FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W642562929> ?p ?o ?g. }

• W642562929 abstract "This thesis deals with control of fuel cells, focusing on high-temperature proton-exchange-membrane fuel cells.Fuel cells are devices that convert the chemical energy of hydrogen, methanol or other chemical compounds directly into electricity, without combustion or thermal cycles. They are efficient, scalable and silent devices that can provide power to a wide variety of utilities, from portable electronics to vehicles, to nation-wide electric grids.Whereas studies about the design of fuel cell systems and the electrochemical properties of their components abound in the open literature, there has been only a minor interest, albeit growing, in dynamics and control of fuel cells.In the relatively small body of available literature, there are some apparently contradictory statements: sometimes the slow dynamics of fuel cells is claimed to present a control problem, whereas in other articles fuel cells are claimed to be easy to control and able to follow references that change very rapidly. These contradictions are mainly caused by differences in the sets of phenomena and dynamics that the authors decided to investigate, and also by how they formulated the control problem. For instance, there is little doubt that the temperature dynamics of a fuel cell can be slow, but users are not concerned with the cell’s temperature: power output is a much more important measure of performance.Fuel cells are very multidisciplinary systems, where electrical engineering, electrochemistry, chemical engineering and materials science are all involved at various levels; it is therefore unsurprising that few researchers can master all of these branches, and that most of them will neglect or misinterpret phenomena they are unfamiliar with.The ambition of this thesis is to consider the main phenomena influencing the dynamics of fuel cells, to properly define the control problem and suggest possible approaches and solutions to it.This thesis will focus on a particular type of fuel cell, a variation of proton-exchange-membrane fuel cells with a membrane of polybenzimidazole instead of the usual, commercially available Nafion. The advantages of this particular type of fuel cells for control are particularly interesting, and stem from their operation at temperatures higher than those typical of Nafion-based cells: these new cells do not have any water-management issues, can remove more heat with their exhaust gases, and have better tolerance to poisons such as carbon monoxide.The first part of this thesis will be concerned with defining and modelling the dynamic phenomena of interest. Indeed, a common mistake is to assume that fuel cells have a single dynamics: instead, many phenomena with radically different time scales concur to define a fuel-cell stack’s overall behaviour. The dynamics of interest are those of chemical engineering (heat and mass balances), of electrochemistry (diffusion in electrodes, electrochemical catalysis) and of electrical engineering (converters, inverters and electric motors). The first part of the thesis will first present some experimental results of importance for the electrochemical transient, and will then develop the equations required to model the four dynamic modes chosen to represent a fuel-cell system running on hydrogen and air at atmospheric pressure: cathodic overvoltage, hydrogen pressure in the anode, oxygen fraction in the cathode and stack temperature.The second part will explore some of the possible approaches to control the power output from a fuel-cell stack. It has been attempted to produce a modularised set of controllers, one for each dynamics to control. It is a major point of the thesis, however, that the task of controlling a fuel cell is to be judged exclusively by its final result, that is power delivery: all other control loops, however independent, will have to be designed bearing that goal in mind.The overvoltage, which corresponds nonlinearly to the rate of reaction, is controlled by operating a buck-boost DC/DC converter, which in turn is modelled and controlled with switching rules. Hydrogen pressure, being described by an unstable dynamic equation, requires feedback to be controlled. A controller with PI feedback and a feedforward part to improve performance is suggested. The oxygen fraction in the cathodic stream cannot be easily measured with a satisfactory bandwidth, but its dynamics is stable and disturbances can be measured quite precisely: it is therefore suggested to use a feedforward controller. Contrary to the most common approach for Nafion-based fuel cells, temperature is not controlled with a separate cooling loop: instead, the air flow is used to cool the fuel-cell stack. This significantly simplifies the stack design, operation and production cost. To control temperature, it is suggested to use a P controller, possibly with a feedforward component. Simulations show that this approach to stack cooling is feasible and poses no or few additional requirements on the air flow actuator that is necessary to control air composition in the cathode." @default.
• W642562929 created "2016-06-24" @default.
• W642562929 creator A5071141459 @default.
• W642562929 date "2007-01-01" @default.
• W642562929 modified "2023-09-26" @default.
• W642562929 title "Control of Fuel Cells" @default.
• W642562929 cites W1487127700 @default.
• W642562929 cites W1496415811 @default.
