A heat exchanger is being investigated as a waste heat recovery device. A heat exchanger is commo...
A heat exchanger is being investigated as a waste heat recovery device. A heat exchanger is common device for using a hot fluid to heat a cold fluid without the fluids mixing. The cold fluid stream of liquid A enters at 294.2 K and leaves the device at a temperature of 330.91 K. Liquid A flows at a rate of 0.006 Kg/s and has a specific heat of 4180 J/(Kg K) and a specific volume of 0.00102 m3/Kg. Liquid B enters the device at a temperature of 350.2 K and flows at a rate of 0.005 Kg/s and has a specific heat of 3900 J/(Kg K) and a specific volume of 0.00133 m3/Kg. The dead state is at 293.2 K and 1 bar. The device is adiabatic and the pressure loss for fluid A is 0.001 bars and for fluid B it is 0.002 bars. Both liquids can be considered to be incompressible materials.
- Using the first law determine the exit temperature of fluid B.
- Calculate the heat transfer rate between the fluids.
- Calculate the rate of exergy destroyed in the heat exchanger
- Calculate the second law efficiency for this device. The exergy product is the exergy increase in liquid A and the exergy input is the exergy change in liquid B.
- If the exiting liquid B is not used for any useful purpose, calculate the exergy destroyed associated with it.
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A heat exchanger is being investigated as a waste heat recovery device. A heat exchanger is commo...
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Help me!!!!
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A hot fluid of specific heat 4100 J/kg K flows through a parallel flow heat exchanger at the rate of 3.5 kg/min with an inlet temp. of 105C. A cold fluid of specific heat 2350 J/kg K flows in at a rate of 9 kg/min and with inlet temperature 25C. Make calculations for maximum possible effectiveness if the fluid flow conforms to parallel * .flow arrangement 0.596 0.458 .321 0.825 O
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this problem in heat exchanger, please solve.
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