Solved

Bernoulli's Principle: Water Flows in the Horizontal Pipe Shown in the Figure

Question 47

Multiple Choice

Bernoulli's principle: Water flows in the horizontal pipe shown in the figure. At A the diameter is 5.00 cm and at B the diameter is 4.00 cm The fluid in the manometer is mercury, which has a density of 13,600 kg/m3. The manometer reading h is 4.40 cm. We can treat water as an ideal fluid having a density of 1000 kg/m3. What volume of water is flowing through the pipe per second? Bernoulli's principle: Water flows in the horizontal pipe shown in the figure. At A the diameter is 5.00 cm and at B the diameter is 4.00 cm The fluid in the manometer is mercury, which has a density of 13,600 kg/m<sup>3</sup>. The manometer reading h is 4.40 cm. We can treat water as an ideal fluid having a density of 1000 kg/m<sup>3</sup>. What volume of water is flowing through the pipe per second? A) 0.0206 /s B) 0.0426 /s C) 0.00560 /s D) 0.372 /s E) 0.186 /s


A) 0.0206 Bernoulli's principle: Water flows in the horizontal pipe shown in the figure. At A the diameter is 5.00 cm and at B the diameter is 4.00 cm The fluid in the manometer is mercury, which has a density of 13,600 kg/m<sup>3</sup>. The manometer reading h is 4.40 cm. We can treat water as an ideal fluid having a density of 1000 kg/m<sup>3</sup>. What volume of water is flowing through the pipe per second? A) 0.0206 /s B) 0.0426 /s C) 0.00560 /s D) 0.372 /s E) 0.186 /s /s
B) 0.0426 Bernoulli's principle: Water flows in the horizontal pipe shown in the figure. At A the diameter is 5.00 cm and at B the diameter is 4.00 cm The fluid in the manometer is mercury, which has a density of 13,600 kg/m<sup>3</sup>. The manometer reading h is 4.40 cm. We can treat water as an ideal fluid having a density of 1000 kg/m<sup>3</sup>. What volume of water is flowing through the pipe per second? A) 0.0206 /s B) 0.0426 /s C) 0.00560 /s D) 0.372 /s E) 0.186 /s /s
C) 0.00560 Bernoulli's principle: Water flows in the horizontal pipe shown in the figure. At A the diameter is 5.00 cm and at B the diameter is 4.00 cm The fluid in the manometer is mercury, which has a density of 13,600 kg/m<sup>3</sup>. The manometer reading h is 4.40 cm. We can treat water as an ideal fluid having a density of 1000 kg/m<sup>3</sup>. What volume of water is flowing through the pipe per second? A) 0.0206 /s B) 0.0426 /s C) 0.00560 /s D) 0.372 /s E) 0.186 /s /s
D) 0.372 Bernoulli's principle: Water flows in the horizontal pipe shown in the figure. At A the diameter is 5.00 cm and at B the diameter is 4.00 cm The fluid in the manometer is mercury, which has a density of 13,600 kg/m<sup>3</sup>. The manometer reading h is 4.40 cm. We can treat water as an ideal fluid having a density of 1000 kg/m<sup>3</sup>. What volume of water is flowing through the pipe per second? A) 0.0206 /s B) 0.0426 /s C) 0.00560 /s D) 0.372 /s E) 0.186 /s /s
E) 0.186 Bernoulli's principle: Water flows in the horizontal pipe shown in the figure. At A the diameter is 5.00 cm and at B the diameter is 4.00 cm The fluid in the manometer is mercury, which has a density of 13,600 kg/m<sup>3</sup>. The manometer reading h is 4.40 cm. We can treat water as an ideal fluid having a density of 1000 kg/m<sup>3</sup>. What volume of water is flowing through the pipe per second? A) 0.0206 /s B) 0.0426 /s C) 0.00560 /s D) 0.372 /s E) 0.186 /s /s

Correct Answer:

verifed

Verified

Unlock this answer now
Get Access to more Verified Answers free of charge

Related Questions

Q42: Viscosity: A flat horizontal plate of area

Q43: Bernoulli's principle: In a section of horizontal

Q44: Bernoulli's principle: Water flows in the horizontal

Q45: Bernoulli's principle: A level pipe contains a

Q46: Viscosity: Motor oil, with a viscosity of

Q48: Bernoulli's principle: Air is flowing through a

Q49: Bernoulli's principle: A large cylindrical water tank

Q50: Bernoulli's principle: A horizontal tube consists of

Q51: Viscosity: Glycerin, with a viscosity of 1.50

Q52: Bernoulli's principle: A paint sprayer pumps air

Unlock this Answer For Free Now!

View this answer and more for free by performing one of the following actions

qr-code

Scan the QR code to install the App and get 2 free unlocks

upload documents

Unlock quizzes for free by uploading documents