Evaluating the Technical and Economic Feasibility of Adding a Power Recovery  System to the Steam Condenser of a  Lignite Coal-Fired Power Plant

Wilmer, Joshua; Seames, Wayne; Bazile, Dimitri; Smith, Kay Lee; Koster, Benjamin; Mauch, Grady; Weimer, Lucas Philipp

doi:10.4236/jpee.2022.1011002

JPEE

2022

DOI: 10.4236/jpee.2022.1011002

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Evaluating the Technical and Economic Feasibility of Adding a Power Recovery System to the Steam Condenser of a Lignite Coal-Fired Power Plant

Joshua Wilmer¹,

Wayne Seames²,

Dimitri Bazile³

et al.

Abstract: Steam is the typical working fluid to drive turbo-generators in coal-fired power plants. It is an effective working fluid, but some of its energy is extracted in an unusable form when condensed. A Power Recovery Cycle (PRC) using a more volatile Secondary Working Fluid (SWF) added to the steam cycle could improve energy efficiency. PRCs have been applied to the flue gas and for combined cycle systems but not to traditional plant steam cycles. This paper details an analysis of adding a steam cycle PRC to a 500 … Show more

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Biosolid Gasification Performance Prediction Using a Stoichiometric Thermodynamic Model

Li,

Zhang,

2024

ACS Omega

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The gasification process can recover energy from biosolids produced in wastewater treatment. This paper developed a stoichiometric thermodynamic equilibrium model for biosolid gasification based on the biosolid properties, thermodynamic database, and equilibrium constants. If the calculation result showed that the quantity of char was negative, the quantity of char was put to zero, and the simulation was carried out again. The model was first verified by woody gasification under isothermal conditions, and the influence of a given temperature on biosolid gasification was simulated. The model further investigated the effects of different feedstock types, moisture contents, equivalence ratios, and reaction extensions on the adiabatic temperature, exergy efficiency, and syngas properties under autothermal conditions. The four factors were all the main factors for adiabatic temperature. The exergy efficiency depended more on the operation conditions than on the feedstock type. The H 2 concentration of the dry syngas in biosolid gasification exhibited a curve both against the given temperature under isothermal conditions and against the moisture content under autothermal conditions.

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Biosolid Gasification Performance Prediction Using a Stoichiometric Thermodynamic Model

Li,

Zhang,

2024

ACS Omega

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Evaluating the Technical and Economic Feasibility of Adding a Power Recovery System to the Steam Condenser of a Lignite Coal-Fired Power Plant

Cited by 1 publication

References 16 publications

Biosolid Gasification Performance Prediction Using a Stoichiometric Thermodynamic Model

Biosolid Gasification Performance Prediction Using a Stoichiometric Thermodynamic Model

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