Poiseuille’s law
from class:
College Physics II – Mechanics, Sound, Oscillations, and Waves
Definition
Poiseuille's law describes the volumetric flow rate of a fluid through a cylindrical pipe based on the fluid's viscosity, the pressure difference, and the dimensions of the pipe. It is particularly applicable to laminar flow conditions.
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5 Must Know Facts For Your Next Test
- Poiseuille's law is expressed mathematically as $$Q = \dfrac{\pi r^4 \Delta P}{8 \eta L}$$, where $Q$ is the volumetric flow rate, $r$ is the radius of the pipe, $\Delta P$ is the pressure difference, $\eta$ is the dynamic viscosity, and $L$ is the length of the pipe.
- The flow rate increases dramatically with an increase in the radius of the pipe due to its fourth-power relationship ($r^4$).
- It applies only to incompressible, Newtonian fluids under steady-state and laminar flow conditions.
- An increase in fluid viscosity or pipe length results in a decrease in flow rate, assuming other variables remain constant.
- Poiseuille’s law becomes invalid when turbulent flow occurs; Reynold’s number can help determine whether flow will be laminar or turbulent.
Review Questions
- What are the key variables that Poiseuille's law depends on?
- How does an increase in pipe radius affect volumetric flow rate according to Poiseuille's law?
- Why does Poiseuille’s law not apply to turbulent flows?
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