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Type your answer here... The actual mechanical advantage.
Mechanical Advantage = distance moved at input / distance moved at output
the equation of mechanical advantage isFout (force, output)divided byFin (force input)the equation for Ideal mechanical advantage isDin (distance, input)divided byDout (distance, output)hope this helps a bit
Mechanical Advantage: F(out)/ F(in) Actual Mechanical Advantage is the ratio of Force outputed to Force inputed. (AMA=Fo/Fi) Similarly, IMA (Ideal Mechanical Advantage) = di/do
MA= (force output)/ (force input)
Type your answer here... The actual mechanical advantage.
Mechanical Advantage = distance moved at input / distance moved at output
torque in * input rpm/output rpm = torque out
The equation for ideal mechanical advantage is: Output force/input force, Or input distance/ output distance.
From the design of the lever (on paper), the mechanical advantage is effort arm/load arm which means Distance from pivot to the applied force/distance from pivot to the load The result of that is that the forces will have the reciprocal ratio, and the input force to the lever will be the output force/the Mechanical Advantage .
Distance input = Mech Adv/Distance output
Actual Mech. Advantage
Distance moved by input force / distance moved by output force
the equation of mechanical advantage isFout (force, output)divided byFin (force input)the equation for Ideal mechanical advantage isDin (distance, input)divided byDout (distance, output)hope this helps a bit
Mechanical Advantage: F(out)/ F(in) Actual Mechanical Advantage is the ratio of Force outputed to Force inputed. (AMA=Fo/Fi) Similarly, IMA (Ideal Mechanical Advantage) = di/do
Whatever output force is required, you can divide it by the "mechanical advantage" to calculate the input force.
MA= (force output)/ (force input)