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It decreasesThe greater the angle, the steeper the inclination, the less effective it is. The greater the horizontal distance traveled for every unit length of height gained, the greater the mechanical advantage. GO Michael cooper repersentin Monticello
it really depends on the machine you are talking about. there are 6 simple machines: the lever, wheel and axle, pulley, inclined plane, wedge, and the screw. Lever = (distance from fulcrum to effort) divided by (distance from fulcrum to resistance) Wheel and Axle = (diameter of the wheel) divided by (diameter of the axle) Pulleys = the # of pulleys used Inclined Plane and Wedge = (length of slope) divided by (height) Screw = (circumference) divided by (pitch) Hope this helped :)
When the output is less than the input. Mechanical advantage is expressed as the ratio of the output to the input.
The actual mechanical advantage is usually less, due to losses.
The mechanical advantage is less than that given by a formula due to additional outside forces. This can include things like temperature which are difficult to predict or incorporate.
The mechanical advantage of an inclined plane is equal to length divided by height (l/h). Therefore, if the length is less than than the height, the mechanical advantage would be less than one.
Lesser the height of inclined plane, and more the length of it, More will be the mechanical advantage of inclined plane i.e less effort would be applied.
The mechanical advantage of an inclined plane is the ratio of its length to the height of its lift. At 45 degrees, this ratio is equal to one. Less than 45 degrees and it is greater than one, more than 45 degrees, and it it less than one. So the answer is yes.
It decreasesThe greater the angle, the steeper the inclination, the less effective it is. The greater the horizontal distance traveled for every unit length of height gained, the greater the mechanical advantage. GO Michael cooper repersentin Monticello
This is because the actual mechanical advantage is the actual calculation found after dividing the effort force by the output force. Ideal mechanical advantage is what many people would call an estimate. When estimating mechanical advantage, the numbers are always rounded. This makes actual mechanical advantage less. Sources: Science teacher
No. The slope would have to be shorter than the height.
For example: think of the inclined plane- The advantage of gaining force is offset by the disadvantage of losing distance. So, that means... The longer the inclined plane is, the less steep it has to be and the less force a load needs to have exerted on it to move. :) Hope that answers your question. :)
it really depends on the machine you are talking about. there are 6 simple machines: the lever, wheel and axle, pulley, inclined plane, wedge, and the screw. Lever = (distance from fulcrum to effort) divided by (distance from fulcrum to resistance) Wheel and Axle = (diameter of the wheel) divided by (diameter of the axle) Pulleys = the # of pulleys used Inclined Plane and Wedge = (length of slope) divided by (height) Screw = (circumference) divided by (pitch) Hope this helped :)
An inclined plane allows an object to be lifted through a vertical distance using less force than is required to lift the object straight up. The shallower the angle of the inclined plane, the less force is required to raise the object. The inclined plane is a very simple machine that offers a mechanical advantage. Although the force needed to raise the object is reduced, the force needs to move through a longer distance. Therefore, it takes the same amount of energy to raise the object . In fact, as there is always an amount of friction, it will actually take more energy to lift that simply lifting it straight up. The most common example of an inclined plane is a ramp used to raise vehicles to a higher level.
The inclined plane is a simple machine because it can be used to use less force.
it is less than the ideal mechanical advantage
The actual mechanical advantage is usually less, due to losses.