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Shear Rate Calculator

Flow Geometry Type Parallel Plates (Simple Shear) Pipe Flow (Newtonian)

Velocity (v) [m/s]

Gap Height (h) [mm]

Calculated Shear Rate:

0 s⁻¹

Formula: γ̇ = v / h

*Note: This calculation assumes a no-slip boundary condition and laminar flow.

How to Calculate Shear Rate

Shear rate (denoted by γ̇, or "gamma dot") is a measure of how fast a fluid flows relative to the distance over which that flow occurs. It quantifies the rate of deformation of a fluid element. Understanding shear rate is critical in fields ranging from chemical engineering and rheology to injection molding and physiology (blood flow).

        Quick Definition: Shear rate represents the velocity gradient perpendicular to the direction of flow. The standard unit is reciprocal seconds (s⁻¹).
    

1. Simple Shear (Parallel Plates)

The most fundamental definition of shear rate comes from the Couette flow model, where a fluid is trapped between two parallel plates—one stationary and one moving.

Formula:

γ̇ = v / h

γ̇ = Shear Rate (s⁻¹)
v = Velocity of the moving plate (m/s)
h = Gap distance between plates (m)

2. Pipe Flow (Newtonian Fluid)

For fluids flowing through a circular pipe, the shear rate is not constant; it is zero at the center and maximum at the wall. This calculator estimates the Shear Rate at the Wall for a Newtonian fluid.

Formula:

γ̇ = 8v / D

γ̇ = Shear Rate at the wall (s⁻¹)
v = Average flow velocity (m/s)
D = Inside Diameter of the pipe (m)

Calculation Example

Imagine a coating process where a blade moves over a surface (Parallel Plate model):

Velocity (v): 0.5 m/s
Gap Height (h): 1 mm (which is 0.001 meters)

Step 1: Convert units to match. 1 mm = 0.001 m.

Step 2: Apply the formula: γ̇ = 0.5 / 0.001

Result: The Shear Rate is 500 s⁻¹.

Why is Shear Rate Important?

Shear rate determines the viscosity of non-Newtonian fluids.

Shear Thinning: Viscosity decreases as shear rate increases (e.g., ketchup, paint).
Shear Thickening: Viscosity increases as shear rate increases (e.g., cornstarch in water).

Knowing the shear rate allows engineers to predict how a fluid will behave during processing, such as pumping, spraying, or extrusion.