Greetings. 
Back to Energy 101. 
And another exciting day in energy 
resources. 
We're going to look at wind today. 
We looked at solar last time. 
We looked at fossil fuels. 
we're looking at the renewable energy 
resources. 
know, before we know how to use them, we 
need to know how you get them, where they 
are, how much there is, and how diffuse 
they are. 
So, let's look at wind today. 
Wind energy is the biggest contributor 
from renewable energy of all the sources, 
much more higher than solar and much 
higher than the renewable biomass, 
and so, it's, it's an important renewable 
energy resource. 
the way we reap the energy, of course the 
wind energy, is with wind turbines. 
Here's just a shot of a small wind farm. 
on land, wind farms are generally fairly 
small relative to offshore wind farms, 
which we'll look at also. 
But unless they're out in the middle of 
the desert, which of course is good, 
because they, they generally have good 
wind resources with high average wind out 
in the deserts. 
This is an offshore wind farm that is 
very prevalent in Europe. Here's a shot 
of a beautiful view of, if you go out and 
look at them. 
I made a trip in 19, in 2005, I guess it 
Six over, visited several of the offshore 
wind farms in Europe. 
of course, servicing them is more 
expensive constructing them is more 
expensive out of the water than on land. 
one good thing, though, it's easier to 
ship for very long blades that you have. 
And so those are the, you notice they're 
on pylons and those pylons of course, put 
them up off the surface of the earth, 
whether it be land or water, 
and one thing we find is that energy 
resources, 
the average wind speed increases with the 
height above the earth's surface of water 
or land. 
it also varies with geographical 
location. 
Some areas is meteorologically have a 
higher average wind speed, which is what 
we want for high energy density and lots, 
lots of resources versus other 
geographical locations. 
I just mentioned height above the surface 
of the earth is, turns out very important 
as well see, 
so we'll like to put them on a very high 
pylon. 
That's economically, that's very viable 
when you have a very large wind turbine, 
because the pylon is only 15% of the 
total cost of the wind turbines. 
But if you're putting up a small, one 
horsepower, one kilowatt sized turbine if 
you put it up too high, you'll be 
spending more money on your pylon than 
you will on the, wind turbine yourself. 
But it course, it varies by weather, and 
if you're, get a stormy condition, you 
get high winds, 
if you get a calm, it's calm. 
You have differences in night and day 
because of solar heating of the earth, 
and of course, by as that, we already 
said, the different geographical 
location. 
So, again, it varies, by the way, the 
average is vary from winter to summer. 
it's the opposite of what sometimes we 
might assume regarding month of year, is 
that the average wind speed is generally 
almost all, all the regions is higher in 
the winter than the summer. 
that's good if you have peak demand for 
electricity in the winter for heating 
versus summer, but when you get into the 
south for instance, you would like to 
have more electricity and need more 
electricity in the summers for air 
conditioning. So [COUGH] wind energy, 
particularly where you have summer 
peaking energy demand, electrical demand, 
doesn't really match the annualized load, 
but we'll look at the average, the annual 
average on wind maps like we looked at 
the wind maps for solar. 
But they're a little more straightforward 
because this time it doesn't depend on 
the orientation. 
We can always point the wind turbine into 
the wind. 
These turbines will pivot around the 
pylon on huge bearings, 
and so that they're always pointing into 
the wind, and, that's not a big deal by 
the way. 
You, you notice the, blades, in that 
case, the case we're looking at here is 
pitched so that they're basically 
perpendicular to the, to the wind, 
and so, the, that's in the stop lock 
position. 
If the wind gets below a certain speed or 
it gets above a certain speed that could 
cause damage to the turbine they turn the 
blades into the wind and lock it down, 
they could do prevent damage. 
But let's look at the, how we classify 
winds. 
You, you classify winds by wind power, 
class one through seven and that 
indicates the range of wind power density 
and that's the watts per, when it says 
they're a class one, 0-200 watts of 
kinetic energy in the wind per cube or 
square meter of the area that you're 
capturing of the wind. 
So if your rotor blade is, in its 
circumference circle is capturing 10 
square meters, then that means that the 
total watts of kinetic, kinetic energy or 
power in that, in that 10 square meters 
is up to 200 watts, watts per up to 2,000 
for the class one. 
the power density is a little bit 
nonintuitive. 
You would think that the, 
because of the kinetic energy is all we 
think about, is always 1/2*mv^2 that as 
the wind speed goes up, the power would 
go up as the square of the velocity. 
But it actually goes up as a cube and the 
reason it does is, because is, is the, 
kinetic energy per unit mass of air goes 
up as the as the speed goes up. 
So if you double the wind speed, the 
kinetic energy per unit mass goes up by a 
factor of four, 
two squared is four, two times two. 
But the power density goes up by the 
cube, because the amount of mass is 
flowing through the wind turbine, goes up 
proportional to the velocity. 
So, the power density in watts is, goes 
up by the cube, which is really makes the 
higher wind speeds pay off liberally, 
because if you double the wind speed, the 
power that you get out of the turbine in 
kilowatts, a given turbine will go up by 
the, a factor of eight. 
If you double the wind speed, the power 
coming out by the generator goes up by 
factor of eight. 
