Thermochemical Recuperation of the Exhaust Gas Heat in Combined-Cycle Units: Thermodynamic Analysis

D. I. Pashchenko

doi:10.1134/S0040601523010056

Thermochemical Recuperation of the Exhaust Gas Heat in Combined-Cycle Units: Thermodynamic Analysis

D. I. Pashchenko^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

Abstract: A scheme of a combined-cycle unit with thermochemical recuperation of flue gas heat using methane steam reforming is considered. The essence of thermochemical recuperation is the recovery of flue gas heat for the endothermic methane reforming yielding a new synthetic fuel. The results are presented of a thermodynamic analysis of the combined-cycle unit thermal cycle with a gas turbine inlet temperature of 1500 and 1600°C at a pressure in the combustion chamber from 2 to 4 MPa. The thermodynamic analysis of the thermal cycle of a combined cycle unit was performed using the Aspen HYSYS software package, and the thermodynamic analysis of methane steam reforming was performed using the Gibbs free energy minimization method. The efficiency of thermochemical recuperation of flue gas heat has been demonstrated to depend on the process conditions, such as pressure, temperature, and composition of the initial reaction mixture. Increasing the temperature and the steam to methane ratio increases the reaction enthalpy and the efficiency of methane reforming, while an increase in the pressure decreases these parameters. It has been found that the thermochemical recuperation of heat can increase the effectiveness of a conventional combined-cycle unit by 3–5%. For example, the efficiency of a combined-cycle unit is 59% without thermochemical recuperation or 64% with thermochemical recuperation at a turbine inlet temperature of 1600°С and a compression ratio of 30. The thermal and material balances of a combined-cycle unit with thermochemical heat recuperation are presented in the form of energy and material flows, according to which 45% of the exhaust gas heat is recuperated in the fuel cycle of the gas turbine unit and approximately 45% of the exhaust gas heat is consumed in the steam turbine cycle.

Original language	English
Pages (from-to)	48-54
Number of pages	7
Journal	Thermal Engineering (English translation of Teploenergetika)
Volume	70
Issue number	1
DOIs	https://doi.org/10.1134/S0040601523010056
State	Published - Jan 2023
Externally published	Yes

Keywords

combined-cycle unit
energy efficiency
methane reforming
methane steam reforming
reaction enthalpy
thermochemical recuperation
thermodynamic analysis

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1134/S0040601523010056

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title = "Thermochemical Recuperation of the Exhaust Gas Heat in Combined-Cycle Units: Thermodynamic Analysis",

abstract = "Abstract: A scheme of a combined-cycle unit with thermochemical recuperation of flue gas heat using methane steam reforming is considered. The essence of thermochemical recuperation is the recovery of flue gas heat for the endothermic methane reforming yielding a new synthetic fuel. The results are presented of a thermodynamic analysis of the combined-cycle unit thermal cycle with a gas turbine inlet temperature of 1500 and 1600°C at a pressure in the combustion chamber from 2 to 4 MPa. The thermodynamic analysis of the thermal cycle of a combined cycle unit was performed using the Aspen HYSYS software package, and the thermodynamic analysis of methane steam reforming was performed using the Gibbs free energy minimization method. The efficiency of thermochemical recuperation of flue gas heat has been demonstrated to depend on the process conditions, such as pressure, temperature, and composition of the initial reaction mixture. Increasing the temperature and the steam to methane ratio increases the reaction enthalpy and the efficiency of methane reforming, while an increase in the pressure decreases these parameters. It has been found that the thermochemical recuperation of heat can increase the effectiveness of a conventional combined-cycle unit by 3–5%. For example, the efficiency of a combined-cycle unit is 59% without thermochemical recuperation or 64% with thermochemical recuperation at a turbine inlet temperature of 1600°С and a compression ratio of 30. The thermal and material balances of a combined-cycle unit with thermochemical heat recuperation are presented in the form of energy and material flows, according to which 45% of the exhaust gas heat is recuperated in the fuel cycle of the gas turbine unit and approximately 45% of the exhaust gas heat is consumed in the steam turbine cycle.",

keywords = "combined-cycle unit, energy efficiency, methane reforming, methane steam reforming, reaction enthalpy, thermochemical recuperation, thermodynamic analysis",

author = "Pashchenko, {D. I.}",

note = "Publisher Copyright: {\textcopyright} 2023, Pleiades Publishing, Inc.",

year = "2023",

month = jan,

doi = "10.1134/S0040601523010056",

language = "英语",

volume = "70",

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journal = "Thermal Engineering (English translation of Teploenergetika)",

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T1 - Thermochemical Recuperation of the Exhaust Gas Heat in Combined-Cycle Units

T2 - Thermodynamic Analysis

AU - Pashchenko, D. I.

