Let,V → Control Volumeb → Intensive value of B in any small element of the fluidρ → Density of the flow\(\vec{v}\) → Velocity of fluid entering or leaving the control volumeAfter applying Gauss divergence theorem, how does the term representing ‘net flow of B into and out of the control volume’ look like?

dV\) b) \(\int_s \nabla.(\rho \vec{v}b)dS\)

\(\int_v \nabla.(\rho \vec{v}b)dV\) b) \(\int_s \nabla.(\rho \vec{v}b)dS\) c) \(\int_v(\rho \vec{v}b)dV\) d) \(\int_s(\rho \vec{v}

dV\) b) \(\int_s \nabla.(\rho \vec{v}b)dS\)

Gauss divergence is applied to which of these terms?

Net flow of B into and out of the control mass

Instantaneous total change of B inside the control mass

Instantaneous total change of B within the control volume

Net flow of B into and out of the control volume

Net flow of B into and out of the control mass

Gauss divergence theorem is used to convert a surface integral to volume integral. This is used in Reynolds Transport theorem. What is the purpose of this conversion?

Differentiating the flow property

Grouping terms related to control volume

Let,V → Control VolumeB → Flow propertyb → Intensive value of B in any small element of the fluidρ → Density of the flowt → Instantaneous timeWhich of these terms represent the ‘instantaneous total change of the flow property within the control volume’ after Leibniz rule is applied?

\(\rho \int_v \frac{\partial b}{\partial T} dV \)

\( \frac{d}{dt}(\int_vb \rho dV)\)

\( \int_v \frac{\partial}{\partial T}(b \rho)dV\)

\(\rho \int_v \frac{\partial b}{\partial T} dV \)

\(\rho \int_v \frac{\partial \rho}{\partial b} dV\)

When is Leibniz rule applicable to control volume?

When control volume is deforming

Why a surface integral is used to represent flow of B into and out of the control volume?

Fluid only on the control surfaces

Flow of fluid is through the control surfaces

Fluid only on the control surfaces

Leibniz rule is applied to which of these terms in deriving Reynolds transport theorem?

Differential term of material volume

Volume integral term of control volume

Differential term of material volume

Surface integral term of control volume

Volume integral term of material volume

Consider the following terms:MV → Material Volume (Control Mass)V → Control VolumeS → Control SurfaceB → Flow propertyb → Intensive value of B in any small element of the fluidρ → Density of the flowt → Instantaneous time\( \vec{v} \) → Velocity of fluid entering or leaving the control volume\( \vec{n} \) → Outward normal vector to control surfaceWhich of these equations is the mathematical representation of Reynolds transport theorem in the above terms?

\((\frac{dB}{dt})_V = \frac{d}{dt}(\int_{MV}b \rho MV) + \int_sb \rho \vec{v}.\vec{n} dS\)

\((\frac{dB}{dt})_{MV} = \frac{d}{dt}(\int_sb \rho dS) + \int_vb \rho \vec{v}.\vec{n} dV\)

\((\frac{dB}{dt})_{MV} = \frac{d}{dt}(\int_vb \rho dV) + \int_sb \rho \vec{v}.\vec{n} dS\)

\((\frac{dB}{dt})_V = \frac{d}{dt}(\int_{MV}b \rho MV) + \int_sb \rho \vec{v}.\vec{n} dS\)

\((\frac{dB}{dt})_{MV} = \int_vb \rho dV + \frac{d}{dt}(\int_sb \rho \vec{v}.\vec{n} dS)\)

Let B denote any property of a fluid flow. The statement of Reynolds transport theorem is “The instantaneous total change of B inside the _____________ is equal to the instantaneous total change of B within the ______________ plus the net flow of B into and out of the _____________”

Control volume, Control mass, Control volume

Control volume, Control volume, Control mass

Control mass, Control mass, Control volume

Control mass, Control volume, Control volume

The Reynolds transport theorem establishes a relationship between __________ and ___________

Differential equation, Integral equation

Control mass system, Control volume system

Differential equation, Integral equation

Non-conservative equation, Conservative equation

Substantial derivative, Local derivative

11 + Mcqs in Reynolds Transport Theorem in Computational Fluid Dynamics Page 1 McqOptions

1.	The final equation of Reynolds transport theorem can be used to drive ____________ form of the conservation laws in fixed regions.
A.	Eucledian
B.	Lagrangian
C.	Eulerian
D.	Cartesian
Answer» D. Cartesian

Discussion

2.	Let,V → Control Volumeb → Intensive value of B in any small element of the fluidρ → Density of the flow\(\vec{v}\) → Velocity of fluid entering or leaving the control volumeAfter applying Gauss divergence theorem, how does the term representing ‘net flow of B into and out of the control volume’ look like?
A.	\(\int_v \nabla.(\rho \vec{v}b)dV\) b) \(\int_s \nabla.(\rho \vec{v}b)dS\) c) \(\int_v(\rho \vec{v}b)dV\) d) \(\int_s(\rho \vec{v}
B.	dV\) b) \(\int_s \nabla.(\rho \vec{v}b)dS\)
C.	\(\int_v(\rho \vec{v}b)dV\)
D.	\(\int_s(\rho \vec{v}b)dS\)
Answer» B. dV\) b) \(\int_s \nabla.(\rho \vec{v}b)dS\)

Discussion

3.	Gauss divergence is applied to which of these terms?
A.	Instantaneous total change of B inside the control mass
B.	Instantaneous total change of B within the control volume
C.	Net flow of B into and out of the control volume
D.	Net flow of B into and out of the control mass
Answer» D. Net flow of B into and out of the control mass

Discussion

4.	Gauss divergence theorem is used to convert a surface integral to volume integral. This is used in Reynolds Transport theorem. What is the purpose of this conversion?
A.	Simplifying the term
B.	Differentiating the flow property
C.	Adding the flow property
D.	Grouping terms related to control volume
Answer» E.

