I think that you have pointed out the flaw in this paper. The key piece of data is to measure the mixing between wind farm wakes and the atmosphere just above. It is believable that measurable slowing of the surface winds could be caused by very large wind farms. It is not believable that there is no mixing as this paper posits.

compare and contrast with what is needed for BAU.

A renewable grid isn't BAU.

If wind power was going to be the answer to world's problems, it would have to doable by all the countries of the world, including the Bangladeshis and Somalians.

Why? Fossil fuel isn't.

build an HVDC grid" it is said, to overcome the distribution losses of generators all across the country trying to feed the cities. But at what financial and energetic cost

Just do a quick google search, you'll find it's affordable. IIRC, 1,000km costs about $.25/Wp.

When was wind power going to be the only answer? It is part of the answer. Wind, solar, wave, more efficient distribution, storage, and to your point, conservation/more efficient use of energy are all going to have an important role.

Your point that the methodology is transparent and open to modification is quite valid. I think this methodology is too conservative while some of the other projections are way too optimistic. Still, I am not sure anyone would give up a Terawatt of production capability that has no carbon footprint.

We consider the first 200m depths, see your second figure.

This floating WT-pilot is already in 200 m of water ....

claim ;The wind turbine can be placed at ocean depths of between 120 and 700 metres.
more here ; http://en.wikipedia.org/wiki/Floating_wind_turbine

Diffuser Augmented Wind Turbine draws in more air and increases efficiency. It is claimed that this design is not limited by the 59% maximum efficiency for an ordinary turbine and generates about three times more power than an ordinary turbine of the same blade diameter.

F2=0.5 means that you could access 50% of the entire Earth. a kite attached to the seas? Sci-fiction.
F3= same (for kite type take 0.0001)
F4=1, but obviously is extremelly optimistic (we use the best places for economical reasons)
F5=0.9 again very very generous.
F6 = same=0,5, generous (probably much lesser than mills, and with a bad EROEI)
Therefore, if P0=1200TW you get 0,027TWe for kite-gen type apparatuses...

That won't suffice.

Shox said autonomous floating windmills can operate on deep-seas.

If you have an anchored floating windmill, then the water must be shallow enough to anchor it, which rules out most of the world's oceans.

That's probably true. I didn't think of the implications of the density difference between water and air. It's probably not overwhelming practical but it might work in theory.

And then I got carried away with idea of free floating windmills in the Southern Ocean powering floating cities, but somehow that seemed more practical than a lot of the stuff that gets posted here. At least there would be no shortage of wind there.

whenever you see some argument presented to you by her on this, directly or indirectly, it is best to come to it with a very suspicious mind knowing that there is always a very polemical, one-sided, hostile urge behind it.

That would tend to explain why my fisking of Michael Dittmar's error-ridden pieces was so ruthlessly and consistently censored.  It doesn't matter if the ideology is wrong, it only matters if people get to see that it's wrong.

Of course it's a good argument. In fact it is an argument that completely obliterates this guys whole thesis.

Only if you assume that the amount of wind power that can be tapped is proportional to the surface area devoted to wind farms. I.e., that tapping the wind at location X has no effect on wind at location Y. That's not the case.

The key factor in how much power can be sustainably generated from wind is not how much wind happens to be blowing across the world and any given moment, but rather on the rate at which wind is regenerated after being dissipated by turbulence, friction, and any wind turbines that happen to be in its path.

It's long bothered me that wind resource estimates are made simply from measurements of how much wind there is at available sites. There seems to be no regard for depletion of wind resources. But there's nothing magical about wind; when you take energy from it via a wind turbine, the energy you've withdrawn from the system doesn't just magically reappear. The wind is a kind of bank account of kinetic energy. Friction creates a steady leakage from that account, balanced by a steady income driven by differential solar heating of the atmosphere. It's the rate of income that ultimately determines how much can be tapped, not the instantaneous size of the account.

Betz law and the 30% interaction with blades also seems like double accounting

I believe that current turbines already get close to 0.5 (Betz limit is 16/27), so an extra 30% is only reasonable as a factor for crosswind turbine spacing.  I'll let you re-read with that in mind, I have no time ATM.

I think you're missing a bigger story in Alaska.  The Kodiak Electric Association has already shifted largely to hydro and wind, and is looking to upgrade the hydro plant and add more wind turbines to go 95% RE.

The new Nordex N117 produces a 80% higher capacity factor than the popular Vestas V80 at the same location:

If I check in the paper, I can only see:

Every year, the N117/2400 notches up more than 3,500 full-load hours at typical locations, outstripping other products in its category by 20 percent. It achieves a capacity factor of up to 40 percent.

