Impacts of Catalyst Ink Composition and Wet Film Thickness on Fuel Cell Catalyst Layers Fabricated by Direct Film Coating Method

J. Stoll, Jisung Jeong, Philip Huynh, E. Kjeang
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Abstract

Utilizing a direct film coating method (DFCM), such as doctor blade coating, offers a promising approach for efficient and scalable catalyst layer (CL) production for fuel cells. To further widen the understanding of lab-scale DFCM, the present research investigates how different Pt-based catalyst ink formulations coated via doctor blade coating with varying blade gap thickness (BGT) affect the CL quality and catalyst loading. In total, 120 CL samples were prepared by coating 20 different catalyst ink formulations with varying solids content, ionomer-to-carbon (I/C) ratio, and water-to-isopropanol solvent ratio with BGTs of 75, 125, and 200 μm. Inspection of these samples showed that the solvent ratio affects the coating uniformity, with the most uniform films achieved with a ratio of 1.67 or greater. Furthermore, increasing the I/C ratio for a given solids content ink formulation decreases the Pt loading, whereas an I/C ratio above or below 1.0 reduces cell performance due to mass transport or proton conductivity impacts, respectively. In addition, a relationship factor and equations are presented to estimate the solid weight and catalyst loading of the fabricated CL based on the ink formulation and BGT. Overall, this work provides important guidance for lab-scale DFCM fabrication of industrially relevant CLs
催化剂油墨成分和湿膜厚度对直接涂膜法制造的燃料电池催化剂层的影响
利用直接薄膜涂层法(DFCM),如刮刀涂层,为燃料电池高效、可扩展的催化剂层(CL)生产提供了一种前景广阔的方法。为了进一步拓宽对实验室规模 DFCM 的理解,本研究调查了通过刮刀涂层涂覆不同铂基催化剂油墨配方以及不同的刮刀间隙厚度(BGT)如何影响 CL 质量和催化剂负载。通过涂覆 20 种不同的催化剂油墨配方,共制备了 120 个 CL 样品,这些配方的固体含量、离子体与碳 (I/C) 的比例以及水与异丙醇的溶剂比例各不相同,BGT 分别为 75、125 和 200 μm。对这些样品的检测表明,溶剂比会影响涂层的均匀性,当溶剂比大于或等于 1.67 时,薄膜的均匀性最好。此外,在给定固体含量的油墨配方中,提高 I/C 比会降低铂载量,而高于或低于 1.0 的 I/C 比则会分别由于质量传输或质子传导影响而降低电池性能。此外,根据油墨配方和 BGT,还提出了一个关系因子和方程,用于估算制造出的 CL 的固体重量和催化剂负载量。总之,这项工作为实验室规模 DFCM 制备工业相关 CL 提供了重要指导
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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