Enhancing the Specific Power of a PEM Fuel Cell Powered UAV with a Novel Bean-Shaped Flow Field
Abstract
:1. Introduction
2. Model Description
3. Mathematic Formulation
3.1. Assumption
- (a)
- PEMFC operates at steady-state conditions.
- (b)
- The inlet gas flow is assumed incompressible.
- (c)
- The mixture of reactants gases is estimated as an ideal gas.
- (d)
- The flow is supposed to be laminar due to the low fluid velocity inside the flow channels.
- (e)
- The CLs and membrane are uniform, isotropic, and homogeneous.
- (f)
- Phase change only takes place in CLs and GDLs.
- (g)
- The membrane is assumed impermeable against the gas phase.
- (h)
- The electrical contact resistance is only taken into account at the GDLs/BPs interface.
3.2. Governing Equation
3.3. Boundary Condition
3.4. Solution Procedure
4. Results and Discussion
5. Conclusions
- The specific arrangement of pins in the unblocking bean-type allows flow velocity to increase further. The highest velocity is found in this flow field in areas between two pins, where they act as a nozzle and increase velocity as the path becomes narrow.
- For blockage pin-type, the highest amount of pressure drop is observed for a cathode stoichiometric of 30 and is nearly 20,762.7 Pa due to creating vortices behind pins. However, there is not a notable difference between bean-type models in terms of pressure drop in a lower cathode stoichiometric (ξcat = 20).
- In pin-type models, oxygen penetration into the GDL is more than a parallel design due to the specific arrangement of pins. When air collides with beans, it diverts and diffuses to the GDL. This increases the accessibility of the reactants to the active surface area.
- In bean-shaped models, a slight difference in temperature is seen in the space between two pins because the coefficient of convection heat transfer raises as velocity increases in these areas, which can facilitate heat management.
- Pins that are placed until the middle of the channel’s depth play the role of a fin in the unblocked bean-shape. This leads to enhancing heat conduction and improving the PEMFC cooling using a further drop in temperature. The hottest point in the bean-shape without blocking in the stoichiometry of 20 is 337.9 K, which is close to the optimal temperature of 336 K. With increasing stoichiometry from 20 to 30, the maximum temperature for parallel, unblocking, and blocking pin-type models reduce from 370, 337.9, and 341.6 to 344.6, 331.5, and 332.3, respectively. By using an unblocked bean-shape in a stoichiometry of 20, we achieve optimal cooling and do not need to increase cathode stoichiometry for the cooling target. For other flow fields, we need to increase the cathode stoichiometry to reach the desired temperature.
- The current density distribution becomes more uniform as the cathode stoichiometry increases. That causes the electrochemical reaction rate and the electrical current density to increase. As the reactant diffuses into active surface areas, and the electrochemical reaction occurs, the current density reduces along the active surface area due to oxygen consumption. Nonetheless, there is no considerable difference in system performance at a higher stoichiometric ratio (more than 20).
- The highest amount of power density is achieved in the bean-type without blockage at a specific voltage of 0.60, which is about 6.2% and 43.9% higher than the parallel and blocking bean-type, respectively. Therefore, the unblocked bean-shape produces more power for a given active area and requires fewer cells to generate power. For the parallel, blocking, and unblocking pin models, the number of needed cells to generate net power of 2.5 kW is 60, 80, and 55, respectively.
- Among different investigated flow fields, the bean-shape without blockage is an ideal flow field in the PEMFC for aerial applications with the maximum amount of volume power density, i.e.,1.1 kW L−1, and maximum mass power density of 0.2 kW kg−1. The Mass of the 2.5 kW PEMFC stack is equal to 13.8, 17.5, and 12.5 with parallel, blocking, and unblocking pin-type models, respectively.
