L is 140 m, d is 13 cm, and h is 80 cm Problem (11): A pipe discharges an unknown fluid into theatmosphere from a tank of depth (h) through a pipe of length(L), and diameter (d).Given the values of L [m], d [cm], and (h) [cm], calculate thedischarge rate (Q) [lit/s] that would maintain Laminar flow inthe pipe with a Reynolds number of Re=1500. Ignore minorlosses.hd

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Answered: L is 140 m, d is 13 cm, and h is 80 cm…

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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In the gap between the two plates, the lubricant flows in one direction (x) by the pressure gradient. Lubricants are incompressible Newtonian fluids, flows are laminates, and terminal effects are ignored. Find the maximum flow rate [m/s] when the pressure difference (△P/L) per unit length is 25000 Pa/m.Data: clearance between plates (B) = 6 mm, lubricant viscosity (μ) = 25 cP (1cP = 10-3 Pa·s), lubricant density (=) = 0.88 g/cm3
In the gap between the two plates, the lubricant flows in one direction (x) by the pressure gradient. Lubricants are incompressible Newtonian fluids, flows are laminates, and terminal effects are ignored. Find the maximum flow rate [m/s] when the pressure difference (△P/L) per unit length is 25000 Pa/m.Data: clearance between plates (B) = 6 mm, lubricant viscosity (μ) = 25 cP (1cP = 10-3 Pa·s), lubricant density (=) = 0.88 g/cm3 Please.. explain more easy
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Q5: The following solution in blue is provided by ChatGPT for the following question. Please find out the errors it made and show the step-by-step solution by yourself. Water in a vertical (i.e., gravitational force of the fluid in the nozzle plays a role, and the elevation change in the Bernoulli's Equation, if needed, should be considered) pipe is charging from an attached bend nozzle into the atmosphere as shown in Fig. 5. The nozzle's weight is 20 kg. The pipe and the nozzle are connected by a flange. The gage pressure of the flow at the flange is 35 kPa when the discharge rate is 0.1 m³/s. The volume of the bending nozzle is 0.012 m³. Calculate the vertical component of the anchoring forcing required to hold the nozzle in place and determine its direction. G= 9.81 m/s². The density of water is 1000 kg/m³. Nozzle Area-0.01m² P-35 kPa Area -0.025 Figure 5: Q5 35 degree ChatGPT solution: This is a challenging problem that requires some knowledge of fluid mechanics and calculus. I…

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