Probably on the axle??
Greater force would be required on the wheel since on a axle the effort arm is longer therefore less force would also produce the same output.
my liquids
Force of attraction make a solid denser. Solids have great force of attraction between their molecules that's why they are denser. Greater would be the force of attraction greater would be the density.....
It is only attractive in nature. I am not sure which nuclear force you talk about. Electrical forces of the nucleus are repulsive to the positively charged. There are "strong forces" and the like which are attractive.
There is no force of drag or friction acting to slow it down.
Yes. I used a wheel and placed magnets all around it, then I spun the wheel and placed another magnet in front of the wheel and thought that the wheel would keep spinning due to the magnets repelling each other but it didn't work.
A wheel requires a smaller amount of force to be moved than an axle. Combined, a minimal amount of force is used to move the wheel and in turn is transferred from the wheel to the attached axle, to move the axle. Alone the axle would require a greater amount of force for it to be turned.
I'm not a scientist but I would say the greater the force, the greater the erosion. A larger wave has more mass, and would exert more force on what it hits. The greater force would have greater potential for knocking particles loose from what it hits - erosion. The speed of the wave would have a similar effect - greater speed equals greater fore and greater erosion.
Possibly bad wheel bearing.
The deformation would increase because the force increases.
force
The greater the mass, the greater the force of gravity.
my liquids
The wheel and axle would be multiplying distance.
Force of attraction make a solid denser. Solids have great force of attraction between their molecules that's why they are denser. Greater would be the force of attraction greater would be the density.....
It is only attractive in nature. I am not sure which nuclear force you talk about. Electrical forces of the nucleus are repulsive to the positively charged. There are "strong forces" and the like which are attractive.
To get something t accelerate, you must apply a force to it. To get it to accelerate faster requires more force. Also, if something has a greater mass, it requires more force to get the same acceleration as something of lesser mass. Leave a note on my message board if you would like some formulas relating to mass, force, and acceleration.
To get a trailer up to a speed v in a time t, you would need to get it accelerating at a rate of v/t. From F=ma, the net force on the trailer to achieve this would have to be mv/t. First, you'll need to apply a force greater than the static frictional force to get the trailer moving - then to get the desired acceleration, you'd apply a force F = mv/t + Ff where Ff is the kinetic friction of the axel/tires. So, once you overcome the static friction the required force to achieve velocity v in time t would be: F = mv/t + frictional force