A 4km long pipeline, 88 cm in diameter connects two fresh water open reservoirs A and b, with ater surface elevations at 75m and 50m respectively. In order to increase the rate of flow between the reservoirs by exactly 30%, the assigned engineering team decided to lay an additional pipeline with the same diameter from the upper reservoir. The 2nd pipeline is to lie parallel to the original pipeline with length X (from the upper reservoir to a certain point in the 4km pipeline) which produces this increase in flow. If C=110, determine the a. flowrate of the original pipeline (original system) b. flowrate in the additional pipeline c. length "X" of the second pipeline measured from the upper reservoir

A 4km long pipeline, 88 cm in diameter connects two fresh water open reservoirs A and b, with ater surface elevations at 75m and 50m respectively. In order to increase the rate of flow between the reservoirs by exactly 30%, the assigned engineering team decided to lay an additional pipeline with the same diameter from the upper reservoir. The 2nd pipeline is to lie parallel to the original pipeline with length X (from the upper reservoir to a certain point in the 4km pipeline) which produces this increase in flow. If C=110, determine the a. flowrate of the original pipeline (original system) b. flowrate in the additional pipeline c. length "X" of the second pipeline measured from the upper reservoir

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Description: 1. A 4km long pipeline, 88 cm in diameter connects two fresh water open reservoirs A and b, with ater surfaceelevations at 75m and 50m respectively. In order to increase the rate of flow between the reservoirs by exactly30%, the assigned engineering

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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