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--- 183_notes:drag [2015/09/03 20:35] – [Models of fluid resistance] caballero
+++ 183_notes:drag [2021/02/04 23:39] (current) – [Models of fluid resistance] stumptyl
@@ Line 5: / Line 5: @@
 ==== Fluid Resistance ====
-An object moving in any fluid experiences some form of resistance to its motion due collisions with molecules of the fluid. Each of these little collisions with the surrounding fluid contribute to the overall resistive force that the fluid exerts on a moving object.
+//An object moving in any fluid experiences some form of resistance to its motion due collisions with molecules of the fluid.// Each of these little collisions with the surrounding fluid contribute to the overall resistive force that the fluid exerts on a moving object.
-Unlike friction forces, which are velocity-independent, fluid resistance depends on the velocity of the object in the fluid. While modeling the molecular collisions with the object can be done, for most purposes, macroscopic models of the fluid drag force are sufficient to model the motion of the object. Below, you will learn about the two most common models: laminar drag and turbulent drag.
+//Unlike friction forces, which are velocity-independent, fluid resistance depends on the velocity of the object in the fluid//. While modeling the molecular collisions with the object can be done, for most purposes, macroscopic models of the fluid drag force are sufficient to model the motion of the object. Below, you will learn about the two most common models: laminar drag and turbulent drag.
 ==== Models of fluid resistance ====
@@ Line 22: / Line 22: @@
 === Laminar drag ===
-For a situation where the Reynolds number is low (e.g., a small, slow-moving object in a viscous fluid), the fluid resistance is proportional to the velocity of the object:
+For a situation where the __Reynolds number is low__ (e.g., a small, slow-moving object in a viscous fluid), the fluid resistance is proportional to the velocity of the object:
  $\vec{F}_{drag} = -b\vec{v}$
@@ Line 30: / Line 30: @@
  $\vec{F}_{drag} = -6\pi\eta r \vec{v}$
-where  $\eta$  is the fluid viscosity.
+where**  $\eta$ ** is the **fluid viscosity**.
+\\
 === Turbulent drag ===
-For a situation where the Reynolds number is high (e.g., a large, fast-moving object in a less viscous fluid), the fluid resistance is proportional to the speed of the object squared:
+For a situation where the __Reynolds number is high__ (e.g., a large, fast-moving object in a less viscous fluid), the fluid resistance is proportional to the speed of the object squared:
  $\vec{F}_{drag} = -cv^2\hat{v}$
@@ Line 43: / Line 44: @@
  $\vec{F}_{drag} = -\dfrac{1}{2} \rho C_d A v^2 \hat{v}$
-where  $\rho$  is the density of the fluid,  $A$  is the cross-sectional area of the object in the fluid, and  $C_d$  is the drag coefficient of the object, which is often measured experimentally.
+where  $\rho$  is the// density of the fluid//,  $A$  //is the cross-sectional area of the object in the fluid//, and  $C_d$  //is the drag coefficient of the object, which is often measured experimentally//.
+\\
 === What about "medium" Reynolds numbers flows? ===