Your document seems to says 20%. I don't know what to think about the 20% more means 40% capacity factor, I can't see how 19% * 1.2 = 40% unless the 40% is theorical.

Now, I can assume the Nordex N117 dosen't cost that much more, so you get more power with a little more money.

What I care is actual output versus cost. I don't care if the turbine is up 50% of the time, or 1% of the time, it's the quantity produced that I'm first concerned about.

Cape wind is a bad exemple, but let's run the numbers:

Cost is $2.5 billion and annual production is about 1.5 billion kwh (using the wikipedia entry). That gives us a construction cost of $1.66 per kwh.
If you take nuclear, we have $14-18 billion for 17.3 billion kwh, hence around $0.90 per kwh for construction costs.

Nuclear reactors last 60+ years, wind farms 20+.
Operating cost for offshore wind farm are about 2 to 4 cents/kwh ¹, nuclear is 2.2 cents/kwh ²

______________________________________________
¹http://www.ecn.nl/docs/library/report/2007/m07120.pdf
²http://www.eia.gov/cneaf/electricity/epa/epat8p2.html

Could you point to any example? I've read Smil extensively, he was a bit reluctant to recognize peak oil and in general, predictions about energy.

> Vaclav Smil has written some flawed stuff....

Maybe. I had to overcome my incredulity a few times. But when I did investigate a few things, I came up with minor quibbles and uncertainties. Nothing that was clearly wrong.

... that is, leaving aside the typos. That book has at least two on every page. Someone sure cut costs on the sub-editing.

And/or if smart grid technologies are employed within the blend of storage and transportation.

http://www.rltec.com/gridbalancing

1TW*24h*365days

Wait a minute here, it's wind power and wind power is intermittent. Using economic resources, we'll use a capacity factor of 40%, so we'll have 3504 TWh.

The earth radiation budget is something like 240 watt/meter squared. I think current CO2 is 1.6. The solar constant is roughly 1350. Divide by four for geometry, then take out about 30% due to reflected energy.

A PV panel can cool very quickly. What hits urban areas nighttime temps, are surfaces that are connected to large thermal sinks, that absorb heat during the day. Pavement, seems to have a pretty long thermal memory (taking several hours to heat/cool), whereas stuff like vegetaion or unpacked soil, changes its surface temp within minutes. I can recall being in the Phoenix area during a summer heatwave. If you stepped onto a sidewalk barefoot, at midnight, it was still hot enough to burn your feet!

But again, PV & solar thermal, needs a pretty small collection area. Also most vegetation has pretty low albedo anyway, and outside of deserts and snow/ice covered unvegetated areas, the surface albedo is actually pretty low, so putting up dark panels only affects the shortwave energy balance by a little bit.

I'm guessing you drive Altamont.

Those turbines are 30 years old and short. They are being replaced by fewer, but taller models. Stuff we didn't know how to build three decades ago.

There were several test turbines up there. It served as a useful nursery to get the industry sorted out. Some of the designs were real turkeys.

Probably in 30 more years we'll look at the current set as a bit primitive. But they, like their predecessors, will have cranked out a lot of useful electricity.

We've got some new blade technology in the works that will change things.

how old were they?

And mountain ranges, don't just create local friction, they create atmospheric waves that can go on hundreds of miles downstream. And these are a major source of frictional dissaption within the atmosphere. I doubt anything we could do to the lower boundary layer could come close.

There are some things in this busy life that we simply have to evaluate on a Heuristic level, and just decide whether it's worth going out to the next stage and doing the research and the math..

I would be fascinated to hear what someone comes up with, when adding up all the;

industrial towers,
skyscrapers,
telephone poles,
High-tension Line Towers,
Ski Lifts,
Oil-Rigs,
Container Ships,
Very Large Crude Carriers,
Railway and Highway Bridges,
Dams,
Great Walls,
and other Manmade Wind-barriers..
(to name a few things..) as well as perhaps deducting a bit for all the Deforestation, Desertification and Mountaintop removals that we've also had a heavy hand in.. but I'm really hard-pressed to believe that the question of windfarms affecting Global Wind to a worrying degree is really very high on the list of Global Concerns, or how much, in fact it would really affect wind patterns and force to such a degree that it would impose a limit on the amount of energy extractable from wind currents.

As mentioned above by BOTH sides of this argument, the vastness of the oceans might be visited by 'some' wind production, but will really barely be touched by this intrusion.. so I'm left to wonder how serious our impact really can be to the global air-currents.

