Increasing the length of an inclined plane does not directly affect the work done. The work done on an object moved up an inclined plane is determined by the force applied over the vertical height, not the length of the plane. However, a longer inclined plane may require more time and energy to move an object along it, but the actual work done remains the same.
One way to increase the mechanical advantage of an inclined plane is to increase the length of the plane, which reduces the slope angle. Another way is to decrease the height of the plane relative to its length, which also reduces the slope angle.
An inclined plane can affect the speed of an object by decreasing it due to friction between the object and the surface of the inclined plane. The steeper the incline, the more the speed will be reduced. Additionally, the length of the inclined plane can influence the object's speed as it may take longer for the object to travel the length, thus affecting its overall speed.
Since the Mechanical Advantage of the inclined plane is inversely proportional to its height, increasing the height would lower your mechanical advantage and lowering the height would increase it.Alternately, mechanical advantage is directlyproportional to an inclined plane's length, therefore increasing the length would increase your mechanical advantage.
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
The mechanical advantage of an inclined plane is the ratio of the length of the inclined plane to the height it lifts a load. Since the length is always greater than the height (unless the inclined plane is vertical), the mechanical advantage is always at least 1.
One way to increase the mechanical advantage of an inclined plane is to increase the length of the plane, which reduces the slope angle. Another way is to decrease the height of the plane relative to its length, which also reduces the slope angle.
the formula for the mechanical advantage of an inclined plane is the length divide by the height.
it is due to the fact that the length of an inclined plane(effect arm) is greater than its vertical height(load arm).
An inclined plane can affect the speed of an object by decreasing it due to friction between the object and the surface of the inclined plane. The steeper the incline, the more the speed will be reduced. Additionally, the length of the inclined plane can influence the object's speed as it may take longer for the object to travel the length, thus affecting its overall speed.
Since the Mechanical Advantage of the inclined plane is inversely proportional to its height, increasing the height would lower your mechanical advantage and lowering the height would increase it.Alternately, mechanical advantage is directlyproportional to an inclined plane's length, therefore increasing the length would increase your mechanical advantage.
The slope of an inclined plane is found by dividing the rise of the plane by the run of the plane. also the ideal mechanical advantage.
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.
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
The mechanical advantage of an inclined plane is the ratio of the length of the inclined plane to the height it lifts a load. Since the length is always greater than the height (unless the inclined plane is vertical), the mechanical advantage is always at least 1.
The size of the ball. The weight of the ball. The angle of the inclinned plane. The length of the inclined plane
The ideal mechanical advantage of an inclined plane is the ratio of the length of the incline to the vertical rise. It is calculated by dividing the length of the ramp by the vertical height of the ramp.
Ideal Mechanical Advantage for an Inclined Plane is equal to the length of the incline divided by the height of the incline.