Optimization of parameters for heat recovery steam generator (HRSG) in combined cycle power plants

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Optimization of parameters for heat recovery steam generator (HRSG) in combined cycle power plants Muammer Alus, Milan V. Petrovic - Faculty of Mechanical Engineering Laboratory of Thermal Turbomachinery Power Plants 2010 Vrnajcka Banja Oct. 26-29, 2010

Introduction This work illustrated thermodynamic and thermoeconomic optimization in HRSG of combined cycle power plants. Thermodynamic optimization is minimization of the thermal exergy losses due to decreasing the pinch point (P.P). Thermoeconomic optimization is minimization of the total HRSG cost: cost of exergy losses + installation cost. 2 Power Plants 2010

Heat Balance Diagram of CCGT 3 Power Plants 2010

Pinch Point (P.P) Definition P.P: Δ between t of gas leaving the evaporator and the water saturation t. 4 Power Plants 2010

Example of Optimization Main characteristics of the CCGT plant: Gas Turbine: Gross Power 200 MW Gas turbine inlet temperature 1423 K Efficiency 0.393 Gas exit temperature 758 K Air mass flow 571.60 kg/s 5 Power Plants 2010

Example of Optimization Steam Turbine: Gross power 103.68 MW Maximum steam pressure 28 bar Steam condenser pressure 0.08 bar Feed water temperature 363 K Steam mass flow 70.12 kg/s Min. designed Δt for P.P 10 K 6 Power Plants 2010

Example of Optimization Assumptions of economic parameters: Life of plant 20 year Operating hours 7446 h.year -1 Selling price of power 0.0625 $/kwh Installed costs of the sections of the HRSG Economizer 45.70 $/m 2 evaporator 34.80 $/m 2 Superheater 96.20 $/m 2 The overall heat transfer coefficients for the sections of the HRSG Economizer 42.60 W/m 2 K evaporator 43.60 W/m 2 K Superheater 50 W/m 2 K 7 Power Plants 2010

Thermodynamic Optimization The thermodynamic optimization of the HRSG due to min. of exergy losses. For a heat exchanger at steady state, the availability balance equation is given by: I = E E = ( me ) ( me ) HRSG in out in out The HRSG exergy losses can be calculated as : I = m.[( h Ts ) ( h Ts )] m.[( h Ts ) ( h Ts )] HRSG g 4g 0 4g 7g 0 7g s 4 0 4 7 0 7 8 Power Plants 2010

Thermodynamic Optimization 17,700 17,600 Exergy loss ( KW ) 17,500 17,400 17,300 17,200 17,100 17,000 16,900 0 5 10 15 20 25 pinch point ( K ) The relation between exergy loss and P.P is linear. 9 Power Plants 2010

Thermoeconomic Optimization 1. Cost of exergy loss of the HRSG: K = k. H. I I I HRSG 2. Cost of the HRSG: K = k A + k A + k A HRSG e e V V sh sh e V sh 10 Power Plants 2010

Thermoeconomic Optimization 3. The total cost of HRSG: The total annualized cost of the HRSG is: K = K + K I HRSG 1 = k. H. I + k A + k A + k A D I e e V V sh sh e V sh The heat exchange surface is: A Qi i = U. Δ T mi, mi, 11 Power Plants 2010

Results and Discussion - Cost of heat area 15,000,000 14,000,000 cost of heat area of HRSG ($) 13,000,000 12,000,000 11,000,000 10,000,000 9,000,000 8,000,000 7,000,000 0 5 10 15 20 25 pinch point (K) The cost of heat area of HRSG decreases with increasing P.P 12 Power Plants 2010

Results and Discussion - Exergy loss cost 7,750,000 7,700,000 Exergy cost of HRSG ( $/year ) 7,650,000 7,600,000 7,550,000 7,500,000 7,450,000 7,400,000 0 5 10 15 20 25 Pinch point ( k ) The relation between exergy loss cost of HRSG and P.P is very close to linear. 13 Power Plants 2010

Results and Discussion - Total cost of HRSG 8,160,000 8,140,000 Total cost of HRSG ( $/year ) 8,120,000 8,100,000 8,080,000 8,060,000 8,040,000 8,020,000 8,000,000 0 4 8 12 16 20 24 Pinch point ( K ) The total cost of HRSG decreases with increasing the P.P until pinch point 8 K and than increases with increasing the P.P. 14 Power Plants 2010

Conclusions The thermodynamic optimization was carried out by means of the minimization of exergy losses due to the temperature difference between the hot (gas) and the cold stream (steam). The exergy loss decreases almost linearly by reduction of the P.P. The thermoeconomic optimization was performed by analyzing the total cost of HRSG (the sum of the costs related to the exergy losses plus the costs of HRSG components). The variation of values for the pinch-points in the range between 3 and 20 K has shown that the optimal value is at 8 K. 15 Power Plants 2010

Optimization of parameters for heat recovery steam generator (HRSG) in combined cycle power plants Muammer Alus, Milan V. Petrovic - Faculty of Mechanical Engineering 16 Power Plants 2010

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