M. Momenifar
Malek-Ashtar University of Technology
6 Papers
3 Citations
M. Momenifar is an academic researcher from Malek-Ashtar University of Technology. The author has contributed to research in topics: Contact resistance & Proton exchange membrane fuel cell. The author has an hindex of 4, co-authored 4 publications.
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Papers
Investigation of contact pressure distribution over the active area of PEM fuel cell stack
TL;DR: In this article, the authors developed a PEM fuel cell model to study the contact pressure distribution over the membrane electrode assembly using finite element model, where a single cell was reduced to a two-dimensional model to decrease the calculation time.
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Fabrication of multi-filler thermoset-based composite bipolar plates for PEMFCs applications: Molding defects and properties characterizations
TL;DR: In this article, the bipolar plates with and without the flowing channels were fabricated and the channels were perfectly formed on the plates with the designed depth of 0.65mm and 0.5mm of width.
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A Physics-Informed Vector Quantized Autoencoder for Data Compression of Turbulent Flow
M. Momenifar,Enmao Diao,Vahid Tarokh,Andrew D. Bragg +3 more
- 10 Jan 2022
TL;DR: A physics-informed Deep Learning technique based on vector quantization is applied to generate a discrete, low-dimensional representation of data from simulations of three-dimensional turbulent flows to improve the CR, and reduce the mean square error of the MSE by an order of magnitude.
4
Contact Pressure Distribution over MEA of a Three-Cell PEMFC with Metallic Bipolar Plates
TL;DR: In this paper , the contact pressure distribution over the MEA in a three-cell fuel cell stack with metallic bipolar plates with an active area of 100 cm 2 was investigated numerically and experimentally.
Investigation of contact pressure distribution on gas diffusion layer of fuel cell with pneumatic endplate
TL;DR: In this article, the geometric parameters of a pneumatic clamping system are optimized using a central composite design method and finite element simulations to obtain the most uniform contact pressure distribution on gas diffusion layers.