Safe operating range dynamic analysis, and tuning of the temparature and reactant utilization control for solid oxide cells

Giulia Botta; Matteo Romeo; Alvaro Monteiro Fernandes; Aravind Purushothaman Vellayani

Safe operating range dynamic analysis, and tuning of the temparature and reactant utilization control for solid oxide cells

Giulia Botta, Matteo Romeo, Alvaro Monteiro Fernandes, Aravind Purushothaman Vellayani

Energy Technology

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

Abstract

Solid Oxide Cells systems (SOCs) are increasingly being considered as an electrical energy storage method and therefore as a means to boost the penetration of Renewable Energy and to improve the grid flexibility by power-to-gas electrochemical conversion. However, temperature and reactant utilization control become crucial if the systems are to be used in dynamic operation with intermittent electrical power sources. In the present work, two 1D models of SOC stacks are built and used to study the dynamic behaviour of such stacks, and to select and tune the best control systems. After having compared with literature the accuracy of the models, safe operating ranges are determined to respect the thermal constraints of the stack. The dynamic analysis points out that inputs (m_fuel,m_atr) and outputs (U, ΔT max) are strongly decoupled; therefore, proportionalintegral control strategy has a good potential to prevent dangerous operating conditions in dynamic operation. Finally, the controllers are tuned and their transfer functions are reported.

Original language	English
Title of host publication	Proceedings of EFC2017 - European Fuel Cell Technology & Applications Conference - Piero Lunghi Conference
Editors	V. Cigolotti, C. Barchiesi, M. Chianella
Place of Publication	Rome, Italy
Publisher	ENEA
Pages	455-456
ISBN (Print)	978-88-8286-324-1
Publication status	Published - 2017
Event	7th European Fuel Cell Piero Lunghi Conference - Naples, Italy Duration: 12 Dec 2017 → 15 Dec 2017 http://www.europeanfuelcell.it/images/proceedings_EFC17.pdf

Conference

Conference	7th European Fuel Cell Piero Lunghi Conference
Abbreviated title	EFC17
Country/Territory	Italy
City	Naples
Period	12/12/17 → 15/12/17
Internet address	http://www.europeanfuelcell.it/images/proceedings_EFC17.pdf

UN SDGs

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

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Botta, G., Romeo, M., Monteiro Fernandes, A., & Purushothaman Vellayani, A. (2017). Safe operating range dynamic analysis, and tuning of the temparature and reactant utilization control for solid oxide cells. In V. Cigolotti, C. Barchiesi, & M. Chianella (Eds.), Proceedings of EFC2017 - European Fuel Cell Technology & Applications Conference - Piero Lunghi Conference (pp. 455-456). Article EFC17281 ENEA.

Botta, Giulia ; Romeo, Matteo ; Monteiro Fernandes, Alvaro et al. / Safe operating range dynamic analysis, and tuning of the temparature and reactant utilization control for solid oxide cells. Proceedings of EFC2017 - European Fuel Cell Technology & Applications Conference - Piero Lunghi Conference . editor / V. Cigolotti ; C. Barchiesi ; M. Chianella. Rome, Italy : ENEA, 2017. pp. 455-456

@inproceedings{1d19c732372c4b0880181e4e70969b26,

title = "Safe operating range dynamic analysis, and tuning of the temparature and reactant utilization control for solid oxide cells",

abstract = " Solid Oxide Cells systems (SOCs) are increasingly being considered as an electrical energy storage method and therefore as a means to boost the penetration of Renewable Energy and to improve the grid flexibility by power-to-gas electrochemical conversion. However, temperature and reactant utilization control become crucial if the systems are to be used in dynamic operation with intermittent electrical power sources. In the present work, two 1D models of SOC stacks are built and used to study the dynamic behaviour of such stacks, and to select and tune the best control systems. After having compared with literature the accuracy of the models, safe operating ranges are determined to respect the thermal constraints of the stack. The dynamic analysis points out that inputs (mfuel, matr) and outputs (U, ΔT max) are strongly decoupled; therefore, proportionalintegral control strategy has a good potential to prevent dangerous operating conditions in dynamic operation. Finally, the controllers are tuned and their transfer functions are reported. ",

author = "Giulia Botta and Matteo Romeo and {Monteiro Fernandes}, Alvaro and {Purushothaman Vellayani}, Aravind",

year = "2017",

language = "English",

isbn = "978-88-8286-324-1",

pages = "455--456",

editor = "Cigolotti, {V. } and C. Barchiesi and M. Chianella",

booktitle = "Proceedings of EFC2017 - European Fuel Cell Technology & Applications Conference - Piero Lunghi Conference",

