Finite element method modeling and optimization of the mechanical behavior of a low-temperature PEM fuel cell

�zdemir, Safiye Nur; Taymaz, �mdat; Kurt, Emre

Volume : 30 Issue : 2 Year : 2024

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Finite element method modeling and optimization of the mechanical behavior of a low-temperature PEM fuel cell [Pamukkale Univ Muh Bilim Derg]

Pamukkale Univ Muh Bilim Derg. Ahead of Print: PAJES-45773 | DOI: 10.5505/pajes.2023.45773

Finite element method modeling and optimization of the mechanical behavior of a low-temperature PEM fuel cell

Safiye Nur �zdemir¹, �mdat Taymaz¹, Emre Kurt²
¹Sakarya University Engineering Faculty-Sakarya
²T�rsan Solutions-Sakarya

Proton exchange membrane fuel cells (PEMFCs) consist of six main components: current collectors (CC), end plates (EP), bipolar plates (BPP), gas diffusion layers (GDL), gaskets, and membrane electrode assembly (MEA). PEMFC assembly or design parameters are critical for maximum performance, strength, and reliability. The cell's mechanical behavior should be known for optimum fuel cell assembly and design. Therefore, a three-dimensional finite element model of PEMFC with an active area of 100 cm� was developed, and the stress and deformation values in the cell components were calculated with Ansys Mechanical software. The response surface method (RSM) was applied to obtain optimum levels and analyze the effect of design parameters. For statistical analysis, bolt number, bolt hole diameter, and clamping torque were defined as three different independent design variables, and their individual-combined effects on stress and deformation, which were determined as response parameters, were analyzed. Therefore, the number of bolts, bolt hole diameter, and clamping torque ranges are 12-20, 4-6 mm, and 9-15 Nm, respectively. When the number of bolts is 12, the bolt hole diameter is 6 mm, the clamping torque is 9 Nm, the total minimum deformation is 0.063 mm, and the minimum stress on the membrane is 12.846 MPa. As a result of reducing the bolt hole diameter from 6 mm to 4 mm, the total deformation has increased by approximately 60.4%. With the increasing number of bolts, more homogeneous stress distributions were achieved, and the end plate's maximum stress increased by about 83.3%. The increase in clamping torque has caused a pressure increase of roughly 21 MPa on the membrane. The numerical and statistical findings of the study can be an important guide in evaluating the performance, durability and reliability of the PEMFC.

Keywords: 3D PEMFC, Finite element method, Response surface method, Optimization, Mechanical analysis

D��k s�cakl�kl� bir PEM yak�t h�cresinin mekanik davran��n�n sonlu elemanlar y�ntemiyle modellenmesi ve optimizasyonu

Safiye Nur �zdemir¹, �mdat Taymaz¹, Emre Kurt²
¹Sakarya �niversitesi M�hendislik Fak�ltesi-Sakarya
²T�rsan Treyler A.�.-Sakarya

Proton de�i�im membranl� yak�t pilleri (PEMYP) alt� esas bile�enden olu�maktad�r: ak�m toplay�c�lar (AT), u� plakalar (UP), bipolar plakalar (BP), gaz dif�zyon tabakalar� (GDT), contalar ve membran elektrot �nitesi (ME�)�dir. Maksimum performans, y�ksek dayan�m ve g�venilirlik i�in PEMYP montaj veya tasar�m parametreleri kritik bir �neme sahiptir. Optimum yak�t pil montaj ve tasar�m� i�in h�crenin mekanik davran��lar�n�n bilinmesi gerekmektedir. Yak�t pilinin mekanik montaj s�recinin deneysel tekniklerle ger�ek zamanl� olarak yap�lmas� olduk�a maliyetli ve zaman al�c�d�r. Bu nedenle, 100 cm� aktif alana sahip PEMYP�nin �� boyutlu sonlu eleman modeli geli�tirilmi�, h�cre bile�enlerindeki gerilme ve deformasyon de�erleri Ansys Mechanical yaz�l�m� ile hesaplanm��t�r. Optimum seviyeleri elde etmek ve tasar�m parametrelerinin etkisini analiz etmek i�in cevap y�zeyi y�ntemi (CYY) uygulanm��t�r. �statistiksel analiz i�in c�vata say�s�, c�vata delik �ap� ve s�k��t�rma torklar� �� farkl� ba��ms�z tasar�m de�i�keni olarak tan�mlanm��, bunlar�n yan�t parametreleri olarak belirlenen gerilme ve deformasyon �zerindeki bireysel-birle�ik etkileri analiz edilmi�tir. Bu nedenle �al��lan c�vata say�s�, c�vata delik �ap� ve s�k��t�rma torku aral�klar� s�ras�yla 12-20, 4-6 mm ve 9-15 Nm�dir. C�vata deli�i �ap�n�n 6 mm'den 4 mm'ye d��r�lmesi sonucunda, toplam deformasyon yakla��k olarak %60.4 oran�nda artm��t�r. Artan c�vata say�s�yla birlikte daha homojen gerilme da��l�mlar� sa�lanm�� ve u� plakadaki maksimum gerilme yakla��k olarak %83.3 oran�nda artm��t�r. S�k��t�rma torkundaki y�kselme ise membran �zerinde yakla��k olarak 21 MPa'l�k bir bas�n� art��na neden olmu�tur. �al��man�n say�sal ve istatistiksel bulgular�, PEMYP performans�n�n, dayan�kl�l��n�n ve g�venilirli�inin de�erlendirilmesinde �nemli bir rehber olabilir.

Anahtar Kelimeler: 3B PEMYP, Sonlu elemanlar y�ntemi, Cevap y�zeyi y�ntemi, Optimizasyon, Mekanik analiz

Corresponding Author: �mdat Taymaz, T�rkiye
Manuscript Language: Turkish

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Finite element method modeling and optimization of the mechanical behavior of a low-temperature PEM fuel cell

D���k s�cakl�kl� bir PEM yak�t h�cresinin mekanik davran���n�n sonlu elemanlar y�ntemiyle modellenmesi ve optimizasyonu

D��k s�cakl�kl� bir PEM yak�t h�cresinin mekanik davran��n�n sonlu elemanlar y�ntemiyle modellenmesi ve optimizasyonu