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What is the mechanical advantage of a lever with an effort arm of 16cm an a resistance arm of 2cm?
The mechanical advantage of a lever is calculated by dividing the length of the effort arm by the length of the resistance arm. In this case, the mechanical advantage would be 16cm (effort arm) divided by 2cm (resistance arm), resulting in a mechanical advantage of 8.
What is the mechanical advantage of a lever with an effort arm of 12 feet resistance arm of 3 feet?
The mechanical advantage of a lever is calculated by dividing the length of the effort arm by the length of the resistance arm. In this case, the mechanical advantage would be 12 feet (effort arm) divided by 3 feet (resistance arm), which equals a mechanical advantage of 4.
What is the mechanical advantage of a lever with an effort alarm of 12 feet and a resistance arm of 3 feet?
The mechanical advantage of a lever is determined by the ratio of the effort arm to the resistance arm. In this case, the mechanical advantage would be 12 feet (effort arm) divided by 3 feet (resistance arm), resulting in a mechanical advantage of 4.
Which lever would have more mechanical advantage?
A longer lever would typically have more mechanical advantage than a shorter lever. Mechanical advantage is calculated by dividing the length of the effort arm by the length of the resistance arm; therefore, the longer the effort arm, the greater the mechanical advantage.
What is the mechanical advantage of a lever with a resistance arm of 1.5 feet and an effort arm of three feet?
The mechanical advantage of a lever is calculated by dividing the effort arm length by the resistance arm length. In this case, the mechanical advantage would be 2, as 3 feet (effort arm) divided by 1.5 feet (resistance arm) equals 2.
How is mechanical advantage calculated for levers?
The mechanical advantage of a lever is calculated by dividing the length of the lever arm on the effort side by the length of the lever arm on the resistance side. The formula for mechanical advantage is MA = Length of effort arm / Length of resistance arm. It represents the factor by which a lever multiplies the force applied to it.
How do you find the mechanical advantage of a wheelbarrow?
Mechanical advantage= effort arm length/ load arm length For Example Effort arm=120 cm Load arm length= 40 cm MA-120/40 = 3
A lever has an input arm 50 centimeters and an output arm 40 centimeters long what is the machanical advantage of the lever?
The mechanical advantage of a lever is calculated by dividing the length of the input arm by the length of the output arm. In this case, the mechanical advantage would be 50 cm (input arm) divided by 40 cm (output arm), which equals 1.25. Therefore, the mechanical advantage of the lever is 1.25.
What is the mechanical advantage of a lever that has an input arm of 3 meters and an output arm of 2 meters?
The mechanical advantage of a lever is calculated by dividing the length of the input arm by the length of the output arm. In this case, the mechanical advantage would be 3/2, which simplifies to 1.5. This means that for every 1 unit of effort applied to the input arm, the lever can lift 1.5 units on the output arm.
What is the mechanical advantage of a lever with an input arm of 5 m and an output arm of .5?
3
How can you increase the mechanical advantage of a lever?
Distance decreases by the wheel barrow lever force must be increased.above doesn't make a lick of sense does it, move the fulcrum towards the load arm.
Which lever would have more mechanical advantage than one with a resistance arm of 3 riches and an effort arm of 6 inches?
A lever with a resistance arm of 3 inches and an effort arm of 1 inch would have more mechanical advantage as the effort arm is shorter than the resistance arm, making it easier to lift the load.
