Passive Fuel Cell Heat Recovery Using Heat Pipes to Enhance Metal Hydride Canisters Hydrogen Discharge Rate: An Experimental Simulation

Tetuko, Anggito P.; Shabani, Bahman; Andrews, John

doi:10.3390/en11040915

Cited by 28 publications

(8 citation statements)

References 87 publications

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“…The results showed that the application of a heat pipe can keep the temperature of the PEMFC within the ideal range and achieve a better temperature uniformity. Tetuko et al − established a passive thermal bridge between the PEMFC and metal hydrogen canisters using passive cooling and a circular heat pipe of high thermal conductivity. They flattened the evaporation section and got it integrated into the PEMFC.…”

Section: Micro Heat Pipe Coupled Proton Exchange Membrane Fuel Cellmentioning

confidence: 99%

A Review of MHP Technology and Its Research Status in Cooling of Li-Ion Power Battery and PEMFC

Chang

et al. 2020

Energy Fuels

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A lithium-ion (Li-ion) power battery and proton exchange membrane fuel cell (PEMFC) have an excellent electrical conversion performance, which makes them a hot spot in the new energy power research field. Electricity is generated inside the battery through an electrochemical reaction, during which time a large amount of heat is also generated. The ideal operating temperature of a Li-ion battery and PEMFC falls into a small range, but the operations require a high temperature uniformity. Efficient cooling technology can be used to timely discharge the heat generated and control the temperature field change inside the battery, thus ensuring the battery's efficient and stable performance. The micro heat pipe (MHP) is currently a more efficient passive cooling equipment with high heat fluxes and a high thermal conductivity through the phase change heat transfer of working fluid. The development and research status of an MHP and its application in the cooling of a Li-ion power battery and PEMFC are reviewed in this paper.

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Section: Micro Heat Pipe Coupled Proton Exchange Membrane Fuel Cellmentioning

confidence: 99%

A Review of MHP Technology and Its Research Status in Cooling of Li-Ion Power Battery and PEMFC

Chang

et al. 2020

Energy Fuels

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“…The excess hydrogen available can be part of the solution to lift this barrier and encourage the utilisation of hydrogen fuel cell vehicles. It is important to consider this point that hydrogen fuel cell systems generate heat, as well as electricity [67,68]. Part of the total heat generated by the fuel cell that is available for recovery (i.e., Q in W) can be calculated from the following equation [69]:…”

Section: Alternative Scenariosmentioning

confidence: 99%

Hydrogen as a Long-Term Large-Scale Energy Storage Solution to Support Renewables

2018

Self Cite

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This paper presents a case study of using hydrogen for large-scale long-term storage application to support the current electricity generation mix of South Australia state in Australia, which primarily includes gas, wind and solar. For this purpose two cases of battery energy storage and hybrid battery-hydrogen storage systems to support solar and wind energy inputs were compared from a techno-economical point of view. Hybrid battery-hydrogen storage system was found to be more cost competitive with unit cost of electricity at $0.626/kWh (US dollar) compared to battery-only energy storage systems with a $2.68/kWh unit cost of electricity. This research also found that the excess stored hydrogen can be further utilised to generate extra electricity. Further utilisation of generated electricity can be incorporated to meet the load demand by either decreasing the base load supply from gas in the present scenario or exporting it to neighbouring states to enhance economic viability of the system. The use of excess stored hydrogen to generate extra electricity further reduced the cost to $0.494/kWh.

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“…Figure 1 shows a sketch of the ability to transfer electrons Fe2+ and Fe3+ due to oxidation and reduction processes [2] . Magnetite (Fe3O4) nanoparticles are used in several applications, such as nanofluid for heat transfer applications [3][4] , thermal conduktivity, density and adsorbent materials [5][6][7][8] .…”

Section: Introductionmentioning

confidence: 99%

The Effect of Tetraethil OrthoCilicate (TEOS) on Fe3O4 Nanoparticles Addition in Electrical

Dayana,

Satria,

Rianna

2024

Indonesian J Appl Phys

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Magnetite Nanoparticles of pure (Fe3O4) and Fe3O4 with TEOS addition have been successfully synthesized from natural iron sand using the coprecipitation method. The purpose of this study is to provide information on the effect of TEOS to Fe3O4 on the electrical properties. The effect of TEOS addition to Fe3O4 indicates that the increase in true density results is 4.95 gr/cm3. The stability of nanolubricant on Fe3O4 nanoparticles with the addition of TEOS 1.2 ml was dispersed homogeneously. The value of thermal conductivity also increases due to TEOS addition on Fe3O4 nanoparticles in a volume fraction of 0.8% of 1,631 W/m.K and the heat of the type produced was 718.44 J/kg.K. The effect of TEOS addition on Fe3O4 nanoparticles produces good electrical properties of stability in the nano-lubricant.

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Passive Fuel Cell Heat Recovery Using Heat Pipes to Enhance Metal Hydride Canisters Hydrogen Discharge Rate: An Experimental Simulation

Cited by 28 publications

References 87 publications

A Review of MHP Technology and Its Research Status in Cooling of Li-Ion Power Battery and PEMFC

A Review of MHP Technology and Its Research Status in Cooling of Li-Ion Power Battery and PEMFC

Hydrogen as a Long-Term Large-Scale Energy Storage Solution to Support Renewables

The Effect of Tetraethil OrthoCilicate (TEOS) on Fe3O4 Nanoparticles Addition in Electrical

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