Express \(\tau_{yz}\) in terms of velocity gradients.

\(\tau_{yz}=μ(\frac{\partial u}{\partial z}+\frac{\partial u}{\partial y})\)

\(\tau_{yz}=μ(\frac{\partial v}{\partial z}+\frac{\partial w}{\partial y})\)

\(\tau_{yz}=μ(\frac{\partial u}{\partial z}+\frac{\partial u}{\partial y})\)

\(\tau_{yz}=μ(\frac{\partial v}{\partial x}+\frac{\partial w}{\partial x})\)

\(\tau_{yz}=μ(\frac{\partial w}{\partial z}+\frac{\partial v}{\partial y})\)

Express the shear stress tensor(τ) of a three-dimensional fluid flow element in terms of the velocity vector(v).

\(\tau=\mu\left\{(\nabla \vec{v})^T\right\}+\lambda(\nabla.\vec{v})I\)

\(\tau=\mu\left\{(\nabla \vec{v})\right\}+\lambda(\nabla.\vec{v})I\)

\(\tau=\mu\left\{(\nabla \vec{v})^T+(\nabla.\vec{v})^T\right\}\)

\(\tau=\mu\left\{(\nabla \vec{v})^T+(\nabla.\vec{v})^T\right\}+\lambda(\nabla.\vec{v})I\)

What are the two viscosity coefficients involved in the relationship between stress tensor and strain rate of fluids?

Kinematic viscosity and volume viscosity

Kinematic viscosity and bulk viscosity

Dynamic viscosity and kinematic viscosity

Dynamic viscosity and bulk viscosity

Kinematic viscosity and volume viscosity

What do the two subscripts of stress tensors represent?

Directions of strain and normal to the surface on which they are acting

Directions of stress and strain

Directions of stress and normal to the surface on which they are acting

Directions of strain and normal to the surface on which they are acting

Direction of stress and the flow direction

Explore topic-wise MCQs in Computational Fluid Dynamics.

This section includes 9 Mcqs, each offering curated multiple-choice questions to sharpen your Computational Fluid Dynamics knowledge and support exam preparation. Choose a topic below to get started.

1.	Viscous forces fall into which kind of the following forces acting on a body?
A.	Pressure force
B.	Tensile force
C.	Body forces
D.	Surface forces
Answer» D. Surface forces

Discussion

2.	Express \(\tau_{yz}\) in terms of velocity gradients.
A.	\(\tau_{yz}=μ(\frac{\partial v}{\partial z}+\frac{\partial w}{\partial y})\)
B.	\(\tau_{yz}=μ(\frac{\partial u}{\partial z}+\frac{\partial u}{\partial y})\)
C.	\(\tau_{yz}=μ(\frac{\partial v}{\partial x}+\frac{\partial w}{\partial x})\)
D.	\(\tau_{yz}=μ(\frac{\partial w}{\partial z}+\frac{\partial v}{\partial y})\)
Answer» B. \(\tau_{yz}=μ(\frac{\partial u}{\partial z}+\frac{\partial u}{\partial y})\)

Discussion

3.	Express the shear stress tensor(τ) of a three-dimensional fluid flow element in terms of the velocity vector(v).
A.	\(\tau=\mu\left\{(\nabla \vec{v})^T\right\}+\lambda(\nabla.\vec{v})I\)
B.	\(\tau=\mu\left\{(\nabla \vec{v})\right\}+\lambda(\nabla.\vec{v})I\)
C.	\(\tau=\mu\left\{(\nabla \vec{v})^T+(\nabla.\vec{v})^T\right\}\)
D.	\(\tau=\mu\left\{(\nabla \vec{v})^T+(\nabla.\vec{v})^T\right\}+\lambda(\nabla.\vec{v})I\)
Answer» E.

Discussion

4.	What is the relationship between bulk viscosity coefficient (λ) and the dynamic viscosity coefficient (μ)?
A.	λ=\(-\frac{2}{3}\) μ
B.	λ=\(\frac{2}{3}\) μ
C.	λ=\(-\frac{1}{3}\) μ
D.	λ=\(-\frac{1}{2}\) μ
Answer» B. λ=\(\frac{2}{3}\) μ

Discussion

5.	What are the two viscosity coefficients involved in the relationship between stress tensor and strain rate of fluids?
A.	Kinematic viscosity and bulk viscosity
B.	Dynamic viscosity and kinematic viscosity
C.	Dynamic viscosity and bulk viscosity
D.	Kinematic viscosity and volume viscosity
Answer» D. Kinematic viscosity and volume viscosity

Discussion

6.	The divergence of the stress tensor is _____
A.	Scalar
B.	Vector
C.	0
D.	1
Answer» C. 0

Discussion

7.	Which of the stress tensors from the diagram is represented by Τxy?
A.	3
B.	2
C.	1
D.	4
Answer» B. 2

Discussion

8.	What do the two subscripts of stress tensors represent?
A.	Directions of stress and strain
B.	Directions of stress and normal to the surface on which they are acting
C.	Directions of strain and normal to the surface on which they are acting
D.	Direction of stress and the flow direction
Answer» C. Directions of strain and normal to the surface on which they are acting

Discussion

9.	Which among these forces used in momentum equation is a tensor?
A.	Gravitational forces
B.	Pressure forces
C.	Viscous forces
D.	Electromagnetic forces
Answer» D. Electromagnetic forces

Discussion

Explore topic-wise MCQs in Computational Fluid Dynamics.

Viscous forces fall into which kind of the following forces acting on a body?

Express \(\tau_{yz}\) in terms of velocity gradients.

Express the shear stress tensor(τ) of a three-dimensional fluid flow element in terms of the velocity vector(v).

What is the relationship between bulk viscosity coefficient (λ) and the dynamic viscosity coefficient (μ)?

What are the two viscosity coefficients involved in the relationship between stress tensor and strain rate of fluids?

The divergence of the stress tensor is _____

Which of the stress tensors from the diagram is represented by Τxy?

What do the two subscripts of stress tensors represent?

Which among these forces used in momentum equation is a tensor?