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Checking units

According to the equation for kinetic energy, the unit should be kg · m 2 · s - 2 . We can prove that this unit is equal to the joule, the unit for energy.

( kg ) ( m · s - 1 ) 2 = ( kg · m · s - 2 ) · m = N · m ( because Force ( N ) = mass ( kg ) × acceleration ( m · s - 2 ) ) = J ( Work ( J ) = Force ( N ) × distance ( m ) )

We can do the same to prove that the unit for potential energy is equal to the joule:

( kg ) ( m · s - 2 ) ( m ) = N · m = J

A bullet, having a mass of 150 g , is shot with a muzzle velocity of 960 m · s - 1 . Calculate its kinetic energy.

    • We are given the mass of the bullet m = 150 g . This is not the unit we want mass to be in. We need to convert to kg.
      Mass in grams ÷ 1000 = Mass in kg 150 g ÷ 1000 = 0 , 150 kg
    • We are given the initial velocity with which the bullet leaves the barrel, called the muzzle velocity, and it is v = 960 m · s - 1 .
    • We are asked to find the kinetic energy.
  1. We just substitute the mass and velocity (which are known) into the equation for kinetic energy:

    E K = 1 2 m v 2 = 1 2 ( 0 , 150 ) ( 960 ) 2 = 69 120 J

Kinetic energy

  1. Describe the relationship between an object's kinetic energy and its:
    1. mass and
    2. velocity
  2. A stone with a mass of 100 g is thrown up into the air. It has an initial velocity of 3 m · s - 1 . Calculate its kinetic energy
    1. as it leaves the thrower's hand.
    2. when it reaches its turning point.
  3. A car with a mass of 700 kg is travelling at a constant velocity of 100 km · hr - 1 . Calculate the kinetic energy of the car.

Mechanical energy

Mechanical energy is the sum of the gravitational potential energy and the kinetic energy.

Mechanical energy, E M , is simply the sum of gravitational potential energy ( E P ) and the kinetic energy ( E K ). Mechanical energy is defined as:

E M = E P + E K
E M = E P + E K E M = m g h + 1 2 m v 2
You may see mechanical energy written as U . We will not use this notation in this book, but you should be aware that this notation is sometimes used.

Conservation of mechanical energy

The Law of Conservation of Energy states:

Energy cannot be created or destroyed, but is merely changed from one form into another.

Conservation of Energy

The Law of Conservation of Energy: Energy cannot be created or destroyed, but is merely changed from one form into another.

So far we have looked at two types of energy: gravitational potential energy and kinetic energy. The sum of the gravitational potential energy and kinetic energy is called the mechanical energy. In a closed system, one where there are no external forces acting, the mechanical energy will remain constant. In other words, it will not change (become more or less). This is called the Law of Conservation of Mechanical Energy and it states:

The total amount of mechanical energy in a closed system remains constant.

Conservation of Mechanical Energy

Law of Conservation of Mechanical Energy: The total amount of mechanical energy in a closed system remains constant.

This means that potential energy can become kinetic energy, or vice versa, but energy cannot 'disappear'. The mechanical energy of an object moving in the Earth's gravitational field (or accelerating as a result of gravity) is constant or conserved, unless external forces, like air resistance, acts on the object.

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Source:  OpenStax, Physics - grade 10 [caps 2011]. OpenStax CNX. Jun 14, 2011 Download for free at http://cnx.org/content/col11298/1.3
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