Modelling, dynamics and control of a portable DMFC system. Zenith, F. & Krewer, U. Journal of Process Control, 20(5):630–642, 2010.
doi  abstract   bibtex   
A dynamic model for a direct methanol fuel cell and its ancillary units is presented, in which all ancillary units perform only one operation each. The system's losses and main dynamics (cathodic oxygen fraction, anodic methanol concentration, stack temperature, system water holdup) are analysed for stability and time constants. The system is found to be stable in all of its dynamics except for that of water holdup. The influence of external conditions, such as temperature and humidity, on system feasibility is analysed; the capability of system autonomous operation depends essentially on environmental conditions and on the chosen air excess ratio. Decoupled single-input, single-output controllers, some of which employing feedback, are applied to maintain the system at a certain set point. System simulations are performed, confirming the performance of the proposed controllers, their ability to stabilise the water holdup, and the absence of interaction-induced oscillations; the system can be started up in about ten minutes with the presented parameters. © 2010 Elsevier Ltd. All rights reserved.
@article{zenith_modelling_2010,
	title = {Modelling, dynamics and control of a portable {DMFC} system},
	volume = {20},
	copyright = {All rights reserved},
	issn = {09591524},
	doi = {10.1016/j.jprocont.2010.02.014},
	abstract = {A dynamic model for a direct methanol fuel cell and its ancillary units is presented, in which all ancillary units perform only one operation each. The system's losses and main dynamics (cathodic oxygen fraction, anodic methanol concentration, stack temperature, system water holdup) are analysed for stability and time constants. The system is found to be stable in all of its dynamics except for that of water holdup. The influence of external conditions, such as temperature and humidity, on system feasibility is analysed; the capability of system autonomous operation depends essentially on environmental conditions and on the chosen air excess ratio. Decoupled single-input, single-output controllers, some of which employing feedback, are applied to maintain the system at a certain set point. System simulations are performed, confirming the performance of the proposed controllers, their ability to stabilise the water holdup, and the absence of interaction-induced oscillations; the system can be started up in about ten minutes with the presented parameters. © 2010 Elsevier Ltd. All rights reserved.},
	number = {5},
	journal = {Journal of Process Control},
	author = {Zenith, Federico and Krewer, Ulrike},
	year = {2010},
	keywords = {Autonomy, Control, Dynamics, Fuel cells, Methanol, System},
	pages = {630--642},
}
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