Yes, we've said such things before, about the Whales, about Petroleum, about the Fishing-Grounds.. 'they're too big for us wee humans to EVER affect" and yet we've truly been able to mess up our Biota, and we continue to do so. But the inclination to give renewables an extra set of hurdles to pass seems to be an almost irresistable snack for the eager iconoclasts.

If only as much energy were being put into challenging Coal.. ... maybe that's just too easy?

The energy transfered to ocean waves are around 60TW, therefore in the first 200m more than 60TW dissipate over the oceans, more than the 60%, may be more than 75% and may be less. You have Antartica (the windiest continent), it occupies less than 3% but dissipate more than 3%. And do you have many other inaccesible (technical and economical) sites: Amazonas, cities, Himalaya... Really 20% of Earth is accessible? it seams too high.
In our paper:
"...referred to in Table 1, and is only comparable to the estimation by Smil (2008) ( <10 TW), except for the physical–geographical potential estimated by Miller et al. (2010), also using a
top–down methodology, which is 17–38 TW (our physical–geographical potential, applying only f1, f2 and f6, which is comparable to Miller et al. (2010)’s methodology and calculations, would be <40 TW). This means that technological wind power potential imposes an important limit on the effective electric
wind power that could be developed, against the common thinking of no technological constraints by economic, ecological or other assessments".
Miller et al. +f3+f4+f5 that they do not take into account will give 0,5-1TWe, even less than our limit.
Miller et al. paper reinforce our results not the contrary.

No, your analogy is silly. When we take a factor like f2 we do not refer to the surface available for wind parks but the power being dissipated in those available sites. And so on. In fact you take an erroneous and invented average (0,02W/m2) with no sense. The winds in Antartica will dissipate there know and in the future, we think that this power is not accesible, therefore we disccount it. Easy.

retrograde: "First, a large offshore wind farm: these tend to have a fairly dense paking of turbines, so they should demonstrate limits of performance for downwind turbines". Please read the paper and some of the literature cited. (See for instance Christiansen, M.B., Hasager, C.B., 2005. Wake effects of large offshore wind farms identified from satellite SAR. Remote Sensing of Environment 98 (2–3),
251–268 15 October 2005). They identify a loss of 10% of velocity downwind of the parks during around 10 km, this means that if you put a park there (as bottom-up methodologies do) you will have a much lesser efficient parks. Top-down methodology try to overcome this error.

But that 1200 TW is a global average, and it is used even though the other factors limit the surface area being considered to significantly better than average land. It is applying a population-wide average to a skewed subset of the population,

No. The 1200 TW is the total, not an average.

To draw an analogy, this is statistically comparable to saying "most people are between 4 and 7 feet tall, so we'll choose an average of 5 foot 6, and use that as a base assumption of height in our study of ... college basketball players.

Retrograde puts it clearly, I was having trouble formulating it, thinking - Oh that way you could prove Mensa members ...are stupid! (average IQ = 100 by definition - Mensa members are selected on their stellar IQ...) but then there’s the real world where Mensa members can obviously be shown up as dopes.

So it is a measurement problem, or better: the *disjunct* between logic and quantitative manipulations (math) performed on some measure (or quantity, or proposition) defined in a particular way (the arbitrary and very wonky IQ is a good example) and real world facts / examples becoming muddled, in their perception by participants, till the both the forest and the trees disappear from sight. (oh right, they cut down wind..;)

The tension between the two is a genuine, worthwhile struggle. Having it polluted by pre-set ideological stances or inflexible opinions (e.g. against wind, pro or anti nuclear, etc.) or even some rather indirect political slant is inevitable I suppose. (?)

An interesting article though, and some good discussion, it prompted me to post again.

Noirette - then Noizette.

Did you read the paper?
See also:
· Gans, F., et al., 2010. The problem of the second wind turbine—a note on a common but flawed wind power estimation method. Earth System Dynamics Discussion 1, 103–114. doi:10.5194/esdd-1-103-2010
· Wang, C., Prinn, R.G., 2010. Potential climatic impacts and reliability of very large-
scale wind farms. Atmospheric Chemistry and Physics 10, 2053–2061.

