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A stone block is pushed up a ramp that is 120m long and 20m high. what is the ideal mechanical advantage of the ramp?
Wiki User
β 7y ago
6
marquisedennis
The ideal mechanical advantage of a ramp is calculated by dividing the length of the ramp by the vertical height.
In this case, the ideal mechanical advantage of the ramp is 120m (length) divided by 20m (height) which equals 6.
Therefore, the ideal mechanical advantage of the ramp is 6.
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What is the relationship between the height of the ramp and it and its ideal mechanical advantage?
The ideal mechanical advantage of a ramp is directly related to the height of the ramp. The ideal mechanical advantage is calculated as the ratio of the length of the ramp to its vertical height. So, the higher the ramp, the greater the ideal mechanical advantage.
How does mechanical advantage differ from ideal mechanical advantage?
Mechanical advantage refers to the ratio of the output force to the input force in a machine. Ideal mechanical advantage is the theoretical mechanical advantage of a machine calculated by considering only the ideal conditions, such as no energy loss due to friction. In practical applications, actual mechanical advantage will be less than ideal mechanical advantage due to factors like friction and inefficiencies in the machine.
What kind of pulley has an ideal mechanical advantage of 2?
The kind of pulley has an ideal machanical advantage of 2 is called "Movable Pulley". From, Bryan Hollick
What is the formula for determine ideal mechanical advantage?
The formula for determining ideal mechanical advantage is: IMA = (effort distance / load distance) or IMA = (input force / output force).
What is the concept between mechanical advantage and ideal mechanical advantage?
Mechanical advantage is the ratio of the output force produced by a machine to the input force applied to it. Ideal mechanical advantage is the theoretical ratio of the output force to the input force, assuming no energy losses due to friction or other factors. In reality, actual mechanical advantage is always less than ideal mechanical advantage due to factors like friction and inefficiencies in the machine.
Is the ideal mechanical advantage of the ramp is it's mechanical advantage with friction?
No, the ideal is without friction.
How does mechanical advantage differ from ideal mechanical advantage?
Mechanical advantage refers to the ratio of the output force to the input force in a machine. Ideal mechanical advantage is the theoretical mechanical advantage of a machine calculated by considering only the ideal conditions, such as no energy loss due to friction. In practical applications, actual mechanical advantage will be less than ideal mechanical advantage due to factors like friction and inefficiencies in the machine.
What is true about the mechanical advantage of a machine?
it is less than the ideal mechanical advantage
What are some ideal mechanical advantage examples?
Mechanical Advantage = Effort/Load
What are units for Ideal Mechanical Advantage?
Ideal mechanical advantage is a numerical ratio. It's a naked number without a unit.
How does actual mechanical advantage compare with ideal mechanical advantage?
The actual mechanical advantage is usually less, due to losses.
What is the ideal mechanical advantage of a lever 7 meters long and 3 meters high?
The ideal mechanical advantage of the bar is 5.
What will lengthening a ramp do to its ideal mechanical advantage?
Increase the advantage.
What kind of pulley has an ideal mechanical advantage of 2?
The kind of pulley has an ideal machanical advantage of 2 is called "Movable Pulley". From, Bryan Hollick
What is the formula for determine ideal mechanical advantage?
The formula for determining ideal mechanical advantage is: IMA = (effort distance / load distance) or IMA = (input force / output force).
What is the concept between mechanical advantage and ideal mechanical advantage?
Mechanical advantage is the ratio of the output force produced by a machine to the input force applied to it. Ideal mechanical advantage is the theoretical ratio of the output force to the input force, assuming no energy losses due to friction or other factors. In reality, actual mechanical advantage is always less than ideal mechanical advantage due to factors like friction and inefficiencies in the machine.
How does increasing weight affect the ideal mechanical advantage?
The ideal mechanical advantage is determined by the shape, size, and configuration of the simple machine. The weight of the load, the size of the applied force, or the weight of the components or materials of the machine itself have no effect on the ideal mechanical advantage.