So it's really sensitive to wind speed. 
The economics of wind farms is really 
sensitive to wind speeds because of that 
cubic relationship. 
We'll look at that a little more later. 
Here's a wind map. 
Again, this one comes from NREL, 
they got good map resources. 
and we've said that it varies with the 
wind speed, as this one shows, 
varies with the height above the surface 
and this is at about at 100 feet. 
So wind maps aren't any good unless you 
know at what height it's taken. 
This one, as you look across the top up 
here look across the top, it's at 30 
meters. 
U, U.S. 
annual average windspeed at 30 meters 
there about 3.3 feet per meter. 
So that's about 100 feet that's 100 feet 
above the surface. 
looking at the diagram or looking at the 
map, we can see that over here in the 
southeast, where I am, in Atlanta, is 
dark green, which is way down here with a 
average wind speed of aroud four meters 
per second. 
That's not economical. 
It's it's, you can, you can get 
electricity from a wind turbine at that 
speed, but the economics are really not 
going to work and by any stretch of the 
imagination. 
if you get out here and get the, the red 
areas, now you're up to about seven 
meters per second if we look there. 
If we take meters per second times 2.5, 
you get miles per hour. 
So a wind speed of seven, I mentioned 
that the, that the, the orange and red 
out here is about seven, six, and half to 
seven meters per second. 
Well, that's two, two and a half tiems 
seven is about 17 miles per hour, 
so that's a pretty good wind speed on 
average. 
That's the average wind speed 24 hours a 
day, 365 days a year. 
sometimes it's higher than 17 miles per 
hour, but sometimes it's lower. 
So you can see why the wind turbines tend 
to be out here in the midwest and over 
here, again at, at a 100 feet above the 
surface out here in the northwest, 
there, there's not much. 
Now, there are some regions that 
particularly around the Portland area, 
that does have some good wind speeds, 
but that's a very localized situation. 
Let's move up to a higher height now. 
Let's move up to 300 feet, because the 
new larger wind turbines are placed on 
pylons about 100 feet. 
Now, the color coding for the wind speed 
is exactly the same as it was in the 
previous map, the same, 
same color coding. 
We'll get it here in a minute. 
the same color coding that we had before, 
but you notice, the dark green is 
essentially totally gone away. 
So the lowest, now that we're showing, 
even in the southeast, is around four and 
a half, five meters per second. 
So, that's five meters per second with 
the lighter green here would be about 12 
miles per hour, average speed of about 12 
miles per hour. 
That's still not, not really economically 
viable, 
but you notice, you got to spend some 
money to put it up on a high pylon of 300 
feet. 
300 feet is a football length in, in, 
height above the surface of the earth, 
It, it's 80 meters, 80 meters, again. 
It is in conversion factors, that is 3.3, 
3.3 to give you feet, so 80 times, times, 
3.3 is about 270, 280 somewhere in there. 
I used approximate science that we don't, 
no need to get bogged down in decimal 
points here. But you notice, you're 
really out here in, in the Rockies, 
you really get some high wind speeds out 
there around above eight, eight, nine 
meters per second, 
which is averaging over 20 miles per 
hour. 
Now, this also shows offshore, 
which the previous slide didn't shows 
offshore. 
But the first thing to notice about the 
offshore, is as soon as you get to the 
coast to move offshore, 
looking over here in the Atlantic coast, 
the wind speed goes up, 
because when you look at the chart, it 
goes up dramatically compared to on line, 
on land. 
So on land, you really don't have any 
commercially viable wind energy, wind 
resource out in the eastern coast there, 
but as soon as you move offshore, you get 
some dark purples at the same as it is 
out here. 
But as I've already mentioned, 
unfortunately, it takes more money to 
build the turbines out In the ocean and 
requires more to maintain them. 
Same way on the west coast, but another 
thing you've got to be worried about when 
you put in an offshore is the depth of 
the water. 
current technology, 75, a 100 feet depth 
is about as deep as you, we really go 
down with the pylons. 
the, the next slide, this one shows the 
just offshore by itself, 
but you can see again, same, same 
same chart here and see if I can get it. 
This oh, there we go, 
same chart and this actually shows miles 
per hour as well as meters per second 
here, 
But, that's the reason offshore, looks a 
lot better, and people are pushing, 
trying to get more offshore a wind. 
The first offshore wind farm in the U.S. 
has been permitted only recently, hasn't 
started construction yet, it's Cape Wind 
off the Nantucket, and hopefully will, 
supposed to be operational 2014 or so. 
they've had some obstacles they've had to 
overcome, but offshore wind has, has a 
good wind, good potential because of the 
high resources offshore relative to on 
land as we see from these maps. 
Oh, and if we go to the source of these 
maps, we find NREL again, and you can 
download these and take a look at them. 
And this is the page here that has got 
all the maps and has got some row, low 
resolution and high resolution. 
you see, you pick the map [COUGH] and 
take a look at it yourself and we'll have 
you do that. 
Okay. 
So that gives us an overview of wind 
resources and why a lot of the wind farms 
are out in the mid, midwest and southwest 
and why there not, not any wind farms in 
the southeast and eastern coast in 
general. Okay. 
Thank you. 
See you next time.