Authors that use bottom-up methodologies conclude that the potential (with mills of 100m) is around 100TW, they exclude deep-seas, Antartica etc., they exclude sites with very low wind velocities, etc. They exclude also high altitude winds. How is it possible that we can interact and dissipate almost the 10% of all the power of all the atmosphere (10 km high)? If we do the reverse calculations of the bottom-up methodologies we could conclude than much more than 5000TW is the power being dissipated in the atmosphere. This is because this methodology do not conserve energy. We can not extrapolate to the global escale the velocities in local sites as bottom-up methodologies do. In fact, some authors, especulating about high altitudes winds, conclude than 1500 TW is dissipated only in the jeat streams, more than in the entire atmosphere!
The molecule that carry a good velocity in New York is the same than carry a good velocity in Tokio some hours later. If we take this two velocities and sum the power, we do the bottom-up approach, but if you catch this molecule in New York with a windmill, then obviously you will not catch it in Tokio (energy must be conserved).

If your calculations are correct, then the Swedish wind mills are in trouble because the upwind Danish wind farms take a lot of energy out of the wind. Is there any real-world data showing such an effect?

In fact 1TWe is around 4-5TW kinetic

Really? I would have thought that a joule was a joule was a joule. Sure, if we literally convert from electricity to kinetic energy we will lose 50%-80% of the power in the conversion, but does that really apply here??

this is around 4-5% of wind power interacting with mills of the total power being dissipated in the first 200m

But that's not the whole system. The whole system is 1,200TW. And, the 1TW we're discussing is indeed "several orders of magnitude smaller".

So you beg the question - what energy conversion/production system operates near to "in perpetuity"?

Oil can be synthetised, albeit at a significant cost, but certainly $200 per barrel can be though of.

I cannot simply assume a wholesale dismissal of all of these other articles based on a weak, overgeneralized 'analysis'.

That is probably why you must believe that the thousands of studies published by the economicists about the good health of the world economy could never end in the chaos we have these days. Or as we say here: “three trillion flies cannot be mistaken: eat sh.t”

What is important is the evolution of turbine heights, instead of counting the ones installed in the 80s and 90s, so 200m is appropriate for land based turbines, though does not take into account the advantages of mountain ridges.

I think that what is really important is to stick to the facts and realities and understand that in a finite world, nothing, absolutely nothing, can grow indefinitely, including wind generator heights. And with respect to the mountain ridges advantages, have you ever seen where they have been installed in Spain? Precisely, many of them, in mountain ridges in the top of the slopes between plains and plateaus or in the wind corridors like the Gibraltar Strait.

Why citations are needed for the 1,200 TW of total global wind energy at all levels and in all latitudes?
Because this is a key factor in the simple formula presented, and every key factor should have sufficient support.
They are cited in the article and besides, if somebody believes that they are flawed, they should prove the contrary.
We are not the ones proposing a scientific claim - we are asking what the process for identifying and selecting the values for the key factors were chosen, which is the most basic of scientific inquiry.

Perhaps they did not identify so clearly here the citations. The original paper in Energy Policy quotes for this precise figure of 1,200 TW of total energy contained in the winds of the planet to several authors, varying from Gustavson (3,600 TW), Lu et al (340 TW); Lorenz (1,270 TW); Wang and Prim (860 TW); Peixoto and Oort (768 TW); Skinner (350 TW); Sorensen (1,200 TW)and Keith et al (522 TW.

Apart from that, if you still do not trust this figure (I agree with you that the figure of total kinetic energy contained in all the winds of the planet is essential to any study), I can offer you Josep Puig and Joaquim Corominas figures (La ruta de la Energía, 1990) where they assess 1,200 TW for winds, as a subset of the 172,500 TW of the solar energy radiation on Earth, from which all the winds derive. Now, if you have better figures, please let us know. If you need more support, please go to the Enciclopaedia Britannica (Macropedia, Climate and Weather) and see the percentage attributed to “turbulent transfer of heat from surface to atmosphere" and others on the total radiation. I hope that there are no discussions about the size of the Earth and the surface offered to the sun, to calculate how much energy is projected on the planet at 1,359 W/m2 (outer space)

And that of the upper limit of all kinetic energy of the winds is effectively a key figure. All the kinetic energy in the winds of the planet at all heights (up to 30 Km high) and in all latitudes (Northern and Southern Poles, oceans and seas (3/4 of the total surface), inaccessible mountains, national parks (or you want also to fill the Yellowstone with windmills?), etc., etc. represent 1,200 TW, being very optimistic and positive.

