Optimization of electrolysis cell for producing hydrogen is dependent of a set of complex physical and chemical processes simultaneously occurring within the electrolysis cell. Similar to fuel cells, it has been demonstrated that these processes are strongly dependent on the fluid dynamics inside the electrolysis & fuel cell. Bipolar plates are important components of PEM electrolysis cells because they are the first stage of the flow distribution system. Numerical simulations were performed for three-dimensional two-phase water/oxygen flow in the anode side of a bipolar plate with a diagonal flow design. The water flowrate was maintained as constant of 260 ml/min, while the oxygen bubble generation rate was assumed to change from 0 -0.014 g/s. Numerical results reveal that a minimum of the peak values of mainstream velocity component in the channels develops in the middle of the plate. Pressure drop and volume fraction of oxygen at the exit become higher as the oxygen bubble generation flowrate increases. The irregular velocity profile (locally low velocity magnitude near the exit port section) is not observed when the oxygen bubble flowrate is relatively low.
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机译:用于生产氢的电解槽优化依赖于电解槽内同时发生的一组复杂的物理和化学方法。类似于燃料电池,已经证明这些过程强烈依赖于电解和燃料电池内的流体动力学。双极板是PEM电解细胞的重要组成部分,因为它们是流动分配系统的第一阶段。在具有对角线流动设计的双极板的阳极侧进行三维两相水/氧流量的数值模拟。水流量保持为260ml / min的常数,而假设氧气泡沫产生速率从0-0.014 g / s变化。数值结果表明,信道中主流速度分量的最小值在板的中间开发。随着氧气气泡产生流量的增加,出口处的氧的压降和体积分数变得更高。当氧气气泡流量相对较低时,未观察到不规则速度曲线(出口部分附近的局部低速幅度)。
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