Qil A (30 N/s) flow throw the reducer of the proceeding problem ,the air in the (300mm) pipe having weight density of (9.8 N/m') in the flowing through the reducer producing a redaction of density .assuming that the weight density of the air in the (200 mm) pipe is (7.85 N/ m'). Calculate the mass and volume flow rate.
Qil A (30 N/s) flow throw the reducer of the proceeding problem ,the air in the (300mm) pipe having weight density of (9.8 N/m') in the flowing through the reducer producing a redaction of density .assuming that the weight density of the air in the (200 mm) pipe is (7.85 N/ m'). Calculate the mass and volume flow rate.
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
Related questions
Question
![= 4.33
9.74m/ seć
n/ 4(0.2)2
HOMEWORK
Q1l A (30 N/s) flow throw the reducer of the proceeding problem ,the air in the
(300mm) pipe having weight density of (9.8 N/m' ) in the flowing through the
reducer producing a redaction of density .assuming that the weight density of the
air in the (200 mm) pipe is (7.85 N/ m'). Calèulate the mass and volume flow
rate.
Q2/ (2) Water enters a conical diffusing passage (see Figure below). With a flow
rate of 10ft'/s, and if the entrance cross-section area is 2 ft, what's the average
velocity at the entrance to the diffuser? What must the diffuser exit area be to
reduce the velocity to 0.5 ft/s?
4 = 2 f
Q = 10 cfs
- m = AQ:
oiclooleo or boon ow.matve binl
to sinsb omit letot odi stum
hn th .C](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2Fcf81ce6e-eb97-4b1d-9ca8-09bffa84f15f%2F3164eb0d-43c0-422c-ae9b-fd25eda7de51%2Ftbfq8fd_processed.jpeg&w=3840&q=75)
Transcribed Image Text:= 4.33
9.74m/ seć
n/ 4(0.2)2
HOMEWORK
Q1l A (30 N/s) flow throw the reducer of the proceeding problem ,the air in the
(300mm) pipe having weight density of (9.8 N/m' ) in the flowing through the
reducer producing a redaction of density .assuming that the weight density of the
air in the (200 mm) pipe is (7.85 N/ m'). Calèulate the mass and volume flow
rate.
Q2/ (2) Water enters a conical diffusing passage (see Figure below). With a flow
rate of 10ft'/s, and if the entrance cross-section area is 2 ft, what's the average
velocity at the entrance to the diffuser? What must the diffuser exit area be to
reduce the velocity to 0.5 ft/s?
4 = 2 f
Q = 10 cfs
- m = AQ:
oiclooleo or boon ow.matve binl
to sinsb omit letot odi stum
hn th .C
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