The pipe diameter is ________

Inversely proportional to mass flow rate

Directly proportional to fluid density

Directly proportional to mass flow rate

Inversely proportional to mass flow rate

Directly proportional to fluid velocity

The pipe diameter is _______?

Inversely proportional to mass flow rate

Directly proportional to fluid density

Directly proportional to mass flow rate

Inversely proportional to mass flow rate

Directly proportional to fluid velocity

The total head loss for the system is equal to_________

Height difference of reservoirs

What is the total loss developed in a series of pipes?

Sum of losses in each pipe only

Sum of local losses plus the losses in each pipe

The liquid flowing through a series of pipes can take up__________

Pipes of the same diameters only.

Explore topic-wise MCQs in Fluid Mechanics.

This section includes 10 Mcqs, each offering curated multiple-choice questions to sharpen your Fluid Mechanics knowledge and support exam preparation. Choose a topic below to get started.

1.	The pipe diameter is ________
A.	Directly proportional to fluid density
B.	Directly proportional to mass flow rate
C.	Inversely proportional to mass flow rate
D.	Directly proportional to fluid velocity
Answer» C. Inversely proportional to mass flow rate

Discussion

2.	Coefficient of friction of a laminar flow is_________$
A.	R<sub>e</sub>/16
B.	R<sub>e</sub>/64
C.	16/R<sub>e</sub>
D.	64/R<sub>e</sub>
Answer» D. 64/R<sub>e</sub>

Discussion

3.	The pipe diameter is _______?
A.	Directly proportional to fluid density
B.	Directly proportional to mass flow rate
C.	Inversely proportional to mass flow rate
D.	Directly proportional to fluid velocity
Answer» C. Inversely proportional to mass flow rate

Discussion

4.	How do we determine the total discharge through parallel pipes?
A.	Add them.
B.	Subtract them
C.	Multiply them
D.	Divide them
Answer» B. Subtract them

Discussion

5.	If the two reservoirs are kept at the same level, the head loss is _______
A.	Z<sub>1</sub>-Z<sub>2</sub>
B.	Zero
C.	T<sub>2</sub>-T<sub>1</sub>
D.	S<sub>2</sub>-S<sub>1</sub>
Answer» C. T<sub>2</sub>-T<sub>1</sub>

Discussion

6.	Which among the following is the correct formula for head loss?
A.	Z<sub>1</sub>-Z<sub>2</sub>
B.	C
C.	T<sub>2</sub>-T<sub>1</sub>
D.	S<sub>2</sub>-S<sub>1</sub>
Answer» B. C

Discussion

7.	Which among the following is not a loss that is developed in the pipe?
A.	Entry
B.	Exit
C.	Connection between two pipes
D.	Liquid velocity
Answer» E.

Discussion

8.	The total head loss for the system is equal to_________
A.	Pipe length
B.	Pipe diameter
C.	Width of the reservoir
D.	Height difference of reservoirs
Answer» E.

Discussion

9.	What is the total loss developed in a series of pipes?
A.	Sum of losses in each pipe only
B.	Sum of local losses only
C.	Sum of local losses plus the losses in each pipe
D.	Zero
Answer» D. Zero

Discussion

10.	The liquid flowing through a series of pipes can take up__________
A.	Pipes of different diameters
B.	Pipes of the same diameters only.
C.	Single pipe only
D.	Short pipes only
Answer» B. Pipes of the same diameters only.

Discussion

Explore topic-wise MCQs in Fluid Mechanics.

The pipe diameter is ________

Coefficient of friction of a laminar flow is_________$

The pipe diameter is _______?

How do we determine the total discharge through parallel pipes?

If the two reservoirs are kept at the same level, the head loss is _______

Which among the following is the correct formula for head loss?

Which among the following is not a loss that is developed in the pipe?

The total head loss for the system is equal to_________

What is the total loss developed in a series of pipes?

The liquid flowing through a series of pipes can take up__________