Heat Recovery Modeling and Exergy Analysis of Dry Combustion Process for Explosive Gas Treatment Using Aspen Plus

Y. Choi; C. Choi; B. Hong; S. Choi; Y. Kim; H. Kim

doi:10.5572/KOSAE.2017.33.5.521

Heat Recovery Modeling and Exergy Analysis of Dry Combustion Process for Explosive Gas Treatment Using Aspen Plus

Y. Choi, C. Choi, B. Hong, S. Choi, Y. Kim, H. Kim

Institute of Photonic System

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

7 Scopus citations

Abstract

In the combustion treatment of explosive gases with a high heating value such as H2 and NH3 used in semiconductor and chemical processes, the heat recovery modeling and exergy analysis of the process using the Aspen Plus simulator and its thermodynamic data were performed to examine the recovery of high temperature thermal energy. The heat recovery process was analyzed through this process modeling while the exergy results clearly confirmed that the rigorous reaction mainly occurs in the condenser and the chamber. In addition, the process modeling demonstrated that approximately 95% of the exergy is destructed on the basis of the exergies injected and the exergy being exhausted. Using the exergy technique, which can quantitatively analyze the energy, we could understand the energy flow in the process and confirm that our heat recovery process was efficiently designed.

Original language	Korean
Pages (from-to)	521-528
Number of pages	8
Journal	Journal of Korean Society for Atmospheric Environment
Volume	33
Issue number	5
DOIs	https://doi.org/10.5572/KOSAE.2017.33.5.521
State	Published - 31 Oct 2017

Keywords

Heat recovery modeling
Exergy analysis
Dry combustion process
Aspen Plus
Explosive gas treatment
Process modeling

Access to Document

10.5572/KOSAE.2017.33.5.521

Cite this

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title = "Heat Recovery Modeling and Exergy Analysis of Dry Combustion Process for Explosive Gas Treatment Using Aspen Plus",

abstract = "In the combustion treatment of explosive gases with a high heating value such as H2 and NH3 used in semiconductor and chemical processes, the heat recovery modeling and exergy analysis of the process using the Aspen Plus simulator and its thermodynamic data were performed to examine the recovery of high temperature thermal energy. The heat recovery process was analyzed through this process modeling while the exergy results clearly confirmed that the rigorous reaction mainly occurs in the condenser and the chamber. In addition, the process modeling demonstrated that approximately 95% of the exergy is destructed on the basis of the exergies injected and the exergy being exhausted. Using the exergy technique, which can quantitatively analyze the energy, we could understand the energy flow in the process and confirm that our heat recovery process was efficiently designed.",

keywords = "Heat recovery modeling, Exergy analysis, Dry combustion process, Aspen Plus, Explosive gas treatment, Process modeling",

author = "Y. Choi and C. Choi and B. Hong and S. Choi and Y. Kim and H. Kim",

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TY - JOUR

T1 - Heat Recovery Modeling and Exergy Analysis of Dry Combustion Process for Explosive Gas Treatment Using Aspen Plus

AU - Choi, Y.

AU - Choi, C.

AU - Hong, B.

AU - Choi, S.

AU - Kim, Y.

AU - Kim, H.

PY - 2017/10/31

Y1 - 2017/10/31

N2 - In the combustion treatment of explosive gases with a high heating value such as H2 and NH3 used in semiconductor and chemical processes, the heat recovery modeling and exergy analysis of the process using the Aspen Plus simulator and its thermodynamic data were performed to examine the recovery of high temperature thermal energy. The heat recovery process was analyzed through this process modeling while the exergy results clearly confirmed that the rigorous reaction mainly occurs in the condenser and the chamber. In addition, the process modeling demonstrated that approximately 95% of the exergy is destructed on the basis of the exergies injected and the exergy being exhausted. Using the exergy technique, which can quantitatively analyze the energy, we could understand the energy flow in the process and confirm that our heat recovery process was efficiently designed.

AB - In the combustion treatment of explosive gases with a high heating value such as H2 and NH3 used in semiconductor and chemical processes, the heat recovery modeling and exergy analysis of the process using the Aspen Plus simulator and its thermodynamic data were performed to examine the recovery of high temperature thermal energy. The heat recovery process was analyzed through this process modeling while the exergy results clearly confirmed that the rigorous reaction mainly occurs in the condenser and the chamber. In addition, the process modeling demonstrated that approximately 95% of the exergy is destructed on the basis of the exergies injected and the exergy being exhausted. Using the exergy technique, which can quantitatively analyze the energy, we could understand the energy flow in the process and confirm that our heat recovery process was efficiently designed.

KW - Heat recovery modeling

KW - Exergy analysis

KW - Dry combustion process

KW - Aspen Plus

KW - Explosive gas treatment

KW - Process modeling

U2 - 10.5572/KOSAE.2017.33.5.521

DO - 10.5572/KOSAE.2017.33.5.521

M3 - Article

VL - 33

SP - 521

EP - 528

JO - Journal of Korean Society for Atmospheric Environment

JF - Journal of Korean Society for Atmospheric Environment

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