Then, if this key figure is finally accepted, and we reach the first mathematical conclusion that capturing, intercepting and transforming 1 TW would mean to divert, brake, slow down or curb 1/1,200 of all the winds in the planet with technofixes. So, we are concerned about changing 1/10,000 of the composition of a component of the air in the planet (280 to 380 ppm of CO2 in the atmosphere) and here we still have many people arguing that diverting, braking, slowing down or curbing 1 TW is ridiculous and that we have potential to divert 100 TW.

Does anybody here really believe that we have the technical possibilities to access to 1/1,200 of all the winds of this planet?

I wonder how is it possible to find so many readers in this page that simply say, to this only figure:

• I suspect that the analysis is actually more wrong than you posit above
• Again, an arbitrary, seemingly random value is set forth as yet another premise with no support.
• 1 TW from all the wind in the world. That's pretty sobering.
• The deficiencies in the quoted analysis aside, I think the takeaway message is "go nuclear".
• It just makes assumptions about this based on...apparently nothing.
• I suspect there may be a flaw, He excludes all the areas we won't get wind from (deep seas etc.), then invokes using up the global resource. I would think the only way you take too much global wind, is if you take wind from all the areas of the world.
• Exactly my thinking. This must be the most obvious error in the piece. Betz law and the 30% interaction with blades also seems like double accounting, but I may be wrong. Also, I agree with the folks that claim it just isn't a reasonable result. 22x is obviously too little.
• I always believed that the very optimistic projections were unrealistic. However, you effectively push back because the analysis doesn't quite pass the smell test.
• Sure Mankind uses a large amount of electricity but compared to renewable's such as wind,solar,wave etc our consumption is negligible.Any one of the major renewable's alone could easily power our needs 100 times over.Only those that have a vested interest in seeing renewable's fail will speak,talk,write,persuade etc against em.
• It just doesn't add up.
• This article seems to be a real stinker.

Come on, a little bit more of reflection and scientific mood on what we can do with the basic elements as the Greek understood them (water, air, fire and land)

Well, on a theoretical level just about everything is finite. On the other hand, what matters is if we're anywhere near that limit, on a practical level: airplane designers aren't worried about the limit imposed by the speed of light.

In this case, I can't see 1TW as significantly depleting a 1,200TW system.

See France perhaps.

Let me say this in advance:  I'm glad you asked.

Can you please illustrate how the nuclear power can scale up in a near term with examples and statistics of the last 30 years?

It's interesting that you select the last 30 years, because it's been just about that long since the anti-nuclear movement got rolling in a serious way with e.g. MUSE.  That momentum is now waning, as people realize that the scenarios of mass deaths have not materialized even from Chernobyl, and major personalities in the green movement such as Patrick Moore and James Lovelock have shifted their stance to pro-nuclear.  The last 30 years will, I hope, be seen as a historical aberration.

In the US, plants which were shut down have been re-started, and construction is resuming on units which were mothballed.  This trend is already moving.

Or by extrapolating the most furious deployments in the 60's to 80's, that will merely give time in the next 30 years to replace the 430 operative ones that have to be decommissioned in the period the new ones have to be installed -10 years average from decision to switch on for each plant-?

430 plants over 30 years is less than 15 per year (assuming the same capacity, which is a bad assumption).

It would not take a very high rate of construction to build out a new system in the USA (which is what I will limit my analysis to because I have the data for it).  For instance, the USA has enough transuranics in spent nuclear fuel to start approximately 40 GW of fast-breeder reactors.  If these were 300 MWe S-PRISMs, the quantity required is about 133 reactors; at the rate of 1/month, building the vessels and such in a factory and shipping complete to the installation site, building out would take about 11 years (followed by a trickle of new plants to consume the on-going flow of SNF from the LWR fleet plus the growth in the fuel supply from breeding).  To take care of the whole world, construction would have to speed up to one unit per week.  This is roughly the construction pace of low-volume airliners, which are similar in size and complexity.

The fuel supply for S-PRISMs is not an issue.  The USA is sitting on almost 500,000 tons of depleted elemental uranium.  At a consumption rate of 1 ton per GW-yr, this inventory can supply US electrical consumption for over 1000 years, or total energy demand for over 300 years.  The S-PRISM does not scale rapidly, but at GE's projected breeding ratio of 1.22 for a core with axial breeding blankets, the fissionables supply would increase by about 2%/year.  This is on the order of the rate of increase in oil extraction which fed the economic expansion of the 20th century.

At the end of 30 years, S-PRISM starts will roughly equal the total output of the end-of-life LWRs which fed them (figure 70 GW), plus about 1 GW for each 60 GW-yr of output from the LWRs still operating (figure 10 GW), plus growth (figure 45% over 19 years from end of the initial ramp).  That comes to about 110 GWe, plus about 20 GW of LWRs still running.

