As shown in Figure D, three water reservoirs are connected by three pipes. The diameters in each pipe is 1 ft and the Fanning friction factor in each pipe is 0.02. The effective lengths of each pipe are given in the Figure along with other relevant data. Determine the flow rate into or out of each reservoir as well as the Reynolds number in each pipe. (Hint: Start the computations by assuming that the water flows into reservoir В).

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As shown in Figure D, three water reservoirs are connected by three pipes. The diameters in each pipe are 1 ft and the Fanning friction factor in each pipe is 0.02. The effective lengths of each pipe are given in the Figure along with other relevant data. Determine the flow rate into or out of each reservoir as well as the Reynolds number in each pipe. (Hint: Start the computations by assuming that the water flows into reservoir B).

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### Figure D: Hydraulic System Diagram This diagram illustrates a three-reservoir hydraulic system with varying elevations, pipe lengths, and fluid properties. 1. **Reservoir A** - **Elevation:** 100 feet - **Position:** Topmost reservoir with a valve at point A - **Pipe Length from Source (L_A):** 1,000 feet 2. **Reservoir B** - **Elevation:** 20 feet - **Position:** Intermediate reservoir with a valve at point B - **Pipe Length from Reservoir A (L_B):** 500 feet 3. **Reservoir C** - **Elevation:** 0 feet - **Position:** Lowest reservoir with a valve at point C - **Pipe Length from Reservoir B (L_C):** 400 feet ### Fluid Properties - **Density (ρ):** 62.3 pounds per cubic foot (lbm/ft³) - **Dynamic Viscosity (μ):** 0.000672 pound-force second per square foot (lbm/fts) This system demonstrates changes in elevation and flow path in a multi-reservoir setup, valuable for hydraulic engineering studies. The varying elevations and pipe lengths can be used to calculate pressure differences, flow rates, and potential energy changes in the system. Understanding the fluid properties, such as density and dynamic viscosity, is essential for analyzing the flow characteristics within the pipes.