Kinetic Energy

mgz g_c PE mgz g_c 50 lbm 1 32.17 ft sec² 10 ft 1 lbf sec² 32.17 lbm ft KE mv² 2g_c ENERGY AND WORK Energy, Work, and Power CP-05 Page 2 Rev. 0 As an example, consider the energy stored in hydrogen and oxygen as potential energy to be released on burning. Burning changes their relative separation distance from the elemental form to the compound form as water releases the potential energy. When discussing mechanical potential energy, we look at the position of an object. The measure of an object's position is its vertical distance above a reference point. The reference point is normally the earth's surface, but can it be any point. The potential energy of the object represents the work required to elevate the object to that position from the reference point. Potential energy is mathematically represented by Equation 5-1. PE = work to elevate = weight x height (5-1) where: PE = potential energy in ft-lbf m = mass in lbm g = 32.17 ft/sec² g = 32.17 (lbm-ft)/(lbf-sec ) c 2 z = height above a reference in ft It should be noted the g is used only when using the English system of measurement. c Example: What is the potential energy of a 50 lbm object suspended 10 feet above the ground? Answer: PE = 500 ft-lbf Kinetic Energy Kinetic energy is defined as the energy stored in an object because of its motion. If you have a baseball in your hand, it has no kinetic energy because it is not moving. But if you throw the ball, your hand has provided energy to give the ball motion. When you release the ball, it leaves your hand at some velocity. The energy you have given the ball will determine the velocity of the ball. Because the kinetic energy is due to the motion of the object, and motion is measured by velocity, kinetic energy can be calculated in terms of its velocity, as shown below. (5-2)