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
Appendix A
Parameter | Value |
---|---|
Anode stoichiometry/Cathode stoichiometry | 1.1/20 and 30 |
Mole fraction of , | 1/0.073/0.17 |
Cathode relative humidity, % [40,41,42,43] | 100 |
Anode relative humidity, % [43] | 0 |
Working pressure, P, atm | 1 |
Working temperature, T, K | 313.2 |
Parameter | Parallel | Bean-Shaped without Blockage | Bean-Shaped with Blockage | |
---|---|---|---|---|
Length, mm | 63.4 | 63.4 | 63.4 | |
The thickness of BPs, mm | 1 | 1 | 1 | |
The thickness of GDLs, CLs, mm [44] | 0.2, 0.015 | 0.2, 0.015 | 0.2, 0.015 | |
The thickness of the membrane, mm [45] | 0.0508 | 0.0508 | 0.0508 | |
Bean-shaped pins | X, mm | - | 1.21 | 1.21 |
Y, mm | - | 1.58 | 1.58 | |
r, mm | - | 2 | 2 | |
n, mm | - | 1.21 | 1.21 | |
s, mm | - | 1 | 1 | |
w, mm | - | 0.5 | 0.5 | |
α, ° | - | 37.5° | 37.5° | |
Physical and Operating Conditions | ||||
, A m−2 | 1.0 × 104 | |||
, A m−2 [35] | 4700 | |||
, A m−2 [16] | 6.0 | |||
, kmol m−3 [16] | 0.0564 | |||
, kmol m−3 [35] | 3.39 × 10−3 | |||
[35] | 0.5 | |||
[16] | 1.0 | |||
[46] | 0.5 | |||
[46] | 0.5 | |||
, m2 s−1 [47] | 11 × 10−5 | |||
, m2 s−1 [47] | 3.2 × 10−5 | |||
, m2 s−1 [47] | 7.35 × 10−5 | |||
[47] | 2.5 | |||
Pore blockage for transfer current, r [47] | 2.5 | |||
s−1 [16] | 100 | |||
The density of BPs, GDLs, CLs, membrane, kg.m−3 | 8000, 383, 4397.5, 1970 | |||
Specific heat at a constant pressure of BPs, GDLs, CLs, membrane, J kg−1K−1 | 530, 568, 710, 1650 | |||
Thermal conductivity of BPs, GDLs, CLs, membrane, W m−1K−1 | 17, 0.5, 8, 0.95 | |||
The electrical conductivity of BPs, GDLs, CLs, membrane, Ohm−1m−1 [16] | 120, 1000, 1000, 1 × 10−16 | |||
Membrane equivalent weight, kg kmol−1 | 1100 | |||
of CLs, m−1 [47] | 1.9 × 1010 | |||
The porosity of GDLs, CLs, membrane [47] | 0.8, 0.7, 0.5 | |||
The viscous resistance of GDLs, CLs, membrane, m−1 [47] | 1.43 × 1010, 9.8 × 1011, 2.11 × 108 | |||
[48] | ||||
, MPa [35] | 4.5 | |||
, cm2, parallel, without blockage, with blockage | 7.35, 7.758, 7.758 | |||
, cm2, parallel, without blockage, with blockage | 3.82, 1.085, 1.621 |
Zone | Parallel | Unblocked Bean-Shaped | Blocked Bean-Type |
---|---|---|---|
Cathode current collector | 110,080 | 146,574 | 152,334 |
Anode current collector | 110,080 | 152,334 | 152,334 |
Cathode channel | 38,400 | 106,200 | 100,440 |
Anode channel | 38,400 | 100,440 | 100,440 |
GDLs | 74,240 | 112,344 | 112,344 |
CLs | 37,120 | 84,258 | 84,258 |
Membrane | 74,240 | 84,258 | 84,258 |
All | 593,920 | 983,010 | 983,010 |
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Zone | Parallel | Bean-Shaped without Blockage | Bean-Shaped with Blockage | |||
---|---|---|---|---|---|---|
Mass [gr] | Volume [L] | Mass [gr] | Volume [L] | Mass [gr] | Volume [L] | |
Cathode BP | 87.2 | 0.0109 | 82.4 | 0.0108 | 86.4 | 0.0108 |
Anode BP | 87.2 | 0.0109 | 86.4 | 0.0103 | 86.4 | 0.0108 |
Cathode GDL | 0.563 | 0.00147 | 0.594 | 0.00155 | 0.594 | 0.00155 |
Anode GDL | 0.563 | 0.00147 | 0.594 | 0.00155 | 0.594 | 0.00155 |
Cathode CL | 0.485 | 0.00011 | 0.51 | 0.000116 | 0.51 | 0.000116 |
Anode CL | 0.485 | 0.00011 | 0.51 | 0.000116 | 0.51 | 0.000116 |
Membrane | 0.723 | 0.000367 | 0.776 | 0.000394 | 0.776 | 0.000394 |
Total | 177.2 | 0.02532 | 171.8 | 0.02482 | 175.8 | 0.02533 |
Flow Fields | Number of Cells | Active Area (cm2) | Volume (L) | Mass (kg) | Pressure Drop (Pa) | Consumed Power (W) |
---|---|---|---|---|---|---|
Parallel | 60 | 73.54 | 2.44 | 13.8 | 285 | 0.84 |
Unblocking bean-shaped | 55 | 77.58 | 2.27 | 12.5 | 13,254 | 29.8 |
Blocking bean-shaped | 80 | 77.58 | 3.00 | 17.5 | 23,241 | 69.9 |
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Toghyani, S.; Atyabi, S.A.; Gao, X. Enhancing the Specific Power of a PEM Fuel Cell Powered UAV with a Novel Bean-Shaped Flow Field. Energies 2021, 14, 2494. https://doi.org/10.3390/en14092494
Toghyani S, Atyabi SA, Gao X. Enhancing the Specific Power of a PEM Fuel Cell Powered UAV with a Novel Bean-Shaped Flow Field. Energies. 2021; 14(9):2494. https://doi.org/10.3390/en14092494
Chicago/Turabian StyleToghyani, Somayeh, Seyed Ali Atyabi, and Xin Gao. 2021. "Enhancing the Specific Power of a PEM Fuel Cell Powered UAV with a Novel Bean-Shaped Flow Field" Energies 14, no. 9: 2494. https://doi.org/10.3390/en14092494
APA StyleToghyani, S., Atyabi, S. A., & Gao, X. (2021). Enhancing the Specific Power of a PEM Fuel Cell Powered UAV with a Novel Bean-Shaped Flow Field. Energies, 14(9), 2494. https://doi.org/10.3390/en14092494