1) During your experiment, you will have air flowing at a constant flow rate through four different sized ports in a chamber as shown in the picture. Cross sectional area Calculate the cross sectional area for port #1 if its dimension are: Width = 7.2160 x 103 m Depth = 8.0260 x 103 m 2) The relationship between Flow Rate (R), Cross Sectional Area (A) and Velocity (v) is called the Continuity equation: R = Av Use the area from question 1 to calculate the velocity of the air at port #1 if the air is m3 flowing at a rate of R= 0.0011366. Width Depth

1) During your experiment, you will have air flowing at a constant flow rate through four different sized ports in a chamber as shown in the picture. Cross sectional area Calculate the cross sectional area for port #1 if its dimension are: Width = 7.2160 x 103 m Depth = 8.0260 x 103 m 2) The relationship between Flow Rate (R), Cross Sectional Area (A) and Velocity (v) is called the Continuity equation: R = Av Use the area from question 1 to calculate the velocity of the air at port #1 if the air is m3 flowing at a rate of R= 0.0011366. Width Depth

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Description: 1) During your experiment, you will have air flowing at a constant flow rate throughfour different sized ports in a chamber as shown in the picture.Cross sectional areaCalculate the cross sectional area for port #1 if its dimension are:Width = 7.216

University Physics Volume 1

18th Edition

ISBN:9781938168277

Author:William Moebs, Samuel J. Ling, Jeff Sanny

Publisher:William Moebs, Samuel J. Ling, Jeff Sanny

Chapter14: Fluid Mechanics

Section: Chapter Questions

Problem 69P: What is density of a woman floats in fresh water with 4.00% of her volume above the surface? (This...

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