That's exactly what levers and inclined planes do. But remember . . . you don't get
something for nothing.
The force can be multiplied, but the distance it acts through is divided just as much,
So (force) times (distance) doesn't change from the input to the output. That quantity
is called "energy", and the simple machine can't add any more to your energy.
A Machine is something that helps do work. Work, in mechanics, is the amount of energy output over a distance. A force is what does the work, so a force acting over a distance does work...which is what machines help do. Further, the amount of time that a force takes to do work will determine the POWER output.
If a simple machine provide an increased output force, then the the distance from the load to the pivot needs to be increased.
Every real machine is subject to forces that reduce output. These include actual forces such as friction, or human controlled forces such as imperfect machining. This reduces the output to less than the ideal.
Machines can exert both pushing and pulling forces depending on their design and intended function. The ability to apply forces in different directions is essential for various mechanical applications. Pushing: Machines can exert a pushing force to move objects away from their point of application. For instance, a hydraulic press applies force to compress materials, or a bulldozer pushes soil or debris forward. Pulling: Machines can also exert a pulling force to move objects towards their point of application. A winch pulling a heavy load, or a tractor pulling a trailer are common examples of machines using pulling forces.
it is
A Machine is something that helps do work. Work, in mechanics, is the amount of energy output over a distance. A force is what does the work, so a force acting over a distance does work...which is what machines help do. Further, the amount of time that a force takes to do work will determine the POWER output.
If a simple machine provide an increased output force, then the the distance from the load to the pivot needs to be increased.
if one answer is 6 and the other answer is 7, how do the output numbers from the input/output machines compare
Multiply by 5 and add 20 (or equivalently, add 4 and then multiply by 5)
Based on what? - If the input is 50 W, the output will be 50 W, it's as simple as that. Or a little less, since real machines are not 100% efficient. No complicated software is required. However, you can't know the exact power output, until you assume some value for an efficiency. If, in the above example, you assume a 90% efficiency, you multiply the 50 W by 0.90.Based on what? - If the input is 50 W, the output will be 50 W, it's as simple as that. Or a little less, since real machines are not 100% efficient. No complicated software is required. However, you can't know the exact power output, until you assume some value for an efficiency. If, in the above example, you assume a 90% efficiency, you multiply the 50 W by 0.90.Based on what? - If the input is 50 W, the output will be 50 W, it's as simple as that. Or a little less, since real machines are not 100% efficient. No complicated software is required. However, you can't know the exact power output, until you assume some value for an efficiency. If, in the above example, you assume a 90% efficiency, you multiply the 50 W by 0.90.Based on what? - If the input is 50 W, the output will be 50 W, it's as simple as that. Or a little less, since real machines are not 100% efficient. No complicated software is required. However, you can't know the exact power output, until you assume some value for an efficiency. If, in the above example, you assume a 90% efficiency, you multiply the 50 W by 0.90.
OUTPUT is Fulfillment of objective of maintenance like ensuring availability of machines and reducing downtime
Every real machine is subject to forces that reduce output. These include actual forces such as friction, or human controlled forces such as imperfect machining. This reduces the output to less than the ideal.
increased
Increased and overly concentrated.
Every real machine is subject to forces that reduce output. These include actual forces such as friction, or human controlled forces such as imperfect machining. This reduces the output to less than the ideal.
Every real machine is subject to forces that reduce output. These include actual forces such as friction, or human controlled forces such as imperfect machining. This reduces the output to less than the ideal.
Machines can exert both pushing and pulling forces depending on their design and intended function. The ability to apply forces in different directions is essential for various mechanical applications. Pushing: Machines can exert a pushing force to move objects away from their point of application. For instance, a hydraulic press applies force to compress materials, or a bulldozer pushes soil or debris forward. Pulling: Machines can also exert a pulling force to move objects towards their point of application. A winch pulling a heavy load, or a tractor pulling a trailer are common examples of machines using pulling forces.