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Mar 21 2010

How hard does the wind push?

Categories:

Science

by Reuben

Wind incident on an umbrella

During our most recent storm, I found myself victim of the surprisingly harsh Riverside wind. With my umbrella directly out front of me, pointing into the wind, I found I barely had enough strength to hold my position, so great was the force imparted by the wind. I got to thinking about just how strong the wind was as the windspeed picked up.

In a time \Delta t , the column of air in the figure hits and transfers its momentum to my umbrella. The force is equal to the momentum transferred to my umbrella per unit time:

\bar{F}= \frac{\Delta p}{\Delta t}.
(1)

How much is that? Well, the column has area A and height v \Delta t , so the volume is A v \Delta t . The change in momentum is the mass of this column times the change in velocity,

\Delta p = m \Delta v = m (v - 0).
(2)

The mass of the column is its volume times the density, \rho . Putting this all together,

\bar{F} = \frac{\Delta p}{\Delta t} = \frac{m v}{\Delta t} = \frac{v \Delta t A \rho v}{\Delta t} = A \rho v^2.
(3)

If we allow that some of the wind retains a bit of its forward momentum, so that it's just deflected instead of dead stopped, we could add a simple coefficient C_d to this. Thus,

F = A C_d \rho v^2.
(4)

This says that if the wind speed doubles, the force required to stay still quadruples. For a half sphere, the coefficient is about 0.2. Assuming an area of \unit[1]{m^2} , the below graph shows the force in pounds for a wind speed in miles per hour.

Graph of wind force vs wind speed

As you can see, the force gets powerful mighty fast.

Actually, if we were to consider this scenario from a reference frame where the air was stationary, and I was moving at a speed v , we get the expression for drag force (apart from the factor of 1/2). This was surprising to me, although it shouldn't have been. For some reason, I find it easier to derive the expression in the way I just did.

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