Specific Internal Energy

ENERGY, WORK, AND HEAT Thermodynamics Example: Determine the kinetic energy of 7 lbm of steam flowing through a pipe at a velocity of 100 ft/sec. Solution: Using Equation 1-12. KE mv² 2g_c KE (7 lbm) (100 ft/sec)² 2(32.17 ft lbm/lbf sec²) KE (7 lbm) (10,000 ft²/sec²) (64.34 ft lbm/lbf sec²) KE 1088 ft lbf Specific Internal Energy Potential energy and kinetic energy are macroscopic forms of energy. They can be visualized in terms of the position and the velocity of objects. In addition to these macroscopic forms of energy, a substance possesses several microscopic forms of energy. Microscopic forms of energy include those due to the rotation, vibration, translation, and interactions among the molecules of a substance. None of these forms of energy can be measured or evaluated directly, but techniques have been developed to evaluate the change in the total sum of all these microscopic forms of energy. These microscopic forms of energy are collectively called internal energy, customarily represented by the symbol U. In engineering applications, the unit of internal energy is the British thermal unit (Btu), which is also the unit of heat. The specific internal energy (u) of a substance is its internal energy per unit mass. It equals the total internal energy (U) divided by the total mass (m). (1-13) u U m where: u = specific internal energy (Btu/lbm) U = internal energy (Btu) m = mass (lbm) HT-01 Page 16 Rev. 0