This Crazy Wind Turbine May Be The Future of Wind Energy

Is AirLoom onto something or is it just hype? The first 100 people to use code UNDECIDED at the link below will get 60% off of Incogni: incogni.com/undecided
If you liked this, check out Why This NASA Battery May Be The Future of Energy Storage ua-cam.com/video/2zG-ZrC4BO0/v-deo.html

Hi Matt, have you considered makeing a "where are they now" style video of technologies/companies you've spoken about in the last years? Would be cool to see the progress made

As a mechanical engineer, I see some potential issues with this design. One of them is how the blades would react to turbulent winds. I can see the blades twisting the track and really stressing the pulley system and even potentially hitting the vertical support towers. Having a single mid-point track does not have much resistance to twisting. There are plenty of moving parts here that would require upfront CAE analysis and thorough development testing to determine how long it would last and the conditions it would be able to survive (high winds, high and low temperatures, ice, etc.).

I think the fundamental issue is also going to be with friction loss, fundamentally they have more wearing friciton parts which would result in losses and increated in maintenance costs.

Great to see that you got back to being more critical again nowadays.
I had some problems with some of your videos in the past that felt like you were - to put it bluntly - parroting marketing material.
It's important to showcase new ideas and you're doing a great job at that, and it is good to see that you're staying critical.
Will go back and watch a few of the latest videos that i skipped.

A regular turbine can generally last at least 20 years. Many around where I live have worked for well over 30 years at this point. This point is mentioned in the video but I would like to see how long a track system such as the one shown here is going to last. These tracks, when used in the industrial applications I have seen, are regularly lubricated and maintained and operate in factories which, compared to a field in a windy area, is a relatively clean environment. I think dust and dirt buildup will make scrap out of those tracks in a few years without regular cleaning and maintenance. We'll see, but I doubt it will amount to much.
Also, thank you for including the recap of previous wind technologies you have covered. It is greatly appreciated.

The first thing that came to my head was "it's way too short". Maybe it's a good solution if you plan to put it on a big flat roof of a tall building (it would be more conspicuous than a solar roof, though)

I think you're right to be concerned about both the intermittency of low-level wind, and the overall cost of maintenance.

The key physical problem is the loss to friction due to the track system; a secondary problem is alignment as it seems designed to sit statically aligned.
Wish 'em luck!

Maintenance would seem to be the biggest issue. More moving parts, more problems. Close to the ground might be another issue, but there also may be places where the wind blows all the time.

I like this concept, and I could even see niche case uses, such as at the top of skyscrapers. At that height, you've typically got the wind, scale the device to the structure. It doesn't need to be crazy power generation if they're also cheaper to produce and maintain.

As others have pointed out, AirLoom is a vertical axis wind turbine where the central axis is replaced by a rail.

That does seem like a very high friction system in less than optimal wind conditions. I can see how, in theory, you could potentially capture more energy in a given footprint, however blade area is only one component in the lift equation. Velocity is a square component in the lift equation, so chasing higher air flow with taller structures makes more sense. Also the higher the aspect ratio of the blades the more efficient as well, this is one of the major driving factors behind taller wind turbines.

Matt Ferrell has become more skeptical and objective in his analysis.

To ship just one 56.9-meter blade by truck five hundred miles costs over $10,000 or $30k per turbine and that doesn't include the tower or Nacelle so even if they only meet half their stated goal this is a Game changer. Plus, farmers can plow right under them.

Well, I have 'concerns' about the blades being supported at just the midpoint. Imperfections and uneven wind could put a lot of twisting on that central mount point. Seems the earlier company shown, with two cable loops and blades attached at the top and bottom would be better. And of course the cable or chain that runs in the loop is a point of friction and problems. Cautiously move forward with a prototype and gather some real-world test data and experience I guess.

There is a 300MW wind farm, just a few miles from my home; I think they are beautiful. I've visited it a number of times and I really don't understand the fuss about noise. To me, the awe at realising, just one turbine, supplies 1000 homes, a decent sized village, with all the electricity they use annually. 'Twirl, baby, Twirl.'

If you could gimbal the blades as they travel around the track, you could maintain an optimal angle of attack regardless of wind direction and ensure the blades generate torque during their entire rotation.

