Class-I lever . . . may or may not do that, depending on how it's set up. Class-II lever . . . never does that. Class-III lever . . . always does that.
fd=MA
The MA would be 6cm because the formula to find the MA is input arm divided by output arm
yes
Distance decreases by the wheel barrow lever force must be increased.above doesn't make a lick of sense does it, move the fulcrum towards the load arm.
Move the fulcrum farther from the force and closer to the load.
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.
Class-I lever . . . may or may not do that, depending on how it's set up. Class-II lever . . . never does that. Class-III lever . . . always does that.
Move the fulcrum closer to the load.
fd=MA
The ideal MA is 47.
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 MA would be 6cm because the formula to find the MA is input arm divided by output arm
yes it does
you take the lever and turn it around and than the thingey ma bober should be done you take the lever and turn it around and than the thingey ma bober should be done
It is (distance from fulcrum to effort)/(distance from fulcrum to load).
increase the effort arm to 8 feet