Output force is never greater than input force. There are losses associated with any system, and we have not found a way to get more out of a "thing" or "machine" or any other system than we put in.
With a lever, you can have a small input force, and on the other end, you can have a larger output force - or you can do it the other way. Quite often, however, the whole idea of such a lever is to be able to apply more force than we can manage with our weak muscles. But when you use a lever in the conventional way, you have to apply a force through a considerable distance to get the "concentrated" force at the other end.
Just divide the output force by the input force.Just divide the output force by the input force.Just divide the output force by the input force.Just divide the output force by the input force.
In a closed system in the "real world" in which we live, there are losses associated with friction and other actions. These forces "take energy" from the system between its input and output. When we apply force to the imput of a system, some is lost as the force is transferred through that system. That means that the output force we observe will always be a bit less than the input force. A transmission in a vehicle is a classic example of the idea that there are losses between the input and the output of a system. The input from the engine will always be a bit greater than the output at the tailshaft (or axles for a transaxle) due to losses within the transmission.
Input and output are shown on a force diagram by the human being the input force and the load force being the output force. When you divide output force by input force, you get the mechanical advantage of a lever.
Because the output distance is always greaterthan the input distance,and the product of (force) x (distance) is nearly the same on both ends.
Because the output distance is always greaterthan the input distance,and the product of (force) x (distance) is nearly the same on both ends.
Just divide the output force by the input force.Just divide the output force by the input force.Just divide the output force by the input force.Just divide the output force by the input force.
In a closed system in the "real world" in which we live, there are losses associated with friction and other actions. These forces "take energy" from the system between its input and output. When we apply force to the imput of a system, some is lost as the force is transferred through that system. That means that the output force we observe will always be a bit less than the input force. A transmission in a vehicle is a classic example of the idea that there are losses between the input and the output of a system. The input from the engine will always be a bit greater than the output at the tailshaft (or axles for a transaxle) due to losses within the transmission.
An output force is the force that is exerted from the input force to create motion of the resisting object. the input force can be less or more then the output force
Because the output distance is always greaterthan the input distance,and the product of (force) x (distance) is nearly the same on both ends.
Input and output are shown on a force diagram by the human being the input force and the load force being the output force. When you divide output force by input force, you get the mechanical advantage of a lever.
Input and output are shown on a force diagram by the human being the input force and the load force being the output force. When you divide output force by input force, you get the mechanical advantage of a lever.
An output force is the force that is exerted from the input force to create motion of the resisting object. the input force can be less or more then the output force
The difference between and input force and an output force is that an output force is force exerted by a machine, and an input force is force exerted on a machine.
Because the output distance is always greaterthan the input distance,and the product of (force) x (distance) is nearly the same on both ends.
Because the output distance is always greaterthan the input distance,and the product of (force) x (distance) is nearly the same on both ends.
Mechanical Advantage which is the output force divided by the input force.
Yes.