first 2 parts please A2Answer ALL parts (a)-(c).Diesel fuel flows along a pipe 6 m long, whose bore (internal diameter) is 5mm. The density and viscosity of the fuel are 850 kg/m³ and 1.8 x 10-³ Ns/m²respectively. If the pressure-drop over the length of the pipe 1.3 kN/m²,estimate the volume flow rate of fuel along the pipe. (Hint: since the bore issmall, assume the flow is laminar and use Poiseuille's equation to find theflow rate. Then find the flow velocity, and hence the Reynolds number, tocheck that the flow is indeed laminar.)(a)(b)(c)Hot water at 50°C is flowing along a pipe 800 mm diameter at a mean speedof 2.3 m/s. At this temperature the kinematic viscosity of the water isv=5.55x10-7 m²/s. Will the flow be laminar or turbulent?Water at 12°C is supplied to a 40 mm diameter steel pipe at 9 bar gaugepressure. The pipe is 125 m long, the roughness is k = 0.02 mm, and at theend of the pipe the water is discharged to atmosphere. Estimate theflow rate of the water and state your assumptions.(Kinematic viscosity for the water is v= 1.22 x 10-6 m²/s).

Given:For pipe flow:Flow is laminar if Re < 2000Flow is turbulent if Re > 4000Assumption:Since…

Answer ALL parts (a) - (c). (a) Diesel fuel flows along a pipe 6 m long, whose bore (internal diameter) is 5 mm. The density and viscosity of the fuel are 850 kg/m³ and 1.8 x 10-³ Ns/m² respectively. If the pressure-drop over the length of the pipe 1.3 kN/m², estimate the volume flow rate of fuel along the pipe. (Hint: since the bore is small, assume the flow is laminar and use Poiseuille's equation to find the flow rate. Then find the flow velocity, and hence the Reynolds number, to check that the flow is indeed laminar.) (b) Hot water at 50°C is flowing along a pipe 800 mm diameter at a mean speed of 2.3 m/s. At this temperature the kinematic viscosity of the water is v=5.55x107 m²/s. Will the flow be laminar or turbulent?

Answer ALL parts (a) - (c). (a) Diesel fuel flows along a pipe 6 m long, whose bore (internal diameter) is 5 mm. The density and viscosity of the fuel are 850 kg/m³ and 1.8 x 10-³ Ns/m² respectively. If the pressure-drop over the length of the pipe 1.3 kN/m², estimate the volume flow rate of fuel along the pipe. (Hint: since the bore is small, assume the flow is laminar and use Poiseuille's equation to find the flow rate. Then find the flow velocity, and hence the Reynolds number, to check that the flow is indeed laminar.) (b) Hot water at 50°C is flowing along a pipe 800 mm diameter at a mean speed of 2.3 m/s. At this temperature the kinematic viscosity of the water is v=5.55x107 m²/s. Will the flow be laminar or turbulent?

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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