One needs to define one's words and word definitions of wind turbine. Wind mills are a vertically based fan operation facing their "O" blades into all of the various (and moving) wind directions for wind propulsion of the blades. The design as shown here is not a "O" shape but a flattened elliptical on the ground. This is a fixed compass direction in which you need this device to have a constant (and fixed) wind direction in that elliptic. If the wind comes at this device on its sides, as shown, then you only have the small elliptical-circular ends of this design working against the greater majority of the whole unused (and blocked) portions of the device. If they were to truly do this design, then one must have a true circular design on the ground so that all wind compass directions are accounted for. This also means that the down wind blades of the device have proper movement, but that the connected upwind portion of the blades - must be designed to slip-stream through the wind (no wind friction drag) , and the 2 smaller opposing lengths of the upwind and downwind traversing blades must also be slipstreamed and no drag coefficient. The design is unique, but installing a vertical helical or a spiral wind turbine one has a smaller footprint, there is no great wind friction and drag on the downwind blades restricting its spinning motion.
As said, if one can make a circular design, where the upwind and downwind broadsides have no drag, and the same for the upwind blades, then one can have a viable working design. One also needs to account for the moving cabling system across the 2 (shown) generators, with maximum wind velocity and minimum generator resistance in creating this energy. If instead one is able to have an electromagnetic generator, using magnets stroking a separate wiring and charging system - one has removed any mechanical friction on the wind cabling system. In doing this design (my consulting fee is $1000/hour ...) if you have a complete magnetic cabling system working an entire "0" separate wiring that gets charged, one could have a frictionless system for charging the wire, and the (hopefully) frictionless cabling-and-wind blade system provides the maximum energy creation.
Also one needs to have the proberbial rooster-wind-compass-on-the-barn system, so that an electronic monitoring system knows in what compass direction the wind is coming from. One then needs to alter the wind blades to maximize this company direction, while turning away the other 3/4 portions of the wind blades to be non-wind resistive. So one needs to have an entire wind blade alignment and wind compass direction, and one can then have total 360 degree wind capture mechanism.

I like the idea, full advantage the area of the blade. It will be interesting to see how this “flies” in a storm and how they negate friction in the long cable track.

Yeah, I have so many questions too about this one, including twisting of the airfoil in high winds and their possible contact with the support structure and friction on the track.

To me it looks like something that will be mechanically very fragile and susceptible to failures, too many friction points and moving pieces.

I find that wind very rarely travels the path depicted, I still don’t see how this can be made viable, but it’s some very outside the box type thinking, and I’m glad you shared it.
If you make more videos about this, could you describe how it works? Because the information presented is akin to “free energy generators”, all the “how good it is” but none of the “how it works”.
Also the height of standard wind turbine head is to tap into the wind gradient where higher altitude results in stronger winds available.
Maybe this still sounds rude, but this is my 3rd edit where I tried really hard to be polite and helpful.😂

Bro it has an entire track that slurps up efficiency and requires maintenance instead of a single hub like on a traditional wind turbine. I'd love to be wrong but I don't see a way in hell that this thing is gonna beat current wind-tech.

Low, long solutions like this are needed. They can be put on buildings, along canals, in fallow fields. I really hope this one pans out.

I am absolutely sure that this will come to nothing. But, it could work very well in a tidal current or a river.

Holy cow, this could be something a DIYer could install if this works. Really cool to see this.

11:09 Glad you mentioned this. I was wondering how maintenance would be worthwhile enough with the amount of moving parts open to the weather. Also, I don't understand how it would be easier to find locations for Airloom vs current wind turbines. What are the effects of uneven terrain?

Matt, another one of the big hurdles for these large-scale long-blade wind turbines is airspace. For instance there are none of these large wind turbines in our area because we have Wright-Pat AFB, Dayton International Airport, Wilmington Commercial, and four small regional airports all within 25 miles of each other. This makes for a very large air space that simply cannot accommodate Eiffel Tower tall wind turbines in that same airspace. So yes, these other projects you mentioned would be well suited for this kind of space.
Keep up these videos on products like these and others. Your approach is greatly appreciated.

I question the friction losses of the wind track

it's good to see you being more reserved when it comes to the claims of new energy companies

These look like they could easily be installed on top of existing tall buildings, not just towers.
Even if there are challenges, the economic and NIMBY-resistant nature benefits are huge! I’d say it’s worth looking into any shortcomings and trying to overcome them.

Braaaa! Red-Flag Fault:Unit change; switch from kWh(kilo-Watt-hour) at 3:20 to Watts(not kilo-Watts) at 8:47;
clear indication of "size distortion"(using different units to change impact of numbers and distort comparison)

Visually, I'm really having a hard time wrapping my head around this one. I can't see how the sails don't create resistance against the system on the return trip back around the loop.🤔 But, I look forward to updates... and an in-depth explanation of how it even works.

So now the question is, what is the best possible configuration of a continuous loop that can pick up wind from any angle (or a preferred angle)

Seems like a large footprint. The design certainly has potential. Reminds me of a water wheel on its side.

The one thing, it being in Wyoming, I wonder how snow sticking to the blades and slowing or stopping the system. It will be interesting to see the results.

The idea of a wind generator that can fit in a cargo container is very attractive. Imagine what that could mean for remote islands or other hard-to-reach communities.
That said, let's keep our critical thinking caps on until the research has been done and vetted.

just how can they overcome friction of the track, a big vertical objrct on a horizontal mount is just a nightmare to start up

If this works near advertised, a few places it could be installed would be tall buildings. Also, from the design layout, it has an option of stacking and separate tracks. Perhaps, it could have two or more separate loops stacked catching wind speed at different velocities. I would like to see how this technology adapts and the final outcome.

