Thermodynamic Analysis of Waste Heat Power Generation

Question: Talk about the Thermodynamic Analysis of Waste Heat Power Generation. Answer: Arrangement 1 The concoction response for the fume age is as per the following- Vitality created by steam- For 100% yield All out water sum will be changed over into steam and in this manner- Presently ascertaining the mass of water created Proportion of sub-atomic load of ethylene to water = Proportion of sub-atomic load of ethylene to water = Hence mass of ethylene required = 41918*1.55 Hence mass of ethylene required = 65205.77 kg At the point when yield is 75% for example just 75% of the water is changed over into steam- Proportion of atomic load of ethylene to water = Proportion of atomic load of ethylene to water = Accordingly mass of ethylene required = 55890.66*1.55 Accordingly mass of ethylene required = 86630.53 kg Arrangement 3 The given information are as per the following- At 50 m above turbine pressure Pa = 307 kPa At 10 m beneath turbine pressure Pb = 110 kPa Turbine yield = 0.5 MW for example the stature of turbine from ground is 18.70 m Arrangement 4 The given information are as per the following- Volume stream pace of milk V = 5000 liters/day Volume stream pace of milk V = 5 m3/day Starting temperature Last temperature In general warmth move coefficient U = 40 Mass of milk = Mass of milk = Mass of milk = Measure of warmth required = Measure of warmth required = Measure of warmth required = The temperature of water leaving the warmth exchanger can be determined as- The necessary territory of the warmth exchanger can be determined as- Complete warmth Q = UA References Guo, J., Xu, M. also, Cheng, L. (2010). Thermodynamic investigation of waste warmth power age framework. Vitality, 35(7), pp.2824-2835. hman, H. also, Lundqvist, P. (2014). Thermodynamic pre-assurance of intensity age potential in geothermal low-temperature applications. Geotherm Energy, 2(1). Zhang, X. what's more, Jin, H. (2013). Thermodynamic investigation of substance circling hydrogen age. Applied Energy, 112, pp.800-807.