A ramp exerts no force, just gravity.
It is an example of momentum (sometimes called "inertia"). Velocity x mass. The bowling ball is much, much heavier. With both rolling at the same speed, the bowling ball is harder to stop because it has much more mass.
It's a rubbery ball that bounces up when thrown, with force, down on a hard, supportable surface. Much like a basketball.
While the ball does exert a force on Earth according to Newton's third law of motion, the force exerted by the ball on Earth is much smaller compared to the force exerted by Earth on the ball due to Earth's much larger mass. This makes the effect of the ball's force on Earth negligible in comparison.
The weight of a ball affects how much force is needed to overcome inertia and start rolling, as well as how easily it can maintain momentum. Heavier balls require more force to start rolling but can maintain momentum better on flat surfaces. Lighter balls are easier to get moving but may not travel as far due to being more easily affected by external factors such as wind or surface imperfections.
Doc. Newton tells us in his second law thatF=maor force equals mass times acceleration where the mass is Kilograms, the acceleration is meters/second and force is in Newtons.Measure the mass of the soccerball, guestimate the acceleration of the ball (change in speed divided by the elapsed time) and multiply them. Bingo, force.
According to Newton's third law of motion, the force exerted by the ball on the bat would be equivalent to the force exerted by the bat on the ball. Therefore, if the bat hits the ball with 1000 N of force, the ball would also hit back on the bat with 1000 N of force.
Since F= ma the much lighter tennis ball would receive much more acceleration and ,consequently, roll much farther, how far depend on the rolling surface. If they received the same initial velocity, they theoretically would roll the same distance bu it would again depend on the surface.
The height of ball will depend on how much force is used to hit the ball and what kind of ball is being hit. A golf ball will go much higher than a basketball or football.
Gravity most definatley works on a bowling ball as it goes down the lane. If gravity didn't affect it then the ball would go through the roof of the center. However the ball does not appear to slow down much because there is clear oil on the lane (in varying amounts) which allows the ball to skid across the lane without giving up a lot of speed.The ball is rolled down the lane with enough force to allow it to gain momentum (a sort of gravity) and the lane is heavily waxed, so there is little resistence to slow it down. The ball will sometimes 'break', or hook to the left or right; this makes the ball go into the 'gutter' if your ball doesn't have enough momentum. If you notice, on the lane before and after the foul line, there are arrows that guide where you stand and where you aim your ball to guide it so that the ball will turn left or right to hit the left or the right of the #1 pin to get a strike.Work is the force times the distance traveled in the direction of the force (vector multiplication). If the bowling alley is level, then as the ball moves it's distance from the center of the earth does not change. That is, it does not move at all in the direction of the force of gravity. Since the distance moved toward or against the force is zero, the work done is zero.Force of gravity will not effect the bowling ball because the Normal Force is equal to the Force of gravity. Therefore canceling each other out. The forces on the bowling ball rolling down a bowling alley would be Applied Force and some Force of Friction.Work (W) is defined in Physics as the Force (f) acting on an object times the distance (d) the object is moved by that Force, or W = fdSince Force is mass times acceleration, and because the ball is on a surface that is perpendicular to the force exerted by gravity, the ball does not move vertically; there is no gravitational acceleration, hence no Force, so no Work is done by gravity.
the angles that you hit the ball, how high you hit the ball, and the langth you hitt the ball. you also can find out how much force is on the ball:)
The ball exerts an equal and opposite force of 8 newtons on the bat, according to Newton's third law of motion. So, the force exerted by the ball on the bat is also 8 newtons.
To calculate the force required to stop the ball, we need to convert the mass of the ball from grams to kilograms (145g = 0.145kg). Then, we can use the formula for force: force = mass x acceleration. Given that the ball is traveling at 100mph (44.7 m/s) and comes to a stop, the acceleration would be the time it takes to stop divided by the initial velocity. So, the force required to stop the ball would be calculated using these values.