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The gravitational force would then be 100F, by manipulating the formula.
The display indicates zero. That's how you know the forces are equal.
The larger the force pulling on a spring, the greater the length in the spring and the more energy that is stored in that spring. When looking at a spring there is a gradient that determines how much force much be used to sqeeze or stretch a spring a given amount. When a spring is stretched, the greater the force that is applied, the greater the change in length of the spring and the greater the amount of energy that is stored in the spring. A link is supplied to the Wikipedia article on the spring (device).
The electric force becomes four times stronger.
F=e2zc/2r2= 9 nev/m
Yes, those are two names for the same thing
The gravitational force would then be 100F, by manipulating the formula.
The display indicates zero. That's how you know the forces are equal.
Force is a concept and is invisible. An example will be that you use to pull apart two magnets that are stuck together. That effort to pull the two magnets apart is a force. When your airplane is taking off, you feel your back is being pushed against your seat. What you are feeling is the force that the seat cushion is applying on you. When you hang a weight on a spring, the spring elongates. A force is applied by the weight on the spring to cause the lengthening of the spring. When you hit a softball, the softball flies away because you exert a force on the bat; the bat hits the ball; the ball stores the kinetic energy and then releases the energy as a force pushing on the ball until the ball leaves the bat.
Contact forces: frictional force, tension Force, air resistance force , applied force and spring force Action-at-a-Distance Forces: gravitantional, electrical and magnetic force If this was the answer you where looking for :)
Spring clamps are used for holding two or more solid objects together with tremendous force. The spring clamps obtain a very high amount of pressure from the coils.
The larger the force pulling on a spring, the greater the length in the spring and the more energy that is stored in that spring. When looking at a spring there is a gradient that determines how much force much be used to sqeeze or stretch a spring a given amount. When a spring is stretched, the greater the force that is applied, the greater the change in length of the spring and the greater the amount of energy that is stored in the spring. A link is supplied to the Wikipedia article on the spring (device).
If actually weighing the plates is impractical, you could try hanging the plates from a spring, and testing to find the spring's k value, and recording the displacement of the object while hanging from the spring, and use that to calculate the force on the plate, which equals mg. if the density is known, you could immerse the plates in something to find their volume and then calculate their weight from that. or, you could try and pull them with a force meter, taking two data points so that you can solve for the both the friction coefficient and weight.
Gravity and Support Force
You can measure a force with a force meter or by calculating it by using one of two equations depending on the available variables: ma=F or F=m(v1 + v2)/t
The two systems of measurement include the English system which is based on the foot measurements, and the Metric system based on the Meter as the unit of reference.
The electric force will be quarter of its strength.