FBRs scale too slowly to do the job alone.  The Liquid Fluoride Thorium Reactor (LFTR) can do the rest.  LFTR can be started on a charge of enriched natural uranium and switch over to ²³³U bred from thorium.  At a fuel consumption rate of 0.9 ton/GW-yr and a fissionable inventory of 1 ton/GWe, less than 2 years of LEU would be needed before the LFTR switched over to thorium.  LFTR has faster natural growth (breeding ratio up to 1.07 and much lower fissionable inventory).  At a growth rate of 5%/year, the LFTR fleet could double every 14 years.  Starting 225 GW of LFTRs over 12.5 years at 300 MWe/unit is 60 units/year or 5 per month, also on the scale of airliner construction rates (the B787 rate is 2-10 per month).  The growth rate of 5%/year would continue construction at the rate of around 40/year at the beginning, doubling output to 450 GW by about year 25 of the 30-year period and increasing to about 560 GW by the end.

Note that these two systems can feed each other.  The spent LEU from LFTR startups contains some Pu, which can be used to start more S-PRISMs.  If the self-scaling efficiency of S-PRISM is sacrificed, it can breed excess ²³³U instead of ²³⁹Pu and each GWe of S-PRISM capacity can start another GWe of LFTR every 5-6 years.  That's about 7 GWe/yr of new LFTRs based on 40 GWe of S-PRISMs (ignoring growth from LWR fuel), or an additional 200+ GWe of new LFTRs over the 30 years from program start.

Those are two technologies which are reasonably well understood.  Others may do better.  If e.g. molten-chloride FBRs are developed, I don't know what they'll be able to do.  The combination of on-line reprocessing (no inventory stuck in fuel cooling and refabrication) and purging of xenon from the core should improve the scaling rate a lot.

Or are we thinking again in a Marshall Plan or hyperManhattan plan to multiply 10 times those rates of the 60's to 80's?

More like Moore's Law.  Everything gets smaller (mining rates, waste stockpiles, physical system sizes) except the power output.  Going from a billion tons a year of coal to a few hundred tons/year of thorium plus uranium from inventory is a huge reduction.

Or the uranium resources available as per the Red Book to feed all tis imaginarium?

S-PRISM requires no new uranium.  Running 36 GWe average of LFTRs on LEU over 12.5 years to establish the initial 225 GW fleet takes around 10,000 tons/year of uranium.  Natural growth takes no uranium, just thorium.

How it comes that nuclear power is so economic, if when they have the doors opened to develop and install nuclear plants in the USA or in Spain, nobody gets into the business, unless dad State provides enough securities and backing guarantees to entrepreneurs?

Because "dad State" has a history of changing its mind every 4 years, or whenever certain pols get paid to throw spanners in the works.  If the state pays a price for changing its mind, those changes are less likely and the investment is quite a bit safer.

Please observe that I have not used Fukushima as an argument.

That's good, because the relatively benign effects turned George Monbiot into a supporter.

Can you please illustrate how the nuclear power can scale up in a near term with examples and statistics of the last 30 years?

France decided to replace it's mainly oil based electric power in 1973, due to the oil crisis. In 1992, it had reached 75% nuclear. That's 19 years.

Or by extrapolating the most furious deployments in the 60's to 80's, that will merely give time in the next 30 years to replace the 430 operative ones that have to be decommissioned in the period the new ones have to be installed

1985, according to WNA nuclear reactor database, saw the commercial operation start of some 42 reactors. Nowadays, each reactor is bigger and we should be able to build even faster after a ramping period.

Or the uranium resources available as per the Red Book to feed all tis imaginarium?

Economically extractable mineral resources never "last" more than a hundred years, because you won't prospect more than that. But we can pay a hell of a lot more for uranium, so reserves can be expanded an order of a magnitude, at least.

How it comes that nuclear power is so economic, if when they have the doors opened to develop and install nuclear plants in the USA or in Spain, nobody gets into the business, unless dad State provides enough securities and backing guarantees to entrepreneurs?

Because coal is cheap and because the doors aren't really that open - the remaining regulatory burden on nuclear is overwhelming. If it is not partly compensated by guarantees, it's a no-go.

Indeed. As a layperson trying to get a grasp as to the validity of the conclusions of this paper it seems that the experts in the field have yet to reach a consensus as to the true upper limits of energy that can be extracted from wind without causing serious damage to the climate and the ecosphere... How am I supposed to make any sense of the following?

