Calculate torques, mechanical advantage, balance conditions, and required forces for first, second, and third class levers around a fulcrum.
The lever is one of the six classical simple machines and among the most intuitive: apply a force at a distance from a pivot point (the fulcrum) to move a load on the other side. Despite its simplicity the lever underlies countless tools — from crowbars and scissors to your own forearm.
This Fulcrum & Lever Calculator lets you explore the physics of all three classes of levers. Enter the masses (or forces) on each side and their distances from the fulcrum, then instantly see the torques, net balance, mechanical advantage, and the reaction force the fulcrum must withstand. You can also solve for the required distance or mass to achieve balance.
Whether you are a student learning about rotational equilibrium, an engineer designing a mechanical linkage, or just curious about why a seesaw works, this tool provides clear outputs with explanations. Preset buttons cover classic examples: seesaws, wheelbarrows, crowbars, and nutcrackers. A reference table summarizes the three lever classes with everyday examples.
Use this calculator to solve lever-balance problems quickly, check torque on each side of a pivot, and see how moving the fulcrum or the load changes mechanical advantage. It is useful for both classroom equilibrium problems and quick mechanism checks where a small distance change matters. That makes it easier to test a lever idea before sketching a fuller mechanism.
Torque: τ = F × d = m × g × d Balance condition: τ₁ = τ₂ → m₁ × d₁ = m₂ × d₂ Mechanical Advantage: MA = d₁ / d₂ Fulcrum Reaction Force: F_fulcrum = F₁ + F₂
Result: Torque 1 = 294.2 N·m, Torque 2 = 294.2 N·m, Balanced ✓, MA = 1.5
20 kg at 1.5 m balances 30 kg at 1.0 m because both torques equal 294.2 N·m. The mechanical advantage is 1.5.
A lever balances when clockwise torque equals counterclockwise torque about the fulcrum. The important quantity is not just force or mass by itself, but force multiplied by distance from the pivot.
First-class levers trade force and distance around a pivot between the load and effort. Second-class levers put the load in the middle and usually give mechanical advantage. Third-class levers put the effort in the middle and usually favor speed or range of motion instead of force multiplication.
The most common mistakes are measuring the wrong distance, forgetting to convert mass to force when needed, and assuming a balanced lever means the pivot force is zero. Even when torques balance, the fulcrum still carries the combined load.
It is the pivot point about which a lever rotates. Moving the fulcrum changes the torque balance and therefore the mechanical advantage of the lever.
1st class: fulcrum between load and effort, as in a seesaw. 2nd class: load between fulcrum and effort, as in a wheelbarrow. 3rd class: effort between fulcrum and load, as in tweezers. The class tells you where the pivot, load, and applied force sit relative to one another.
The ratio of effort arm to load arm. MA greater than 1 means the lever multiplies force, while MA less than 1 favors speed or motion range instead.
No. A lever trades force for distance or distance for force, but it does not create energy. In an ideal lever, the work on both sides balances once losses are ignored.
The upward force the fulcrum exerts to support both loads. By Newton's third law it balances the downward loads even when the torques themselves cancel.
Move the heavier side closer to the pivot or the lighter side farther away until the torques match on both sides. The goal is not equal distance, but equal torque about the fulcrum.