PY - 2023/1

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N2 - Abstract: A scheme of a combined-cycle unit with thermochemical recuperation of flue gas heat using methane steam reforming is considered. The essence of thermochemical recuperation is the recovery of flue gas heat for the endothermic methane reforming yielding a new synthetic fuel. The results are presented of a thermodynamic analysis of the combined-cycle unit thermal cycle with a gas turbine inlet temperature of 1500 and 1600°C at a pressure in the combustion chamber from 2 to 4 MPa. The thermodynamic analysis of the thermal cycle of a combined cycle unit was performed using the Aspen HYSYS software package, and the thermodynamic analysis of methane steam reforming was performed using the Gibbs free energy minimization method. The efficiency of thermochemical recuperation of flue gas heat has been demonstrated to depend on the process conditions, such as pressure, temperature, and composition of the initial reaction mixture. Increasing the temperature and the steam to methane ratio increases the reaction enthalpy and the efficiency of methane reforming, while an increase in the pressure decreases these parameters. It has been found that the thermochemical recuperation of heat can increase the effectiveness of a conventional combined-cycle unit by 3–5%. For example, the efficiency of a combined-cycle unit is 59% without thermochemical recuperation or 64% with thermochemical recuperation at a turbine inlet temperature of 1600°С and a compression ratio of 30. The thermal and material balances of a combined-cycle unit with thermochemical heat recuperation are presented in the form of energy and material flows, according to which 45% of the exhaust gas heat is recuperated in the fuel cycle of the gas turbine unit and approximately 45% of the exhaust gas heat is consumed in the steam turbine cycle.

AB - Abstract: A scheme of a combined-cycle unit with thermochemical recuperation of flue gas heat using methane steam reforming is considered. The essence of thermochemical recuperation is the recovery of flue gas heat for the endothermic methane reforming yielding a new synthetic fuel. The results are presented of a thermodynamic analysis of the combined-cycle unit thermal cycle with a gas turbine inlet temperature of 1500 and 1600°C at a pressure in the combustion chamber from 2 to 4 MPa. The thermodynamic analysis of the thermal cycle of a combined cycle unit was performed using the Aspen HYSYS software package, and the thermodynamic analysis of methane steam reforming was performed using the Gibbs free energy minimization method. The efficiency of thermochemical recuperation of flue gas heat has been demonstrated to depend on the process conditions, such as pressure, temperature, and composition of the initial reaction mixture. Increasing the temperature and the steam to methane ratio increases the reaction enthalpy and the efficiency of methane reforming, while an increase in the pressure decreases these parameters. It has been found that the thermochemical recuperation of heat can increase the effectiveness of a conventional combined-cycle unit by 3–5%. For example, the efficiency of a combined-cycle unit is 59% without thermochemical recuperation or 64% with thermochemical recuperation at a turbine inlet temperature of 1600°С and a compression ratio of 30. The thermal and material balances of a combined-cycle unit with thermochemical heat recuperation are presented in the form of energy and material flows, according to which 45% of the exhaust gas heat is recuperated in the fuel cycle of the gas turbine unit and approximately 45% of the exhaust gas heat is consumed in the steam turbine cycle.

KW - combined-cycle unit

KW - energy efficiency

KW - methane reforming

KW - methane steam reforming

KW - reaction enthalpy

KW - thermochemical recuperation

KW - thermodynamic analysis

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JO - Thermal Engineering (English translation of Teploenergetika)

JF - Thermal Engineering (English translation of Teploenergetika)

IS - 1

ER -

Thermochemical Recuperation of the Exhaust Gas Heat in Combined-Cycle Units: Thermodynamic Analysis

Abstract

Keywords

UN SDGs

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