De Castro C. et al. 2011.

Economic, ecological and other assessments have been developed, based on these technological capacities. However, this paper tries to show that the reported regional and global technological potential are flawed because they do not conserve the energetic balance on Earth, violating the first principle of energy conservation (Gans et al., 2010). We propose a top-down approach, such as that in Miller et al., 2010, to evaluate the physical-geographical potential and, for the first time, to evaluate the global technological wind power potential, while acknowledging energy conservation. The results give roughly 1TW for the top limit of the future electrical potential of wind energy.

Estimating maximum global land surface wind power extractability
and associated climatic consequences
L. M. Miller1,2, F. Gans1, and A. Kleidon1
1Max Planck Institute for Biogeochemistry, Jena, Germany

5 Conclusions
We estimate that between 18–68TW of mechanical wind
power can be extracted from the atmospheric boundary layer
over all non-glaciated land surfaces. Although wind power
extraction from a single turbine has little effect on the global
atmosphere, many more will influence atmospheric flow and
reduce the large-scale extraction efficiency. Any extraction
of momentum must also compete with the natural process of
wind power dissipation by boundary layer turbulence.

Comment on “Estimating maximum global land surface wind power
extractability and associated climatic consequences,” by L.M. Miller, F. Gans,
and A. Kleidon (Earth Syst. Dynam. Discuss., 1, 169189,
doi:10.5194/esdd11692010,
2010).
Mark Z. Jacobson*, Cristina L. Archer!

We believe the wind power resources from MGK10,
estimated as 17-38 TW over land, are low by a factor of up to four due to the
unphysical nature of MGK10’s calculations and the fact that such calculations are not
comparable with data derived wind resources. Further, even if MGK10’s wind
resources were correct and their scenario realistic, the climate consequences stated
by the authors are overestimated by a factor of at least 50‐100.

I'm amazed when people make studies that basically claim that wind hardly exists.
(Since mountain ranges, forests, cities etc. create orders of magnitudes more friction than the number of wind farms in the study mentioned above ever could).

This article talks about 1,200 TW for kinetic wind energy worldwide. It can hardly ‘harldy exists’

Mountains, forests, cities, etc. create friction, as ever since Earth has mountains, forests, cities, etc. exist. That is why we have forests (wind helps to move leafs, interacts with oceans and seas to create waves that create marine life, stabilizes climate, etc., etc., etc.

That is why we have (probably we had) with these frictions, among other natural things, like the sun rays, the evaporation, etc. the wonderful world we have today.

If we recognize that the human attempts to capture energy with wind generators are targeting the wind power to replace in the medium term a significant percentage of the dwindling, limited and depleting fossil fuels or uranium (about 10 billion Toes/year now), as per the own wind industry and apologists are claiming, then we are talking about the need to install, not the 0.2 TW of today in wind power (2 percent of the world electricity), but something probably between, let us say 40 percent of the world electricity and/or 30% of the primary energy. This is if we believe that wind energy is something else than Micky Mouse games.

And this will require between 5 TW and 12-15 TW of wind installed power, working at 20% load factor (if possible). This represents between 1 TW and 5 TW of captured energy from wind IN A NEW, DIFFERENT FORM than the natural friction with the Earth surface natural elements.

And this is a newcomer interference of between 1/1,200 and 15/1,200, which is a butterfly effect much bigger (10 to 130 times) than the effect that today worries to thousands of specialists in Climate Change and Global Warming, for the introduction of an extra 1/10,000 of a single component of the air: the CO2 from 280 to 380 ppm.

That is why, not to enter in the feasibility and materials and financing and many other things required to put 10 TW wind power in place.

Are you serious? Any data apart from a biased article on how good the parabolic through solar plants are going?

Here there is some data from a country which has plenty of parabolic trough plants and is exporting this technology to the US and installing plants there:

2010. Solar Thermal energy in Spain (best insolated country in Europe):
Installed base (grid connected or feed-in mode): 532 MW
Energy sold: 692 GWh
Operative installations: 13
(Data: Official sources: Comision Nacional de Energía CNE: http://www.cne.es/cne/Publicaciones?id_nodo=143&accion=1&soloUltimo=si&s...)
Some other data from the industry (Prototermosolar, Spanish Association of the Thermoelectric Solar Association) in July 2011
Operative: 19
Under construction: 20
In Promotion: 22
Totalling 2,535 MW
Real world Efficiency –Load Factor-(not marketing paperwork or brochures) of the operative ones as per the official, ministerial, independent sources: 14.8%
They are allowed to account as “renewable” up to 15% of the back up gas fired power plants attached up to 15% of the production to give stability to the plants and to avoid the melting salt deposits used as an energy buffer for clouds and nights (usually 3 to 4 hours autonomy) to solidify in the nights.

