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The local environment (ground state) is at 14.7 psia and 50.0°F. Determine the second law availability efficiency of the power plant.
Assuming that no energy is lost in the impact, determine (a) the velocity of the ball immediately after impact, and (b) the impulse of the force exerted by the plate on the ball.
Select the proper equations to describe the flight of the canister, perform a study to recommend a canister opening setting.
Design a cooling system for this device as an emergency measure keeping in mind that no fans or circulating pumps are available.
The turbine of a large power plant receives 1.00 x 108 Btu/h of heat from the boiler at 900°F. Determine the rate at which available energy enters the boiler.
If the process is not reversible but is adiabatic and polytropic with a polytropic exponent of n = 1.47, calculate the power required to drive the compressor.
Determine the discharge temperature and the power required to drive the compressor if the process irreversible and adiabatic.
Determine the steady state irreversibility rate of each light source when the local environmental temperature is 20.0°C, and comment on which is the more efficient.
Determine the specific availability of the helium in the balloon relative to the ground, where the loval environment is at p0 = 0.101 MPa and T0 = 20.0°C.
If the total entropy of the cell must be ten times its ground state value, what should the total energy of the cell be?
The total energy contained in a closed, sealed, rigid can of tuna is 3000 J with a total entropy of 2.8330 J/K. Determine the maximum reversible work available from the can of tuna.
For the compressor, the isentropic efficiency is 92% and for the turbine the isentropic efficiency is 95%. For a regenerator effectiveness of 85%, determine the net power developed, in MW.
Assuming all processes are reversible, determine the ratio of the heat transfer from the source to the heat transfer from the refrigerated space.
Determine the flow rates for product and water, that will provide the conditions described. Use specific heats of 3.7 Kj/Kg K for the product and 4.18 Kj/(Kg K) for water.
If the venture is undertaken and it is found that the heater does pay for itself in a year by saving $1,400 per month, what amount was paid to the contractor at the last of each month of constructio
Steam flows steadily through a nozzle. the steam enters the nozzle at P1=5MPa and T1=350 C the steam leaves the nozzle at P2 =400 kPa and quality = 0.40 A1=2m^2 A2=1m^2 find the output velocity of
Assuming one-dimensional heat transfer and disregarding radiation, determine the rate of heat transfer through the wall.
For each plot use a range x or y = okm to 1 km. Find the equation for the streamlines and sketch several of them. What does this flow field model?
Determine how long it takes before its velocity is reduced to zero, which occurs when it reaches its maximum height. Use the principle of impulse and momentum.
Determine the velocity at the nozzle exit and the thrust produced. Consider the diameter of the diffuser at the inlet equal to 1.6 m.
Find the net work per unit mass of cycle air, the thermal efficiency and the cyclic irreversibility per unit net work for all combustions of the following parameters.
Determine the factors of safety and state whether or not the part is predicted to fail for the following states of stress. Also plot all four cases on a σ1,σ3 plot showing load lines and
Determine the required size for a square bar to be made from AISI 1213 cold-drawn steel. It carries a constant axial tensile load of 1500 lb
Saturated liquid leaves the regenerator at the pressure of the extraction steam. Neglecting all pump work determine the percent mass flow of steam extracted from the turbine.
What degree of superheat would be required if the team entered an isentropic turbine at 300 psia and exited as a saturated vapor at 1.00 psia?