Thermodynamics analysis and performance optimization of a reheat – Regenerative steam turbine power plant with feed water heaters

Thermodynamics analysis and performance optimization of a reheat – Regenerative steam turbine power plant with feed water heaters

Plot of Cycle Efficiency against Number of closed FWHs. [Display omitted] This study investigates the thermodynamics performance analysis of a reheat-regenerative steam power plant using CyclePad V2.0 software. The impact of closed Feedwater Heaters (FWHs) on the functionality indices of the selecte...

Full description

Saved in:
Bibliographic Details
Published in:Fuel (Guildford) Vol. 280; p. 118577
Main Authors: Oyedepo, S.O., Fakeye, B.A., Mabinuori, B., Babalola, P.O., Leramo, R.O., Kilanko, O., Dirisu, J.O., Udo, M., Efemwenkiekie, U.K., Oyebanji, J.A.
Format: Journal Article
Language:English
Published: Kidlington Elsevier Ltd 15-11-2020
Elsevier BV
Subjects:
Cycle efficiency
Efficiency
Enthalpy
Environmental impact
Feedwater
Feedwater heater
Fuel consumption
Heat
Heat input
Heat rate
Operating costs
Optimization
Performance optimization
Power plants
Regeneration
Specific steam consumption
Steam consumption
Steam electric power generation
Steam power
Steam turbines
Temperature
Thermodynamic efficiency
Thermodynamics
Turbines
Water heaters
Heat input
Performance optimization
Feedwater heater
Specific steam consumption
Heat rate
Cycle efficiency
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Plot of Cycle Efficiency against Number of closed FWHs. [Display omitted] This study investigates the thermodynamics performance analysis of a reheat-regenerative steam power plant using CyclePad V2.0 software. The impact of closed Feedwater Heaters (FWHs) on the functionality indices of the selected power plant was examined. Results of the study show that as the number of closed FWH increases from one to ten, the thermal efficiency and boiler efficiency rise from 42.17% to 45.97% and 79% to 96.4%, respectively. The fuel consumption, heat rejected to the condenser, heat rate, network output and heat input to the power cycle decrease from 9.697 kg/s to 4.686 kg/s, 209.32 kJ/kg to 129.68 kJ/kg, 8536.87 kJ/kWh to 8318.48 kJ/kWh, 152.22 MW to 102.89 MW and 361.11 kJ/kg to 237.98 kJ/kg, respectively as the number of FWHs increased. On the contrary, specific steam consumption increases from 0.0234 kg/kWh to 0.0370 kg/kWh. Moreover, fuel consumption decreases by 51.7% and the efficiency gain (η) successively diminish with increment in the number of closed FWHs. Also, both enthalpy rise and temperature rise increase with increase in the number of closed FWHs. As the number of heaters increases, so is the total temperature rise of feed water (Δtfw), by regeneration, less becomes the heat added to water in the boiler, more becomes the mean temperature of heat addition, and more is the cycle efficiency. This result implies that a decrease in operating cost of the plant and environmental impacts can be achieved with an increase in the number of closed FWHs. Hence, this study establishes the importance of closed FWHs in revamping the performance of a steam power plant.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2020.118577