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Figure 3. 2. DN4 for different flow rates of the electrolytes for single-channel serpentine (SSFF), 3-channel serpentine (3SFF), and interdigitated (IFF) flow field designs.................................... 32 Figure 3. 3. A schematic of the pipe assumption and the flow velocity profile for round pipes in laminar, fully developed viscous flow. ......................................................................................... 35 Figure 3. 4. A Schematic of the geometry and the flow directions for channels in IFF, from the top and front view. The left white, right white, and grey area represent inlet channels, outlet channels, and rib between inlet and outlet channels, respectively................................................................ 36 Figure 3. 5. A HEAM representation for a. 5-channel IFF b. 3-channel SFF (3SFF). Abbreviation used in figure are: MI: the inlet manifold resistance, C: a set of inlet, rib and outlet channel resistance, MO: the outlet manifold resistance, CS: a parallel channel in SFF ............................ 38 Figure 3. 6. DPMA system. .......................................................................................................... 40 Figure 3. 7. Pressure drop- flow rate data and their respective regression lines for two different experimental settings. The zero error of each is shown on each subfigure. ................................. 42 Figure 3. 8. 25 cm2 RFB assembly. .............................................................................................. 44 Figure 3. 9. Experimental and predicted pressure drop by HEAM for different electrolyte flow rates. The data are produced by designed experiments in the lab, and are shifted by the zero error to ensure the effects of systematic errors are removed. (CF: Carbon felt, SGL 4.6: 4.6 mm thick electrode)....................................................................................................................................... 45 Figure 3. 10. Experimental and predicted pressure drop by HEAM for different electrolyte flow rates. The data are produced by designed experiments in the lab, and are shifted by the zero error to ensure the effects of systematic errors are removed. (CP: Carbon paper, CF: Carbon felt, SGL 4.6: 4.6 mm thick electrode) ......................................................................................................... 46 vPDF Image | Analysis of Fluid Flow in Redox Flow Batteries
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