• W642562929 cites W1552880419 @default.
• W642562929 cites W1556142187 @default.
• W642562929 cites W1568001471 @default.
• W642562929 cites W1573847156 @default.
• W642562929 cites W1575311951 @default.
• W642562929 cites W1625530224 @default.
• W642562929 cites W1628052728 @default.
• W642562929 cites W1940259073 @default.
• W642562929 cites W1964891023 @default.
• W642562929 cites W1965319177 @default.
• W642562929 cites W1965602462 @default.
• W642562929 cites W1968411287 @default.
• W642562929 cites W1970782643 @default.
• W642562929 cites W1972085311 @default.
• W642562929 cites W1979859390 @default.
• W642562929 cites W1982944379 @default.
• W642562929 cites W1987720865 @default.
• W642562929 cites W1990211013 @default.
• W642562929 cites W1995728021 @default.
• W642562929 cites W1995774411 @default.
• W642562929 cites W1997473503 @default.
• W642562929 cites W1998101040 @default.
• W642562929 cites W1998179432 @default.
• W642562929 cites W1999468792 @default.
• W642562929 cites W2000981182 @default.
• W642562929 cites W2014959853 @default.
• W642562929 cites W2015897621 @default.
• W642562929 cites W2018104280 @default.
• W642562929 cites W2020919627 @default.
• W642562929 cites W2022173361 @default.
• W642562929 cites W2022518288 @default.
• W642562929 cites W2026331549 @default.
• W642562929 cites W2029346163 @default.
• W642562929 cites W2030048462 @default.
• W642562929 cites W2034126404 @default.
• W642562929 cites W2036032847 @default.
• W642562929 cites W2041721054 @default.
• W642562929 cites W2043904343 @default.
• W642562929 cites W2047318288 @default.
• W642562929 cites W2048121609 @default.
• W642562929 cites W2048963688 @default.
• W642562929 cites W2057203002 @default.
• W642562929 cites W2060272995 @default.
• W642562929 cites W2067892879 @default.
• W642562929 cites W2068692440 @default.
• W642562929 cites W2071885302 @default.
• W642562929 cites W2078123740 @default.
• W642562929 cites W2088462148 @default.
• W642562929 cites W2089487238 @default.
• W642562929 cites W2092065994 @default.
• W642562929 cites W2113433055 @default.
• W642562929 cites W2117483332 @default.
• W642562929 cites W2121859185 @default.
• W642562929 cites W2138844672 @default.
• W642562929 cites W2139749363 @default.
• W642562929 cites W2152101949 @default.
• W642562929 cites W2164594921 @default.
• W642562929 cites W2166520173 @default.
• W642562929 cites W2170400117 @default.
• W642562929 cites W2493886389 @default.
• W642562929 cites W2623785075 @default.
• W642562929 cites W2966083286 @default.
• W642562929 cites W3001973434 @default.
• W642562929 cites W318992741 @default.
• W642562929 cites W598286687 @default.
• W642562929 cites W73172794 @default.
• W642562929 cites W756931401 @default.
• W642562929 cites W1881122619 @default.
• W642562929 cites W2040274044 @default.
• W642562929 cites W2151641503 @default.
• W642562929 hasPublicationYear "2007" @default.
• W642562929 type Work @default.
• W642562929 sameAs 642562929 @default.
• W642562929 citedByCount "5" @default.
• W642562929 countsByYear W6425629292013 @default.
• W642562929 crossrefType "dissertation" @default.
• W642562929 hasAuthorship W642562929A5071141459 @default.
• W642562929 hasConcept C103689191 @default.
• W642562929 hasConcept C127413603 @default.
• W642562929 hasConcept C132319479 @default.
• W642562929 hasConcept C147789679 @default.
• W642562929 hasConcept C153465999 @default.
• W642562929 hasConcept C171250308 @default.
• W642562929 hasConcept C17525397 @default.
• W642562929 hasConcept C178790620 @default.
• W642562929 hasConcept C185592680 @default.
• W642562929 hasConcept C192562407 @default.
• W642562929 hasConcept C21880701 @default.
• W642562929 hasConcept C22547674 @default.
• W642562929 hasConcept C2987658370 @default.
• W642562929 hasConcept C41008148 @default.
• W642562929 hasConcept C42360764 @default.

• next