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).
Wiki User
∙ 13y agoWiki User
∙ 13y agoMovable PULLEYS: it is the # of ropes supporting the load
Block and Tackle PULLEYS: it is the # of ropes supporting the load
fixed PULLEYS: MA=1
Wiki User
∙ 9y agoIdeal M.A. = (length of the effort arm) divided by (length of the load arm)
you have to multiply the individual mechanical advantages of all the simple machines that make up the compound 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).
If you get more force out of a machine than what was put into it, that is mechanical advantage. Levers and gears use this principal to amplify their output.
I believe a bridge should be considered a simple machine. It saves work and gives mechanical advantage. It can also shorten distance, so unlike an inclined plane it can benefit without increasing distance. It can bypass the need to raise and lower massess into crevasses, it can bypass long journeys down then back up a hill. I could find no discussion anywhere.
we find mechanical advantage of pulley by using principle of lever. according to this moment of effort is equal to moment of moment of load. As in this case effort arm is equal to load arm. so mechanical advantage is equal to one. but we know we can never finish friction between rope used and pulley so mechanical advantage is less than one
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.
you have to multiply the individual mechanical advantages of all the simple machines that make up the compound machine.
you have to multiply the individual mechanical advantages of all the simple machines that make up the compound machine.
you have to multiply the individual mechanical advantages of all the simple machines that make up the compound 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).
The mechanical advantage that a machine would have without friction or in another term is that you can find the IDEAL MECHANICAL ADVANTAGE (IMA) OF A MACHINE IS BY HAVING A MACHINE WITH NO FRICTION, ALSO BY MULTIPLYING YOUR EFFORT FORCE BY 2, HOWEVER BECAUSE OF FRICTION AND THE WEIGHT THE ACTUAL MA WILL BE LESS.
if you really want to know the answer go to the restroom and shove your hand as far as you can in your anus and you might find it.
To find the mechanical advantage for a simple machine like a lever, you would divide the length of the effort arm by the length of the load arm. In this case, the mechanical advantage for a lever with a 5 cm effort arm and a 10 cm load arm would be 5/10 = 0.5, indicating the machine can multiply the input force by 0.5.
The mechanical advantage is 5. This means that for every 1 N of force you exert, the machine will output 5 N of force.
Effort force can be found by dividing the load force by the mechanical advantage of the system. The mechanical advantage is the ratio of the load force to the effort force in a simple machine. Alternatively, effort force can be calculated using the formula Effort Force = Load Force / Mechanical Advantage.
Output force can be found by multiplying the input force by the mechanical advantage of a machine. The mechanical advantage is the factor by which a machine multiplies the input force to generate the output force. The formula for calculating mechanical advantage is output force/input force.
The mechanical advantage would be 5, calculated as the output force (200 N) divided by the input force (40 N). This means that the machine amplifies the input force by a factor of 5.