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The closer the load is to the fulcrum the greater the mechanical advantage. The closer to the fulcrum, the less the load moves when the lever is used.
You get greater mechanical advantage the closer the fulcrum is to the resistance (load).
the one with the fulcrum closer to the weight you needed to lift
Move the fulcrum (pivot) farther from the effort and closer to the load.
The mechanical advantage is when the fulcrum is closer to the effort and creates a advantage
The mechanical advantage is when the fulcrum is closer to the effort and creates a advantage
The closer the load is to the fulcrum the greater the mechanical advantage. The closer to the fulcrum, the less the load moves when the lever is used.
You get greater mechanical advantage the closer the fulcrum is to the resistance (load).
The mechanical advantage is when the fulcrum is closer to the effort and creates a advantage
the one with the fulcrum closer to the weight you needed to lift
Move the fulcrum (pivot) farther from the effort and closer to the load.
The mechanical advantage is when the fulcrum is closer to the effort and creates a advantage
The lever? There are probably other names for it, but i was always taught the fulcrum, lever, and load. Load closer to fulcrum, easier to lift load. (longer lever= mechanical advantage) This would fall under simple machines in science class.
Too help the fulcrum get closer to the load
A lever's mechanical advantage is the ratio of the effort arm to the load arm. The shorter the load arm, the greater the lifting power, so the closer the fulcrum is to the object being lifted, the better.
When the pivot point (fulcrum) is moved farther from the effort and closer to the resistance.
More strength is required when the fulcrum is closer to you.