This will occur if the fulcrum is closer to the load than the effort.
The load is the weight and the effort is the movment. The effort is the force applied, and load divided by effort is mechanical advantage.
efficiency=mechanical advantage/velocity ratio mechanical advantage=load/effort use this formula, ans:100N
The effort required is directly proportional to the sine of the angle of inclination.Since the sine of an angle increases with increase in angle, therefore the effort required also increases.
chickjenww
This will occur if the fulcrum is closer to the load than the effort.
A relationship between two of it are when load come closer to fulcrum, you need more effort to use. But if load go far away from the fulcrum, you need less effort to use. A relationship between two of it are when load come closer to fulcrum, you need more effort to use. But if load go far away from the fulcrum, you need less effort to use.
No, the function of the fulcrum remains the same The only change would be the ratio of force to load The closer the fulcrum is the the load, the less force required to lift it The farther away the fulcrum is from the load, the more force required to lift it
efficiency=mechanical advantage/velocity ratio mechanical advantage=load/effort use this formula, ans:100N
The load is the weight and the effort is the movment. The effort is the force applied, and load divided by effort is mechanical advantage.
The effort required is directly proportional to the sine of the angle of inclination.Since the sine of an angle increases with increase in angle, therefore the effort required also increases.
Mechanical disadvantage occurs if the load distance is greater than the effort distance, then the effort required is more than the load being moved. It is also known as a 'negative mechanical advantage'.
It rotates freely until it is required to do work. As soon as a load is placed across the output more effort will be required to rotate the Dynamo.
load arm, effort arm, load, effort, fulcrum!
Effort load is how much force it takes to lift and object. You can measure effort force with a spring scale.
The magnitude of the effort is controlled by you, not by the distance of the load from the fulcrum. Moving the load farther away from the fulcrum has no effect on the effort. But if you want to leave the effort where it is and still lift the load with the lever, then you're going to have to increase the effort.
The fulcrum is between the effort and the load.