Want this question answered?
It's hard to give "daily life examples" when two of the four fources (the weak force, and the strong force) are not encountered in "daily life". The comparison that is usually done is comparing the magnitude of the forces between two subatomic particles.
A mechanism with a positive mechanical advantage is one in which the input force is greater than the output force. This is compensated for by the fact that the distance moved by the input is greater than the output so that in an ideal machine, the work input (Force*Distance) is the same as the work output. In real life, though, you always lose some energy - in the form of frictional heat, or sound.A negative mechanical advantage is the opposite. A small distance moved by the input is converted to a large distance moved by the output. But the force in the output is correspondingly reduced.A mechanism with a positive mechanical advantage is one in which the input force is greater than the output force. This is compensated for by the fact that the distance moved by the input is greater than the output so that in an ideal machine, the work input (Force*Distance) is the same as the work output. In real life, though, you always lose some energy - in the form of frictional heat, or sound.A negative mechanical advantage is the opposite. A small distance moved by the input is converted to a large distance moved by the output. But the force in the output is correspondingly reduced.A mechanism with a positive mechanical advantage is one in which the input force is greater than the output force. This is compensated for by the fact that the distance moved by the input is greater than the output so that in an ideal machine, the work input (Force*Distance) is the same as the work output. In real life, though, you always lose some energy - in the form of frictional heat, or sound.A negative mechanical advantage is the opposite. A small distance moved by the input is converted to a large distance moved by the output. But the force in the output is correspondingly reduced.A mechanism with a positive mechanical advantage is one in which the input force is greater than the output force. This is compensated for by the fact that the distance moved by the input is greater than the output so that in an ideal machine, the work input (Force*Distance) is the same as the work output. In real life, though, you always lose some energy - in the form of frictional heat, or sound.A negative mechanical advantage is the opposite. A small distance moved by the input is converted to a large distance moved by the output. But the force in the output is correspondingly reduced.
If there were no mechanical energy, there would be no movement and so no life exists.
•The conservation of mechanical energy is a principle which states that under certain conditions, the total mechanical energy of a system is constant. This rule does not hold when mechanical energy is converted to other forms, such as chemical, nuclear, or electromagnetic.
i walk and run everyday
using a car
You can use Mechanical Energy in are daily lifes by things that have force and that has power to use the object.
It's hard to give "daily life examples" when two of the four fources (the weak force, and the strong force) are not encountered in "daily life". The comparison that is usually done is comparing the magnitude of the forces between two subatomic particles.
my vagina
Tacoma Narrows Bridge
Everyday life has a myriad of examples of science. Computer science is important, as well as medical science. Another is genetics that are assisting the planet in world hunger.
We are actually finding this gravitational force during the every moment in the life time. If we had no gravitational force, we must have been flying in the air. The 2 examples are:-When we throw a ball in the air air, it returns to the ground.When we shoot a ball in the net, falls down again.
weather front
There are a few example of RXN in daily life. The three most common examples are fusion, combustion, and fission.
The mechanical advantage would be 1 because the force required to life the mass of an object becomes 1/2 the original weight of the object.
Some three examples of how the atmosphere supports and protects life includes blocking out harmful UV rays from the sun and balancing the carbon dioxide levels. Most life forms need oxygen to survive and this comes from the atmosphere.
force -lifting object