Analysis of an intermediate-temperature proton-conducting sofc hybrid system

Tzu Yuan Huang; Chi Fu Chen; Sheng Wei Lee; Kan Rong Lee; Chung Jen Tseng; Jason Shian Ching Jang

Analysis of an intermediate-temperature proton-conducting sofc hybrid system

Tzu Yuan Huang, Chi Fu Chen, Sheng Wei Lee, Kan Rong Lee, Chung Jen Tseng, Jason Shian Ching Jang

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

The performance of an intermediate-temperature (IT) proton-conducting solid oxide fuel cell (pSOFC) hybrid system is investigated in this work. The hybrid system consists of a 25-kW pSOFC, a micro gas turbine (MGT), and heat exchangers. Heat exchangers are used to recover the waste heat from SOFC and GT. The performance of the systems are simulated by using Matlab/Simulink/Thermolib. Flow rates of air and hydrogen are controlled by assigning different stoichiometric ratio (St). St considered in this study is 2~4 for air, and 1.3~1.5 for hydrogen. The operating temperature range is 500°C~700°C. Results show that the combined system efficiency increases as the fuel St decreases or air St increases. This is because lower fuel St means fewer fuel would be wasted from the fuel cell stack, so the combined system efficiency increases. On the other hand, as air St increases, the amount of recovered waste heat increases, and so does the combined system efficiency. The dynamic characteristic of the system is also simulated, and results show that air St does not have great influence on the startup time.

Original language	English
Title of host publication	20th World Hydrogen Energy Conference, WHEC 2014
Publisher	Committee of WHEC2014
Pages	1866-1871
Number of pages	6
ISBN (Electronic)	9780000000002
State	Published - 2014
Event	20th World Hydrogen Energy Conference, WHEC 2014 - Gwangju, Korea, Republic of Duration: 15 Jun 2014 → 20 Jun 2014

Publication series

Name	20th World Hydrogen Energy Conference, WHEC 2014
Volume	3

Conference

Conference	20th World Hydrogen Energy Conference, WHEC 2014
Country/Territory	Korea, Republic of
City	Gwangju
Period	15/06/14 → 20/06/14

Keywords

Hybrid system
Intermediate-temperature
pSOFC
Stoichiometric ratio
System simulation

UN SDGs

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

Cite this

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title = "Analysis of an intermediate-temperature proton-conducting sofc hybrid system",

abstract = "The performance of an intermediate-temperature (IT) proton-conducting solid oxide fuel cell (pSOFC) hybrid system is investigated in this work. The hybrid system consists of a 25-kW pSOFC, a micro gas turbine (MGT), and heat exchangers. Heat exchangers are used to recover the waste heat from SOFC and GT. The performance of the systems are simulated by using Matlab/Simulink/Thermolib. Flow rates of air and hydrogen are controlled by assigning different stoichiometric ratio (St). St considered in this study is 2~4 for air, and 1.3~1.5 for hydrogen. The operating temperature range is 500°C~700°C. Results show that the combined system efficiency increases as the fuel St decreases or air St increases. This is because lower fuel St means fewer fuel would be wasted from the fuel cell stack, so the combined system efficiency increases. On the other hand, as air St increases, the amount of recovered waste heat increases, and so does the combined system efficiency. The dynamic characteristic of the system is also simulated, and results show that air St does not have great influence on the startup time.",

keywords = "Hybrid system, Intermediate-temperature, pSOFC, Stoichiometric ratio, System simulation",

author = "Huang, {Tzu Yuan} and Chen, {Chi Fu} and Lee, {Sheng Wei} and Lee, {Kan Rong} and Tseng, {Chung Jen} and Jang, {Jason Shian Ching}",

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note = "null ; Conference date: 15-06-2014 Through 20-06-2014",

}

Huang, TY, Chen, CF, Lee, SW, Lee, KR, Tseng, CJ & Jang, JSC 2014, Analysis of an intermediate-temperature proton-conducting sofc hybrid system. in 20th World Hydrogen Energy Conference, WHEC 2014. 20th World Hydrogen Energy Conference, WHEC 2014, vol. 3, Committee of WHEC2014, pp. 1866-1871, 20th World Hydrogen Energy Conference, WHEC 2014, Gwangju, Korea, Republic of, 15/06/14.

Analysis of an intermediate-temperature proton-conducting sofc hybrid system. / Huang, Tzu Yuan; Chen, Chi Fu; Lee, Sheng Wei et al.

20th World Hydrogen Energy Conference, WHEC 2014. Committee of WHEC2014, 2014. p. 1866-1871 (20th World Hydrogen Energy Conference, WHEC 2014; Vol. 3).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Analysis of an intermediate-temperature proton-conducting sofc hybrid system

AU - Huang, Tzu Yuan

AU - Chen, Chi Fu

AU - Lee, Sheng Wei

AU - Lee, Kan Rong

AU - Tseng, Chung Jen

AU - Jang, Jason Shian Ching

PY - 2014

Y1 - 2014

N2 - The performance of an intermediate-temperature (IT) proton-conducting solid oxide fuel cell (pSOFC) hybrid system is investigated in this work. The hybrid system consists of a 25-kW pSOFC, a micro gas turbine (MGT), and heat exchangers. Heat exchangers are used to recover the waste heat from SOFC and GT. The performance of the systems are simulated by using Matlab/Simulink/Thermolib. Flow rates of air and hydrogen are controlled by assigning different stoichiometric ratio (St). St considered in this study is 2~4 for air, and 1.3~1.5 for hydrogen. The operating temperature range is 500°C~700°C. Results show that the combined system efficiency increases as the fuel St decreases or air St increases. This is because lower fuel St means fewer fuel would be wasted from the fuel cell stack, so the combined system efficiency increases. On the other hand, as air St increases, the amount of recovered waste heat increases, and so does the combined system efficiency. The dynamic characteristic of the system is also simulated, and results show that air St does not have great influence on the startup time.

AB - The performance of an intermediate-temperature (IT) proton-conducting solid oxide fuel cell (pSOFC) hybrid system is investigated in this work. The hybrid system consists of a 25-kW pSOFC, a micro gas turbine (MGT), and heat exchangers. Heat exchangers are used to recover the waste heat from SOFC and GT. The performance of the systems are simulated by using Matlab/Simulink/Thermolib. Flow rates of air and hydrogen are controlled by assigning different stoichiometric ratio (St). St considered in this study is 2~4 for air, and 1.3~1.5 for hydrogen. The operating temperature range is 500°C~700°C. Results show that the combined system efficiency increases as the fuel St decreases or air St increases. This is because lower fuel St means fewer fuel would be wasted from the fuel cell stack, so the combined system efficiency increases. On the other hand, as air St increases, the amount of recovered waste heat increases, and so does the combined system efficiency. The dynamic characteristic of the system is also simulated, and results show that air St does not have great influence on the startup time.

KW - Hybrid system

KW - Intermediate-temperature

KW - pSOFC

KW - Stoichiometric ratio

KW - System simulation

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M3 - 會議論文篇章

AN - SCOPUS:84924915390

T3 - 20th World Hydrogen Energy Conference, WHEC 2014

SP - 1866

EP - 1871

BT - 20th World Hydrogen Energy Conference, WHEC 2014

PB - Committee of WHEC2014

Y2 - 15 June 2014 through 20 June 2014

ER -

Analysis of an intermediate-temperature proton-conducting sofc hybrid system

Abstract

Publication series

Conference

Keywords

UN SDGs

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