the distance from the fulcrum. This means that the farther away the force is applied from the fulcrum, the less force is needed to lift the load. This relationship is governed by the principle of torque, where force is multiplied by distance.
Yes, the position of the fulcrum affects the force required to lift a weight. Placing the fulcrum closer to the load reduces the effort needed to lift the weight. Conversely, placing the fulcrum further from the load increases the force needed to lift the weight.
The fixed point of a lever is called a fulcrum. It is the point around which the lever rotates when a force is applied.
The distance from the applied force to the fulcrum is called the effort arm or lever arm. It is the perpendicular distance between the line of action of the force and the fulcrum in a lever system. The length of the effort arm affects the mechanical advantage of the lever.
Assuming the fulcrum is at the center, the weight would be lifted if the clockwise torque (force x distance) applied by the 9-N force is greater than the counterclockwise torque of the weight. If the weight is closer to the fulcrum, it may not be lifted, even with a 9-N force.
A 9-N force cannot be applied 2 m from the fulcrum lift the weight because it wouldn't balance
No sweat. Piece o' cake. Bring it on! What's a "nine meter force" ? ?
The input force or the effort on a pair of scissors would be the force applied by your hands on the handles. The output force or load would be the blades of the pair of scissors.
Yes, it can lift the weight if the weight is less than 9-N. This is because the force applied at a distance from the fulcrum creates a torque, and if the torque due to the force is greater than the torque due to the weight, the weight can be lifted.
In a lever, the force applied is inversely proportional to the distance from the fulcrum. This means that the farther away the force is applied from the fulcrum, the less force is needed to lift the load. This relationship is governed by the principle of torque, where force is multiplied by distance.
Yes, the position of the fulcrum affects the force required to lift a weight. Placing the fulcrum closer to the load reduces the effort needed to lift the weight. Conversely, placing the fulcrum further from the load increases the force needed to lift the weight.
The effort force is applied at the handle of the shovel. The fulcrum is where your other hand goes, lower down the shaft, and the fulcrum resistance would be where the load goes on the shovel, I.E the flat bit that you hit people with!
Fulcrum
The distance from the applied force to the fulcrum is called the effort arm or lever arm. It is the perpendicular distance between the line of action of the force and the fulcrum in a lever system. The length of the effort arm affects the mechanical advantage of the lever.
The fixed point of a lever is called a fulcrum. It is the point around which the lever rotates when a force is applied.
A fulcrum is a point around which a lever pivots, allowing for the applied force to be amplified or redirected. It is used in tools like seesaws, wheelbarrows, and scissors to make work easier by leveraging the force applied.