Performance analysis of a micro CHP system based on high temperature PEM fuel cells subjected to degradation

Taccani, Rodolfo; Chinese, T.; Zuliani, Nicola

doi:10.1016/j.egypro.2017.08.198

Cited by 12 publications

(7 citation statements)

References 13 publications

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“…High temperature polymer exchange membrane fuel cells (HT-PEM FC) have entered the market in the last decade [1]. This type of FC is considered as a clean and efficient power source for portable and stationary applications such as combined heat and power (CHP) application, stand-alone power, backup power and uninterrupted power supply (UPS) [2][3][4][5][6]. In HT-PEM FC a polybenzimidazole (PBI) membrane doped with phosphoric acid is used.…”

Section: Introductionmentioning

confidence: 99%

Characterization methodology for anode starvation in HT-PEM fuel cells

Yezerska

Dushina²,

Liu³

et al. 2019

International Journal of Hydrogen Energy

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Degradation caused by fuel starvation may be an important reason for limited fuel cell lifetimes. In this work, we present an analytical characterization of the high temperature polymer exchange membrane fuel cell (HT-PEM FC) behavior under cycled anode starvation and subsequent regeneration conditions to investigate the impact of degradation due to H 2 starvation. Two membrane electrode assemblies (MEAs) with an active area of 21 cm 2 were operated of up to 550 minutes, which included up to 14 starvation / regeneration cycles. Overall cell voltage as well as current density distribution (S ++ unit) were measured simultaneously each minute during FC operation. The cyclicity of experiments was used to check the long term durability of the HT-PEM FC. After FC operation, micro-computed tomography (μ-CT) was applied to evaluate the influence of starvation on anode and cathode catalyst layer thicknesses.During starvation, cell voltage and current density distribution over the active area of the MEA significantly differed from nominal conditions. A significant drop in cell voltage from 0.6 to 0.1 V occured after approx. 20 minutes for the first starvation step, and after 10 minutes for all subsequent starvation steps. By contrast, the voltage response is immediately stable at 0.6 V during every regeneration step.During each starvation, the local current density reached up to 0.3 A•point -1 at the area near the gas inlet (9 cm 2 ) while near the outlet it drops to 0.01 A•point -1 . The deviation from a balanced current density distribution occurred after 10 minutes for the first starvation step, and after ca. 2 minutes for the subsequent starvation steps.Hence, compared to the voltage drop, the deviation from a balanced current density distribution always starts earlier. This indicates that the local current density distribution is more sensitive to local changes in the MEA than overal cell voltage drop. This finding may help to prevent undesirable influences of the starvation process.The μ-CT images showed that H 2 starvation lead to thickness decrease of ca. 20-30 % in both anode and cathode catalyst layers compared to a fresh MEA. Despite of the 14 starvation steps and the thinning of the catalyst layers the MEA presents stable cell voltage during regeneration.

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Section: Introductionmentioning

confidence: 99%

Characterization methodology for anode starvation in HT-PEM fuel cells

Yezerska

Dushina²,

Liu³

et al. 2019

International Journal of Hydrogen Energy

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“…It was shown that electrical, thermal, and co-generation efficiencies of 42.8%, 47.2% and 90% can be obtained. Taccani et al [37] modelled a HTPEMFC-CHP system considering the degradation of the stack in order to evaluate the system performance over one year of operation. The system's performance in terms of electrical and thermal energy production, energy savings, and import/export of electricity from/to the grid was evaluated for four different configurations with and without battery storage.…”

Section: Htpemfc-chpmentioning

confidence: 99%

PEMFC Poly-Generation Systems: Developments, Merits, and Challenges

et al. 2021

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Significant research efforts are directed towards finding new ways to reduce the cost, increase efficiency, and decrease the environmental impact of power-generation systems. The poly-generation concept is a promising strategy that enables the development of a sustainable power system. Over the past few years, the Proton Exchange Membrane Fuel Cell-based Poly-Generation Systems (PEMFC-PGSs) have received accelerated developments due to the low-temperature operation, high efficiency, and low environmental impact. This paper provides a comprehensive review of the main PEMFC-PGSs, including Combined Heat and Power (CHP) co-generation systems, Combined Cooling and Power (CCP) co-generation systems, Combined Cooling, Heat, and Power (CCHP) tri-generation systems, and Combined Water and Power (CWP) co-generation systems. First, the main technologies used in PEMFC-PGSs, such as those related to hydrogen production, energy storage, and Waste Heat Recovery (WHR), etc., are detailed. Then, the research progresses on the economic, energy, and environmental performance of the different PEMFC-PGSs are presented. Also, the recent commercialization activities on these systems are highlighted focusing on the leading countries in this field. Furthermore, the remaining economic and technical obstacles of these systems along with the future research directions to mitigate them are discussed. The review reveals the potential of the PEMFC-PGS in securing a sustainable future of the power systems. However, many economic and technical issues, particularly those related to high cost and degradation rate, still need to be addressed before unlocking the full benefits of such systems.

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“…Due to their easy scale‐up from serving individual homes to large office blocks and industrial complexes, stationary combined heat and power production based on fuel cells (FC‐CHP) is considered as the largest and most established market for fuel cells in near future 1 . The FC‐CHP, which in addition to electricity also provides heat with very high efficiency and low emissions, is a promising technology especially at small scale power production, which is typical for domestic applications 2,3 . Many researchers have paid attention to the FC‐CHP systems in recent years 1–21 …”

Section: Introductionmentioning

confidence: 99%

Improved performance of a residential combined heat and power system by integrating compact fuel processor and proton exchange membrane fuel cell

Zhang

Zhong

et al. 2022

Energy Science & Engineering

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A combined heat and power (CHP) system, which consists of a proton exchange membrane fuel cell and an integrated fuel processor is developed based on solving the energy balance between endothermic and exothermic hydrogen production reactions. The developed system simplifies the traditional complex fuel processing, and only three reactor units are needed—catalytic combustion, new integrated hydrogen production reactor and CO removal. In the novel CHP system, the H2‐rich reformate production from methanol and water is approximately 8 Nm3 h−1 with an H2 concentration of 53%–55% and CO less than 30 ppm. The CHP system was run continuously for more than 1100 h. The power demand was observed to be about 2–9 kW corresponding to the usual load of a residential unit. To increase the whole system efficiency, anode off‐gas (AOG) from fuel cell was returned to the fuel processor and utilized in the catalytic combustion reactor to improve the energy efficiency of the whole system. The average system efficiency can be increased from 60.3% to 67% by utilization of the energy from AOG catalytic combustion.

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Performance analysis of a micro CHP system based on high temperature PEM fuel cells subjected to degradation

Cited by 12 publications

References 13 publications

Characterization methodology for anode starvation in HT-PEM fuel cells

Characterization methodology for anode starvation in HT-PEM fuel cells

PEMFC Poly-Generation Systems: Developments, Merits, and Challenges

Improved performance of a residential combined heat and power system by integrating compact fuel processor and proton exchange membrane fuel cell

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