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To find the output force of a wheel and axle, you can use the formula: Output Force = Input Force * (Radius of Wheel / Radius of Axle). The output force is determined by the ratio of the radii of the wheel and axle, with the input force determining the overall scaling factor.
let the input force be F1,and the distance between point of application of input force and the lever point is x1,similarly if output force iis F2,and distance of it's point of apllication is x2,then efficiency of the lever is (F2*x2)/(F1*x1) actually F*x gives the work done,and efficiency of any machine is output work/input work
Find the radius of the larger wheel.Find the radius of the axle.Divide the radius of the large wheel by the radius of the axle to find the mechanical advantage. MA =r (large wheel )/ r (axle)
All machines lose some of the input force applied to them as a result of friction and other forces. The efficiency of a machine refers to how much of the input work is converted to output work by the machine. You can find the efficiency of a machine by dividing the output work by the input work. Because the output work will always be smaller than input work, efficiency will always fall somewhere between 0 and 1, with 1 being a machine that has as much output as input work (not possible in the real world) and 0 being a machine that is totally useless because none of the input work is converted to output work.
The mechanical advantage is 5.Mechanical Advantage = Output Force/Input Force
To find the output force of a wheel and axle, you can use the formula: Output Force = Input Force * (Radius of Wheel / Radius of Axle). The output force is determined by the ratio of the radii of the wheel and axle, with the input force determining the overall scaling factor.
mechanical advantage= output force over input force
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Multiply (the input force) x (the lever's mechanical advantage).
let the input force be F1,and the distance between point of application of input force and the lever point is x1,similarly if output force iis F2,and distance of it's point of apllication is x2,then efficiency of the lever is (F2*x2)/(F1*x1) actually F*x gives the work done,and efficiency of any machine is output work/input work
The system is 100% efficient. Step 1: Find out Mechanical Advantage so that you can find out input force MA = input distance/output distance = 2.5m / 4.5 m = 0.5555555 Step 2: Find input force AMA = output force / input force 0.5555555 = 250 N / input force input force = 250 N/ 0.5555555 input force = 450 N Step 3: Solve for mechanical efficiency ME = ((output force x output distance) / (input force x input distance)) x 100% = ((250 N x 4.5 m) / (450 N x 2.5 m)) x 100% = (1125 Nm / 1125 Nm) x 100% = 1 x 100% = 100% *** MA = Mechanical Advantage *** AMA = Actual Mechanical Advantage *** ME = Mechanical Efficiency
To find the mechanical advantage of a simple machine divide output force by input force. (input force is the force that we exert on a machine, and output force is the force that is exerted by a machine).
To find the mechanical advantage of a simple machine divide output force by input force. (input force is the force that we exert on a machine, and output force is the force that is exerted by a machine).
Find the radius of the larger wheel.Find the radius of the axle.Divide the radius of the large wheel by the radius of the axle to find the mechanical advantage. MA =r (large wheel )/ r (axle)
I'm not sure how to tell you how to find the output force of an object, any suggestions?
how would you find a input output machine pattern fast so a shortcut or trick!!
The "Ideal Mechanical Advantage" of a simple machine isIMA = output force /input force . To find the 'actual' or real-world mechanical advantage,multiply the IMA by the machine's efficiency.