When tiny particles are suspended in a fluid, they eventually settle due to gravity if they are denser than the surrounding medium. The settling velocity is a key factor in numerous scientific and engineering disciplines, from water treatment and environmental science to pharmaceuticals and geology. For very small, spherical particles in a viscous fluid, the settling behavior is described by Stokes’ law, which assumes laminar flow around the particle. This calculator focuses on that regime, letting you estimate how fast particles sink under idealized conditions.
In the laminar regime, the drag force on a sphere is proportional to its velocity, radius, and the fluid’s viscosity. Balancing gravitational and drag forces leads to , where and are the densities of the particle and fluid, respectively, is gravitational acceleration, is particle radius, and is dynamic viscosity. This relation shows that larger, denser particles settle faster, while higher viscosity slows them down. It is valid only when the particle Reynolds number is very small (typically below 0.1).
Engineers rely on Stokes’ law to design sedimentation tanks, clarifiers, and centrifuges. In wastewater treatment, predicting how fast solids settle helps determine tank dimensions and retention times. In the pharmaceutical industry, controlling particle size ensures consistent drug delivery, so understanding sedimentation rates is crucial during formulation. Geologists study sedimentation to reconstruct past climates and depositional environments. Even food scientists examine how particles like cocoa powder settle in chocolate milk. Each application hinges on predicting how quickly suspended materials separate from liquids.
Enter the particle radius, densities, viscosity, and gravitational acceleration. The defaults correspond to a micron-sized mineral grain settling in water. After clicking Compute, the calculator applies Stokes’ law to deliver the terminal settling velocity in meters per second. You can alter the inputs to explore how density contrasts or fluid viscosity impact sedimentation. For instance, increasing the fluid’s viscosity by an order of magnitude will slow settling by the same factor, illustrating why honey pours much more slowly than water.
Stokes’ law assumes the flow around the particle remains laminar. If the particle is too large or the fluid velocity too high, turbulence arises, and the simple formula no longer holds. The dimensionless Reynolds number helps determine validity. When is less than about 0.1, Stokes’ law applies. Our calculator provides the settling velocity first; you can then compute to verify if the assumption is reasonable for your scenario.
Natural waters are rarely perfectly still, so real sedimentation often deviates from the ideal. Nevertheless, Stokes’ law gives a foundational estimate that guides research on lake sediments, river deposits, and even airborne particulates settling from the atmosphere. In biology, cells and organelles settle according to similar principles, making Stokes’ law relevant for centrifugation protocols used to separate cellular components. Understanding these basics can help you interpret a wide array of phenomena, from cloud formation to the design of industrial separators.
The Stokes Settling Velocity Calculator offers a straightforward way to predict how fast particles fall through viscous fluids under laminar conditions. By adjusting the variables, you can quickly see how size, density, viscosity, and gravity influence sedimentation. Use this tool as a starting point for more detailed fluid dynamics analysis or to gain intuition for laboratory experiments and industrial processes.
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