Some solar thermal plants have been denied permits in Spain because they demand water flows of 6 litres/second in very good insolated areas, but where there is already a battle for water scarcity and Spain is the 4th. country in the world desalinating water. If this water has to be used to refrigerate the system and clean the mirrors and is in fight with the agricultural production, already desperately asking for fresh water, then we are making a bread like a Holy Form (Spanish saying) or killing flies with guns.

In Morocco, the problem is similar or even worst. Also several plants have been denied. In other places, multinationals simply take rights to the water and deprive agriculture of basic supplies in favor of modernity.

It is not as simple as your own rant that is going to be “more economic than gas” (when we will see in an energy forum people talking about energy EROEI, net energy, efficiencies and so, instead of comparing apples of economy with pears of energy?

Combined cycle gas fired plants in Spain are doing a great, great favor to the renewables. They grew from zero in 2003 to 25.2 GW of installed power in 2010. They were originally designed and built to reduce the CO2 emissions in a coal intensive country to comply with Kyoto Protocols. The plans were to be operative at least 5,000 hours/year. (57% load factor). Due to the priority given by law to the intermitent renewables to enter into the grid, the combined cycle gas fired plans were acting as swing producer. The more they injected, the less they could work. Today, they are working with 25% load factor (25.2 GW producing 64.9 GWh/year). Promoters are blaming and claiming to the renewables, because they are very much in the red, but they cannot apply to chapter 11, because the government does not allow, as they need to be installed as back up for renewables, just in case. Is this the type of economic cost efficiency you are comparing when confronting gas with renewables? Has anybody entered into an EROEI equation o renewables the extra costs of these idle combined cycle gas fired power plants, to make an electrical network feasible, plants that, by the way, degrade much faster than normal because forced to frequent switch on and offs, for which they are not designed?.

Hello Bob, thanks for the news about Macy's. Truly saving energy is much easier than trying to generate more. I read online that Macy's was seeing a one year payback on the new bulbs. Your 1 billion dollar savings seems too high ($1,000 per bulb), but whatever it is it will be substantial over the 10 year life of the LED.

I hope to see more comercial establishments in malls use the more efficient LEDs.

I think your graph is flawed as a tool for understanding; a growth rate of 1% of total generation per year is 100%/year at 1% penetration, but only 10% at 10% penetration and 5% at 20% penetration.  That gives you a y = 1/x curve.

If you graphed wind growth rate vs. fraction of total (not wind) generation, it would be much more obvious where limits start to kick in.

jg_
Yes, but the peaks show why the averages struggle to get above a certain level.
If a country has 18% energy generated by wind, a 10% growth rate is still going to result in 36% wind in less than 10 years.
The important figure is the world wide growth in wind at about 30% pa for the last 20 years. Many new countries are starting to add significant wind even if a few such as Denmark are "only" increasing capacity by 5-10% per year. If this was nuclear or NG fired capacity we would be calling a 10% growth rate booming expansion.

If you keep adding wind, eventually the only way to raise wind's _average_ numbers is to discard wind power at peak times.
two other ways are to use pumped hydro storage, or connect to a much larger grid when peak wind output will rarely exceed 70% capacity. A third way would be to use surplus wind power for example charging EV or heating domestic hot water.

Some remarks here:
I do not know where jg_ data bases come from. I quote the official data bases of the government institution, Comision Nacional de Energía (CNE) in his last released report June 2011 Added wind GW in Spain:
2008: 1.786
2009: 2.520
2010: 0.806
Half of 2010: 0.369

I agree that adding wind power in a given isolated electrical network reaches a moment in which more and more parks have to be switched off the net more hours in peak times, when base load (in Spain basically nuclear and coal fired power plants than can not be switched off on short advice or notice as per the wind variations). And this raises, like the case of Spain, many claims of the wind power plants owners that they are complying with the initial, theoretical number of nominal hours a year they were expecting in their business plans as per the on site preliminary studies.

But on the other hand, there is another indirect ways for wind power to raise wind average: the decrease in the national demand of electricity because the deep economic and financial crisis. As renewable energies have priority to enter into the network by law, this automatically increase the penetration percentage.

I'm disappointed to see something so deeply unrealistic from the German military.

I guess the US military has no monopoly on fear-peddling.