0
What else can I help you with?
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 would be the ideal mechanical advantage of the lever if the fulcrum 2m to the right?
The ideal mechanical advantage of a lever is calculated by dividing the distance from the input force to the fulcrum by the distance from the output force to the fulcrum. In this case, with the fulcrum 2m to the right, the mechanical advantage would be different for different positions along the lever.
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 would increase the mechanical advantage of a second class lever?
Increasing the distance between the pivot point and the effort force, or decreasing the distance between the pivot point and the load, could increase the mechanical advantage of a second-class lever. Additionally, using a longer lever arm can also increase the mechanical advantage.
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 would be the ideal mechanical advantage of the lever if the fulcrum 2m to the right?
The ideal mechanical advantage of a lever is calculated by dividing the distance from the input force to the fulcrum by the distance from the output force to the fulcrum. In this case, with the fulcrum 2m to the right, the mechanical advantage would be different for different positions along the lever.
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 would increase the mechanical advantage of a second class lever?
Increasing the distance between the pivot point and the effort force, or decreasing the distance between the pivot point and the load, could increase the mechanical advantage of a second-class lever. Additionally, using a longer lever arm can also increase the mechanical advantage.
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.
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 lever would have more mechanical advantage than one with a resistance are of 3 inches and an effort arm of 6 inches?
A lever with a longer effort arm and a shorter resistance arm would have more mechanical advantage. In this case, if you increase the effort arm to 7 inches while keeping the resistance arm at 3 inches, the mechanical advantage would increase. This is because a longer effort arm allows for less force to be applied to overcome a greater resistance.
If A lever is used to lift a heavy rock the mechanical advantage of the lever is 4 and the lever applies a force of 800n to the rock what is the force applied to the lever?
The force applied to the lever can be found by dividing the force exerted on the rock by the mechanical advantage of the lever. In this case, the force applied to the lever would be 200 N (800 N / 4).
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.
Calculate the mechanical advantage of a lever where 5 N of input force is needed to move a 10 N box using that lever.?
The mechanical advantage of the lever is calculated by dividing the output force by the input force. In this case, the output force is 10 N and the input force is 5 N, so the mechanical advantage would be 10 N / 5 N = 2. This means that the lever provides a mechanical advantage of 2, making it easier to lift the box.
What is the mechanical advantage of a first-class lever in which the fulcrum is 10 inches from the resistance and 40 inches from the effort?
answer is 4
What benefit is provided by a lever that operates at a mechanical advantage?
A lever operating at a mechanical advantage allows you to apply less force to lift or move a heavier object. This makes it easier to perform tasks that would otherwise require more strength.
