Another cathedral that's not in use at the same time.
The more the vehicle weighs the more mass the engine must move. The more mass that the engine is required to move, the more power it requires. A larger engine with more power required to move a heavier vehicle uses more fuel.
That depends on the mass/size of the vehicle the engine is required to move.
That depends on the mass/size of the vehicle the engine is required to move.
Force is measured in Newtons (N) The amount of force required = the mass of the object x the acceleration
More mass --> more force required. More acceleration --> more force required. Remember the relationship commonly known as "Newton's Second Law": F=ma (force = mass x acceleration).
Mass doesn't like to move. Rather, it doesn't like to be forced to move. The first law of motion by Newton states that an object in motion will stay in motion until an external force is acted upon it. The second law of motion by Newton states that force is equal to mass multiplied by acceleration. The more something weighs, or the more mass it has, the more acceleration or force is required to move it. So to answer your question shortly, increase in mass affects how much acceleration or force is needed to move that mass.
If the mass is already moving, then no force is required to move it any desired distance,and if it's not moving, then any force will start it moving. We'll say that there's no definiterelationship between force, mass, and distance.
Work is done by a force acting on a mass when that mass is displaced (moved).Basically, more work is required to move a mass through a greater distance, similarly more work is required to move a greater mass though the same distance.Providing all other things are equal, if the same box is moved through a distance of two metres you do more work than moving the box through one metre.
Light travels at 186,000 miles per second, which means you have to travel faster than that to break the light barrier. This feat is technically "impossible", since the faster you move, the more mass you have and the more mass you have, the more energy is required to move you, and by the time you reach the speed of light, you will need to have infinite energy. This doesn't apply to light particles, since they have no mass.
No force is required to keep an object in motion. Maintaining speed and direction seems to be "the natural thing to do" for any object. A force is required to CHANGE an object's velocity, whether you want to make it go faster, slow it down, or simply change the direction for a moving object.
It takes no force to 'move' an object. There are trillions of objects that are moving right now with no forces acting on them. It only takes force to 'accelerate' an object ... to change its motion, by changing its speed or the direction of its motion. force=mass*acceleration As mass increases, so does the force needed to change the object's motion.
It is exactly the same as momentum and covered by Newton's first law of motion. Inertia is a way of expressing the force required to get an object to move from rest, or the force required to change the velocity or direction of an object in motion. Anything that has mass will have inertia - a "resistance to move or change velocity or direction of motion".