Wiki User
∙ 13y agothe weight is put on the angle of the lever not the small force pushing it down
Wiki User
∙ 13y agoA lever relies on the principle of torque, where the product of force and distance from the pivot point must be equal on both sides to achieve balance. By increasing the distance from the fulcrum, a smaller force can counteract a larger force on the other side of the lever. This relationship allows for mechanical advantage and force multiplication.
The fixed balance point on a lever is called the fulcrum. It is the point at which the lever pivots or rotates when a force is applied to either side of the lever. The position of the fulcrum determines how the lever amplifies or redirects the force applied to it.
The resistance force on a lever opposes the effort force applied to the lever, making it more difficult to move or lift an object. The resistance force helps balance the lever and determine the resulting mechanical advantage.
A large force can produce a small or zero torque if the force is applied at a point where the lever arm (distance from the point of rotation to the line of action of the force) is very small or zero. Torque is calculated as force multiplied by lever arm, so a small lever arm can result in a small or zero torque even with a large force.
Yes, a beam balance is a first class lever. In a first class lever, the fulcrum is located between the effort (input force) and the load (output force), like in the case of a beam balance where the fulcrum is in the middle.
A spring balance is a type of class 2 lever. In this lever system, the fulcrum (pivot point) is at one end, the input force is applied in the middle, and the output force is at the other end. When weighing an object using a spring balance, the object exerts a downward force on the spring, causing it to stretch and give a reading.
The fixed balance point on a lever is called the fulcrum. It is the point at which the lever pivots or rotates when a force is applied to either side of the lever. The position of the fulcrum determines how the lever amplifies or redirects the force applied to it.
The resistance force on a lever opposes the effort force applied to the lever, making it more difficult to move or lift an object. The resistance force helps balance the lever and determine the resulting mechanical advantage.
A large force can produce a small or zero torque if the force is applied at a point where the lever arm (distance from the point of rotation to the line of action of the force) is very small or zero. Torque is calculated as force multiplied by lever arm, so a small lever arm can result in a small or zero torque even with a large force.
Yes, a beam balance is a first class lever. In a first class lever, the fulcrum is located between the effort (input force) and the load (output force), like in the case of a beam balance where the fulcrum is in the middle.
A spring balance is a type of class 2 lever. In this lever system, the fulcrum (pivot point) is at one end, the input force is applied in the middle, and the output force is at the other end. When weighing an object using a spring balance, the object exerts a downward force on the spring, causing it to stretch and give a reading.
A balance is a first-class lever, where the fulcrum is located between the effort (force applied) and the load (object being weighed).
A large force produces a small torque when it is applied close to the axis of rotation, resulting in a smaller lever arm. Conversely, a small force can produce a large torque when applied farther from the axis of rotation, creating a larger lever arm which amplifies the effect of the force. This relationship is described by the equation torque = force x lever arm, so increasing the lever arm can compensate for a smaller force to generate a larger torque.
It applies a small amount of force to produce a large amount of force.
A lever can generate a large force by using a smaller input force applied over a longer distance to lift a heavier load over a shorter distance. This is made possible by the principle of mechanical advantage, where the lever's design multiplies the input force to produce a greater output force.
The distance from the fulcrum to the resistance force in a lever is called the load arm or effort arm. This measurement helps determine the mechanical advantage of the lever system and how much force is needed to balance or move a load.
A lever can be used for both pulling and pushing. By applying a force at one end of the lever, it is possible to either push or pull, depending on the direction of the force applied.
A class 1 lever is typically used in a beam balance. In this type of lever, the fulcrum is located between the effort (applied force) and the load (object being weighed). This arrangement allows for precise and accurate measurement of weight.