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Assuming all other factors are equal, a bigger ball would have the same acceleration as a smaller ball when subject to the same force. This is because acceleration is dependent on force and mass, and in this case, the increased mass of the bigger ball would require more force to achieve the same acceleration as the smaller ball.
The mechanical advantage of the lever in this case would be 10, as the effort force is 1/10th of the load force. This means that by applying an effort force ten times smaller than the load force, the lever can move the load.
The net force produced is the difference between the two forces. Subtraction of the smaller force from the larger force gives the net force. In this case, the net force would be 15.4 N - 9.2 N = 6.2 N.
The force of gravity on an object is commonly referred to as weight. It is the force exerted on an object due to gravity pulling it towards the center of the Earth.
No, centripetal force is the force required to keep an object moving in a circular path, while gravitational force is the force of attraction between two objects due to their mass. In the case of a satellite orbiting a planet, the centripetal force required to keep the satellite in orbit is provided by the gravitational force between the satellite and the planet.
Assuming all other factors are equal, a bigger ball would have the same acceleration as a smaller ball when subject to the same force. This is because acceleration is dependent on force and mass, and in this case, the increased mass of the bigger ball would require more force to achieve the same acceleration as the smaller ball.
friction decreases the acceleration of a car by creating a greater force which pushes against the acceleration force. the friction is a force, but more of it means that whatever is pushing against it ( acceleration in this case) is made smaller.
You would have to specify a distance between the charges. Just as in the case of gravity, the further apart the charges are, the smaller the force.
The mechanical advantage of the lever in this case would be 10, as the effort force is 1/10th of the load force. This means that by applying an effort force ten times smaller than the load force, the lever can move the load.
The net force produced is the difference between the two forces. Subtraction of the smaller force from the larger force gives the net force. In this case, the net force would be 15.4 N - 9.2 N = 6.2 N.
The magnitude of the resultant force in the case of the concurrent forces in equilibrium.
Simply a question of Force distributed over a much smaller area in the case of disk brakes (or higher pressure)
Several things happen in this case; for example:* From each of the objects, the other object will look smaller * Things like gravitational attraction, tidal forces, electrical force, and magnetic force will be reduced.
Several things happen in this case; for example:* From each of the objects, the other object will look smaller * Things like gravitational attraction, tidal forces, electrical force, and magnetic force will be reduced.
None. Gravity IS the force in this case.
In that case, the force is proportional to the acceleration.
Well, isn't that just a happy little problem to solve! To calculate the force output, you can use the formula: Force output = (Area of larger piston / Area of smaller piston) x Force input. So, in this case, it would be (950 cm² / 20 cm²) x 700 N. Just remember, there are no mistakes, only happy little accidents in math!