The frictional pressure drop p for a fluid of density p and viscosity u flowing with a velocity V through a circular pipe of inside diameter d.length L, and surface roughness e can be given by the dimensionless groups, where:AP f(p,V,D.u,L, e)A half-scale model is used to simulate the flow of a liquid hydrocarbon in a pipeline. Determine the expected pressure drop along the full-scale pipe if the average velocity of the hydrocarbon in the full-scale pipe is expected to be 3 m/s. The model uses water where the pressuredrop per meter length is noted to be 4 kPa. The respective densities of water and hydrocarbion are 900 kg/m and 800 kgym, and dynamicviscosities are 10 kg/m.s and 9x104 kg/m.s.Note: Take (p,V,d) as repeating variables.Select one:O a. 2.1025 kPaO b. 1.0125 kPaO c. 1.512 kPaO d. 1.139 kPa

Given:- The frictional pressure drop for a fluid density depends on viscosity, velocity, diameter,…

The frictional pressure drop p for a fluid of density p and viscosity u flowing with a velocity V through a circular pipe of inside diameter c length L and surface roughness e can be given by the dimensionless groups, where: AP = f(p,V,D, H, L, e) A half-scale model is used to simulate the flow of a liquid hydrocarbon in a pipeline. Determine the expected pressure drop along the fu scale pipe if the average velocity of the hydrocarbon in the full-scale pipe is expected to be 3 m/s. The model uses water where the pres drop per meter length is noted to be 4 kPa. The respective densities of water and hydrocarbon are 900 kg/m and 800 kg/m, and dynar viscosities are 10 kg/m.s and 9x104 kg/m.s. Note: Take (p,V,d) as repeating variables. Select one: O a. 2.1025 kPa O b. 1,0125 kPa Oc 1.512 kPa 0dit29 kPa

The frictional pressure drop p for a fluid of density p and viscosity u flowing with a velocity V through a circular pipe of inside diameter c length L and surface roughness e can be given by the dimensionless groups, where: AP = f(p,V,D, H, L, e) A half-scale model is used to simulate the flow of a liquid hydrocarbon in a pipeline. Determine the expected pressure drop along the fu scale pipe if the average velocity of the hydrocarbon in the full-scale pipe is expected to be 3 m/s. The model uses water where the pres drop per meter length is noted to be 4 kPa. The respective densities of water and hydrocarbon are 900 kg/m and 800 kg/m, and dynar viscosities are 10 kg/m.s and 9x104 kg/m.s. Note: Take (p,V,d) as repeating variables. Select one: O a. 2.1025 kPa O b. 1,0125 kPa Oc 1.512 kPa 0dit29 kPa

Structural Analysis

6th Edition

ISBN:9781337630931

Author:KASSIMALI, Aslam.

Publisher:KASSIMALI, Aslam.

Chapter2: Loads On Structures

Section: Chapter Questions

Problem 1P

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