publisher = "ENEA",

note = "7th European Fuel Cell Piero Lunghi Conference, EFC17 ; Conference date: 12-12-2017 Through 15-12-2017",

url = "http://www.europeanfuelcell.it/images/proceedings_EFC17.pdf",

}

Botta, G, Romeo, M, Monteiro Fernandes, A & Purushothaman Vellayani, A 2017, Safe operating range dynamic analysis, and tuning of the temparature and reactant utilization control for solid oxide cells. in V Cigolotti, C Barchiesi & M Chianella (eds), Proceedings of EFC2017 - European Fuel Cell Technology & Applications Conference - Piero Lunghi Conference ., EFC17281, ENEA, Rome, Italy, pp. 455-456, 7th European Fuel Cell Piero Lunghi Conference, Naples, Italy, 12/12/17.

Safe operating range dynamic analysis, and tuning of the temparature and reactant utilization control for solid oxide cells. / Botta, Giulia; Romeo, Matteo; Monteiro Fernandes, Alvaro et al.
Proceedings of EFC2017 - European Fuel Cell Technology & Applications Conference - Piero Lunghi Conference . ed. / V. Cigolotti; C. Barchiesi; M. Chianella. Rome, Italy: ENEA, 2017. p. 455-456 EFC17281.

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

TY - GEN

T1 - Safe operating range dynamic analysis, and tuning of the temparature and reactant utilization control for solid oxide cells

AU - Botta, Giulia

AU - Romeo, Matteo

AU - Monteiro Fernandes, Alvaro

AU - Purushothaman Vellayani, Aravind

PY - 2017

Y1 - 2017

N2 - Solid Oxide Cells systems (SOCs) are increasingly being considered as an electrical energy storage method and therefore as a means to boost the penetration of Renewable Energy and to improve the grid flexibility by power-to-gas electrochemical conversion. However, temperature and reactant utilization control become crucial if the systems are to be used in dynamic operation with intermittent electrical power sources. In the present work, two 1D models of SOC stacks are built and used to study the dynamic behaviour of such stacks, and to select and tune the best control systems. After having compared with literature the accuracy of the models, safe operating ranges are determined to respect the thermal constraints of the stack. The dynamic analysis points out that inputs (mfuel, matr) and outputs (U, ΔT max) are strongly decoupled; therefore, proportionalintegral control strategy has a good potential to prevent dangerous operating conditions in dynamic operation. Finally, the controllers are tuned and their transfer functions are reported.

AB - Solid Oxide Cells systems (SOCs) are increasingly being considered as an electrical energy storage method and therefore as a means to boost the penetration of Renewable Energy and to improve the grid flexibility by power-to-gas electrochemical conversion. However, temperature and reactant utilization control become crucial if the systems are to be used in dynamic operation with intermittent electrical power sources. In the present work, two 1D models of SOC stacks are built and used to study the dynamic behaviour of such stacks, and to select and tune the best control systems. After having compared with literature the accuracy of the models, safe operating ranges are determined to respect the thermal constraints of the stack. The dynamic analysis points out that inputs (mfuel, matr) and outputs (U, ΔT max) are strongly decoupled; therefore, proportionalintegral control strategy has a good potential to prevent dangerous operating conditions in dynamic operation. Finally, the controllers are tuned and their transfer functions are reported.

UR - http://www.europeanfuelcell.it/images/proceedings_EFC17.pdf

M3 - Conference contribution

SN - 978-88-8286-324-1

SP - 455

EP - 456

BT - Proceedings of EFC2017 - European Fuel Cell Technology & Applications Conference - Piero Lunghi Conference

A2 - Cigolotti, V.

A2 - Barchiesi, C.

A2 - Chianella, M.

PB - ENEA

CY - Rome, Italy

T2 - 7th European Fuel Cell Piero Lunghi Conference

Y2 - 12 December 2017 through 15 December 2017

ER -

Botta G, Romeo M, Monteiro Fernandes A, Purushothaman Vellayani A. Safe operating range dynamic analysis, and tuning of the temparature and reactant utilization control for solid oxide cells. In Cigolotti V, Barchiesi C, Chianella M, editors, Proceedings of EFC2017 - European Fuel Cell Technology & Applications Conference - Piero Lunghi Conference . Rome, Italy: ENEA. 2017. p. 455-456. EFC17281

Safe operating range dynamic analysis, and tuning of the temparature and reactant utilization control for solid oxide cells

Abstract

Conference

UN SDGs

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