Thomas-Stormer viscometer

1. Dynamic viscosity: Thomas-Stormer viscometer:
The viscosity is the fluid resistance to shear or flow
The Tomas Stormer apparatus mesures a dynamic viscosity of a liquid as oil.

The shear stress on the surface of the rotor is proportional to:
- The viscosity μ of the liquid, and
- The rotation speed of the rotor.
Hence:
σ = k μ ω
If S is the wetted surface area of the rotor, and F is the tangential force on the edge of the rotor, we can write: F = σ S
The related torque is τ = F x r_rotor
r_rotor is the radius of rotor.

We neglect frictions in the system to write that the power exerted on the rotor is equal to the power supplied by the weight W in order to move this weight of a distance L = v x t.
We have: L = 2 x π x r_axis
Then
v = L/t = 2 x π x r_axis x n_axis/t     (1)
n_axis is the number of rotations made by the axis.
Since the power of the falling weight and the power dissipated over the rotor by viscous steress are equal, we can write:
Power_fluide = Power_weight; that is:
τ ω = W x v
W is the weight of the falling body.

In other hand: ω = 2π x r_rotor x n_rotor/t     (2)

The relationships (1) et (2) give:
2 x π x r_axis x n_axis/v = 2π x r_rotor x n_rotor/ω
Or:
r_rotor x n_rotor/ω = r_axis x n_axis/v
Then:
μ k = σ/ω = F/S/ω = τ / r_rotor/S/ω =
W x v/ω /S/ r_axis x n_axis/v/ =
W /ω /S/ r_axis x n_axis /n_rotor/r_rotor

We define the constant K of the viscometer as:
C = (W x r_axis x n_axis)/(r_rotor n_axis x S x k) Forethermore:

μ = C x W / ω

2. Kinematic viscosity:
Kinematic viscosity is, by definition, the ratio of absolute or dynamic viscosity to density:
ν = μ /ρ
where ν = kinematic viscosity, μ = absolute or dynamic viscosity, and ρ = density

3. Measurement:
For a fluid liquid, we use communly the Oswald apparatus tp mesure the viscosity. We set the following relationship:
μ = k ρ t
where k is a constant callibration of the apparatus, &pho; density and t the time spent by the fluid to live a part "1" of the cappilary viscometer.

According to a known value of the kinematic viscosity of a certain fluid, we just make the ratio μ /μ_known= k &pho; t1 / k &pho;_known t2; and measuring the times t1 and t2 to have the value of μ

μ = μ_known ρ t1 / ρ_known t2
We have also for the kinematic viscosity:
ν = ν_known t1 / t2

We use also Saybolt, Engler, or Brookfield viscosimeters depending on circumstances.