6.5 Fluid Friction and Drag | Fluid Mechanics | Physics 11

Fluid friction is the resistive force generated when an object moves through a fluid (a liquid or a gas). This force, commonly known as drag or viscous force, opposes the object's motion and arises from the interactions between the object's surface and the fluid's particles.

Viscosity

Viscosity is a measure of a fluid's internal resistance to flow. It can be thought of as the "thickness" of a fluid. For example, honey has a high viscosity and flows slowly, while water has a low viscosity and flows easily. This internal friction between the layers of a fluid is a primary contributor to drag.

Real fluids exhibit viscosity because their molecules interact with each other, creating internal friction that resists flow. This is why real fluids are viscous fluids — unlike the idealised non-viscous (inviscid) fluid assumed in Bernoulli's equation.

The SI unit of the coefficient of viscosity $η$ is $Pa \cdot s$ (pascal-second), equivalent to $kg \cdot m^{- 1} \cdot s^{- 1}$ . Its dimensions are $[M L^{- 1} T^{- 1}]$ .

Derived Units→

Drag Force

Drag is the component of fluid friction that acts parallel and opposite to an object's direction of motion. The magnitude of the drag force is influenced by several factors:

Velocity of the Object: The faster the object moves, the greater the drag force.
Size and Shape of the Object: Streamlined or aerodynamic shapes experience less drag.
Fluid Properties: The density and viscosity of the fluid significantly affect drag. Denser and more viscous fluids create more resistance.

The general equation for drag force, particularly at higher velocities, is:

$F_{D} = \frac{1}{2} ρ v^{2} C_{D} A$

Where:

$F_{D}$ = Drag force
$ρ$ = Density of the fluid
$v$ = Velocity of the object relative to the fluid
$C_{D}$ = Drag coefficient (a dimensionless number that depends on the object's shape)
$A$ = Cross-sectional area of the object perpendicular to the flow

Dimensions→

Viscous forces in a fluid create a retarding force on a moving object through friction between the object's surface and adjacent fluid layers. As the object moves, it drags some fluid along with it, and fluid layers at different velocities exert shear stresses on each other, opposing the motion.

Stokes' Law

Stokes' Law is a specific formula used to calculate the drag force on a small spherical object moving at a low velocity through a viscous fluid. The flow of the fluid around the sphere must be smooth and orderly (laminar flow).

The formula is given by:

$F = 6 π η r v$

Where:

$F$ = Viscous drag force (Stokes' drag)
$η$ = Coefficient of viscosity of the fluid
$r$ = Radius of the spherical object
$v$ = Velocity of the object

Stokes' Law is applicable under the following conditions:

The object must be a perfect sphere.
The velocity must be low enough to ensure laminar (streamline) flow around the sphere.
The fluid must be viscous and incompressible.

Comparison: Stokes' Law and General Drag Equation

Factor	Stokes' Law ( $F = 6 π η r v$ )	General Drag Equation ( $F_{D} = \frac{1}{2} ρ v^{2} C_{D} A$ )
Object Shape	Assumes a perfect sphere	Applicable to any shape (accounted for by $C_{D}$ )
Flow Condition	Valid for low velocities (laminar flow)	Applicable for higher velocities (turbulent flow)
Velocity Dependence	Proportional to velocity ( $v$ )	Proportional to the square of the velocity ( $v^{2}$ )

Terminal Velocity

When an object falls through a fluid, it initially accelerates due to gravity. As its velocity increases, the drag force also increases. Eventually, the drag force equals the weight of the object (minus any upthrust), and the net force becomes zero. From this point, the object falls at a constant velocity called the terminal velocity.

Equilibrium→

At terminal velocity, the forces are balanced:

$m g = F_{D} + upthrust$

For a sphere in a viscous fluid, substituting Stokes' Law:

$m g = 6 π η r v_{t} + ρ_{f} V g$

where $v_{t}$ is the terminal velocity and $ρ_{f}$ is the fluid density.

Velocity of the Object: The faster the object moves, the greater the drag force.
Size and Shape of the Object: Streamlined or aerodynamic shapes experience less drag.
Fluid Properties: The density and viscosity of the fluid significantly affect drag. Denser and more viscous fluids create more resistance.

The general equation for drag force, particularly at higher velocities, is:

$F_{D} = \frac{1}{2} ρ v^{2} C_{D} A$

Where:

$F_{D}$ = Drag force
$ρ$ = Density of the fluid
$v$ = Velocity of the object relative to the fluid
$C_{D}$ = Drag coefficient (a dimensionless number that depends on the object's shape)
$A$ = Cross-sectional area of the object perpendicular to the flow

Dimensions→

Stokes' Law

The formula is given by:

$F = 6 π η r v$

Where:

$F$ = Viscous drag force (Stokes' drag)
$η$ = Coefficient of viscosity of the fluid
$r$ = Radius of the spherical object
$v$ = Velocity of the object

Stokes' Law is applicable under the following conditions:

The object must be a perfect sphere.
The velocity must be low enough to ensure laminar (streamline) flow around the sphere.
The fluid must be viscous and incompressible.

Comparison: Stokes' Law and General Drag Equation

Factor	Stokes' Law ( $F = 6 π η r v$ )	General Drag Equation ( $F_{D} = \frac{1}{2} ρ v^{2} C_{D} A$ )
Object Shape	Assumes a perfect sphere	Applicable to any shape (accounted for by $C_{D}$ )
Flow Condition	Valid for low velocities (laminar flow)	Applicable for higher velocities (turbulent flow)
Velocity Dependence	Proportional to velocity ( $v$ )	Proportional to the square of the velocity ( $v^{2}$ )

Terminal Velocity

Equilibrium→

At terminal velocity, the forces are balanced:

$m g = F_{D} + upthrust$

For a sphere in a viscous fluid, substituting Stokes' Law:

$m g = 6 π η r v_{t} + ρ_{f} V g$

where $v_{t}$ is the terminal velocity and $ρ_{f}$ is the fluid density.

Applications

Q: Why do cyclists and speed skaters wear smooth, tight-fitting clothing?

A: To minimize drag. The streamlined shape and smooth texture reduce the fluid friction from the air, allowing them to travel faster with the same amount of effort.