fd=MA
Mechanical Advantage is given by the following equation: MA = Load Effort On a class 2 lever, the fulcrum (pivot) is at one end of the lever and the work applied is at the other end. The load is then applied near the fulcrum, as common with the wheel barrow. A class 3 lever has the effort applied between the fulcrum and the resistance. Therefore, a much greater effort will be required to produce the same moment value. A typical C2 lever has a much greater distance in which to produce the load than a C3 lever.
The MA would be 6cm because the formula to find the MA is input arm divided by output arm
lifting heavy objects
Force, you get? Force = ma or mass x acceleration or your ma!
Class-III Lever . . . MA always less than 1. Class-II Lever. . . . MA always more than 1. Class-I Lever . . . . MA can be 1, more than 1, or less than 1.
It is (distance from fulcrum to effort)/(distance from fulcrum to load).
fd=MA
Mechanical advantage: Class-I lever . . . can be any positive number Class-II lever . . . always less than ' 1 ' (and more than zero) Class-III lever . . . always more than ' 1 '
The ideal MA is 47.
Move the fulcrum farther from the force and closer to the load.
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Mechanical Advantage is given by the following equation: MA = Load Effort On a class 2 lever, the fulcrum (pivot) is at one end of the lever and the work applied is at the other end. The load is then applied near the fulcrum, as common with the wheel barrow. A class 3 lever has the effort applied between the fulcrum and the resistance. Therefore, a much greater effort will be required to produce the same moment value. A typical C2 lever has a much greater distance in which to produce the load than a C3 lever.
Classical High School Springfield, MA Class of 1973
First Class Mail is delivered in three to five days.
First Class Mail is delivered in 3 to 5 days.
By first class mail, 1-3 days.