Discussion

5.	Let,V → Control VolumeB → Flow propertyb → Intensive value of B in any small element of the fluidρ → Density of the flowt → Instantaneous timeWhich of these terms represent the ‘instantaneous total change of the flow property within the control volume’ after Leibniz rule is applied?
A.	\( \frac{d}{dt}(\int_vb \rho dV)\)
B.	\( \int_v \frac{\partial}{\partial T}(b \rho)dV\)
C.	\(\rho \int_v \frac{\partial b}{\partial T} dV \)
D.	\(\rho \int_v \frac{\partial \rho}{\partial b} dV\)
Answer» C. \(\rho \int_v \frac{\partial b}{\partial T} dV \)

Discussion

6.	When is Leibniz rule applicable to control volume?
A.	When control volume is moving
B.	When control volume is deforming
C.	When control volume is fixed
D.	In all conditions
Answer» D. In all conditions

Discussion

7.	Why a surface integral is used to represent flow of B into and out of the control volume?
A.	Control volume is moving
B.	Flow of fluid is through the control surfaces
C.	Fluid only on the control surfaces
D.	Control volume is stationary
Answer» C. Fluid only on the control surfaces

Discussion

8.	Leibniz rule is applied to which of these terms in deriving Reynolds transport theorem?
A.	Volume integral term of control volume
B.	Differential term of material volume
C.	Surface integral term of control volume
D.	Volume integral term of material volume
Answer» B. Differential term of material volume

Discussion

9.	Consider the following terms:MV → Material Volume (Control Mass)V → Control VolumeS → Control SurfaceB → Flow propertyb → Intensive value of B in any small element of the fluidρ → Density of the flowt → Instantaneous time\( \vec{v} \) → Velocity of fluid entering or leaving the control volume\( \vec{n} \) → Outward normal vector to control surfaceWhich of these equations is the mathematical representation of Reynolds transport theorem in the above terms?
A.	\((\frac{dB}{dt})_{MV} = \frac{d}{dt}(\int_sb \rho dS) + \int_vb \rho \vec{v}.\vec{n} dV\)
B.	\((\frac{dB}{dt})_{MV} = \frac{d}{dt}(\int_vb \rho dV) + \int_sb \rho \vec{v}.\vec{n} dS\)
C.	\((\frac{dB}{dt})_V = \frac{d}{dt}(\int_{MV}b \rho MV) + \int_sb \rho \vec{v}.\vec{n} dS\)
D.	\((\frac{dB}{dt})_{MV} = \int_vb \rho dV + \frac{d}{dt}(\int_sb \rho \vec{v}.\vec{n} dS)\)
Answer» C. \((\frac{dB}{dt})_V = \frac{d}{dt}(\int_{MV}b \rho MV) + \int_sb \rho \vec{v}.\vec{n} dS\)

Discussion

10.	Let B denote any property of a fluid flow. The statement of Reynolds transport theorem is “The instantaneous total change of B inside the _____________ is equal to the instantaneous total change of B within the ______________ plus the net flow of B into and out of the _____________”
A.	Control volume, Control mass, Control volume
B.	Control volume, Control volume, Control mass
C.	Control mass, Control mass, Control volume
D.	Control mass, Control volume, Control volume
Answer» E.

Discussion

11.	The Reynolds transport theorem establishes a relationship between __________ and ___________
A.	Control mass system, Control volume system
B.	Differential equation, Integral equation
C.	Non-conservative equation, Conservative equation
D.	Substantial derivative, Local derivative
Answer» B. Differential equation, Integral equation

Discussion

Explore topic-wise MCQs in Computational Fluid Dynamics.

The final equation of Reynolds transport theorem can be used to drive ____________ form of the conservation laws in fixed regions.

Gauss divergence is applied to which of these terms?

Gauss divergence theorem is used to convert a surface integral to volume integral. This is used in Reynolds Transport theorem. What is the purpose of this conversion?

Let,V → Control VolumeB → Flow propertyb → Intensive value of B in any small element of the fluidρ → Density of the flowt → Instantaneous timeWhich of these terms represent the ‘instantaneous total change of the flow property within the control volume’ after Leibniz rule is applied?

When is Leibniz rule applicable to control volume?

Why a surface integral is used to represent flow of B into and out of the control volume?

Leibniz rule is applied to which of these terms in deriving Reynolds transport theorem?

Let B denote any property of a fluid flow. The statement of Reynolds transport theorem is “The instantaneous total change of B inside the _ is equal to the instantaneous total change of B within the plus the net flow of B into and out of the ___”

The Reynolds transport theorem establishes a relationship between and _