1) We want to measure the density Q2 of the fluid in the tank depicted in the figure by attaching a manometer containing a fluid of known density Qi to the side of the tank. Both the manometer and the tank are open to the atmosphere. The manometer is connected at depth h, below the fluid level in the tank. This gives rise to a height difference hm between the levels of fluid in the manometer, and the top of the fluid in the manometer is at a depth h below the fluid level in the tank. Derive an equation to measure Q2 from the various fluid heights and the known density Qi- atm Patm In P2

1) We want to measure the density Q2 of the fluid in the tank depicted in the figure by attaching a manometer containing a fluid of known density Qi to the side of the tank. Both the manometer and the tank are open to the atmosphere. The manometer is connected at depth h, below the fluid level in the tank. This gives rise to a height difference hm between the levels of fluid in the manometer, and the top of the fluid in the manometer is at a depth h below the fluid level in the tank. Derive an equation to measure Q2 from the various fluid heights and the known density Qi- atm Patm In P2

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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