Gravitational force pulling the ball towards the center of the Earth, the normal force between your hands and the ball, and the force exerted on the ball to raise it against gravity; this is called gravitational potential force, which can be calculated to be the mass of the ball multiplied 9.8m/s2 and the height it is raised from it's initial place.
The net force would be in the direction of the bowling ball's motion, which in this case would be towards the bowling pin.
Gravitational force pulling the ball towards the center of the Earth, the normal force between your hands and the ball, and the force exerted on the ball to raise it against gravity; this is called gravitational potential force, which can be calculated to be the mass of the ball multiplied 9.8m/s2 and the height it is raised from it's initial place.
The force required to accelerate a 25 kg bowling ball can be calculated using the equation F = ma, where F is the force, m is the mass of the bowling ball, and a is the acceleration. If the acceleration is given, you can plug in the numbers to find the force needed.
it knocks the pins down.
No. Speed and force cause a bowling ball to roll down a lane. Friction may cause a bowling ball to change course on a lane though, and also slow it down.
Any amount of force can stop either kind of ball. But a greater force is required to stop a bowling ball than to stop a soccer ball IN THE SAME TIME, because the bowling ball has more mass, and therefore more momentum and more kinetic energy.
Use more or less force than you usually do, more force, faster ball, less force, slower ball.
calculate the force of the ball and statistics
The object with the most gravitational force would be the bowling ball, as it has the greatest mass compared to a sand grain, marble, and tennis ball. Gravitational force increases with mass, so the object with the highest mass will have the strongest gravitational force.
The object with the most mass, as gravitational force is dependent on mass. Therefore the bowling ball exerts more gravitational force than a baseball or a football.
A bowling ball has a greater force than an apple due to its larger mass. Force is directly proportional to mass, so the heavier object will exert a greater force when both are accelerated the same way.
Yes... Its not the weight but the force of gravity