The other issue for this device is the drag from one side of the loop on the other. We could space normal wind turbines much much closer together if we wanted to merely for space concerns. However it’s not just about space. Blades chop up the air, and make it turbulent. When another blade passes through that turbulent air, the efficiency is lower. A loop design guarantees that there is always turbulent air going across a significant proportion of the blades.

More moving part more friction, I think maintenance will be the falldown.

I always love to see weird things being made to combat the same problem. Someone coming up with the same idea "but better" is not always innovation, but if you can look at it first in confusion; it then has the chance of making a change.

If viable, I feel like these could be put on the top/top floors of some sky scrapers (high up and they often create "wind tunnels" that these could really take advantage of)

My concern would be the use of direct mechanical forces pulling or turning a standard generator. It would make far more sense to have magnets that the “cable” tows along its entire length. As each magnet passes loops of wire a current is then supplied to these loops. The faster the cable moves the closer the loops get to those magnets. Since electricity is produced along the entire length of the loop friction and the wearing down of parts is present but reduced.

Friction, lubrication, dust/sand buildup...sounds like a maintainance nightmare to me. Also I have doubts if the device can easily start by itself, given that the windswails have to drag the chain/rope around while starting. I wouldn't drop a penny on this, but it's nice that someone with infinite money supports them, since he doesn't need to care about the losses and for the 0.001% chance that this somehow works it's a big win for everyone.
Edit: Also the huge space requirement of these is insane. I don't agree with your criticism of wind turbines taking up too much space when they just grow vertically (yeah, I understand that distance to other tall structures increases with larger blades) while this is meant to take up huge ground level space, which in most civilized countries is a valueable ressource.

I'm sure the engineers have though about this... but stress on the track would seem to be the main stress that would need to be dealt with... I notice that the images use a single track... while this is probably a test track, it seems that a dual track system would be more stable, especially in high wind areas... Also high wind areas or even storms could cause failures depending on design...

The fixed orientation to the wind seems limiting (even with blade attack angle adjustment). Wonder if you could stick this system itself on a tower and have it rotate to the best wind angle. Towers can be modular so aren't construction wise as hard as huge turbine blades.

What about wind blimps? A blimp way up on the air with the generator in the middle and the cable that connects it to the ground transports the electricity? Also they stay in the air 24/7

This will definetly work I am and have been a windsurfer for over 25 Years now I can say from just looking at the design it will work, since the sail or wing would flap over and act as an accellarent to the horizontal axsis.
I Love the concept! And I am looking forward to seeing it in action

how would this be better than just a row of vertical wind turbines ?

I still don't understand people disliking seeing wind turbines. They're very nice looking if you ask me.

The friction on the wire rope or track has been the killer for the many bladed approaches, not just because of the power losses but also because the setups destroyed themselves at high wind speeds, that is at least one of the reasons the wire rope style generator looked like the blades were attached so loosely.

I am 50, kitesurfer and in the past windsurfer. I believe that this can work, but with limited directions. 2x half wind is most effective. So 90 degrees directed to the long sides. So good for locations either way local thermal winds that happens during part of the seasons and mostly not during a full year.

All other things being equal: if the blades are recyclable, that's a huge win.

There was a concept I saw a while back, basically wind turbine blades in a massive inflatable blimp like ring. A wire connected it to the ground and transferred the power it generated. Allows it to be raised or lowered to optimal positioning, and much higher than structural turbines. Curious what happened to the concept, or if you have a video on it. (Looked, but didn’t see one.)

On the NIMBY topic: I have my doubts on how quiet a system with 100 rollers on rails can be. NIMBYS (and regulations, at least in Germany) may currently be more concerned with the height of wind turbines as the main factor determining their impact on residential areas (which is currently accurate: the higher a wind turbine is, the further its noise can travel unimpeded and the louder the noise will usually be in the first place).
The company _might_ get the quietness of the rail+rollers system down (at lest initially), and the low height might allow them to _bypass_ current regulations. But it won't be long before the system starts suffering from wear and the noise levels increase (if it _was_ ever lower than a horizontal axis wind turbine in the first place.) And legislation will eventually catch up. The only way how you could really benefit from the low height in terms of the distance that noise travels is if you installed this system in a dip or surrounded by a berm - which runs completely counter to getting out of the way of ground turbulence.

nonsense

If no wind a helium filled delta kite floats 100 ft high.
Wind above 4 mph causes top kite to rise and pull a train of kites up.
Cloth hose connects all train kites so air pressure runs a generator on the ground.
Weight pulls kite train back in when wind is too light.

I am trying the see the mechanics of it. In an oval horizontal track, it looks like the forces would naturally cancel out and prevent rotation. So the foils would need to change their orientation to maximize rotation. There would also need to spokes to turn the gear or else the device would need to have a lot of tension so it wouldn’t slip.
With all of the potential friction involved it is hard to imagine any electricity being generated and the device having a long lifetime.

you can build them around horizontal access turbines.

I think conceptually there are some takeaways to be had. It is similar enough to a ski lift, combine that with a gravity generator and you could possibly have an effective power system.

I could see this being feasible for offshore generation in certain areas. I wonder if using magnets on a dual-rail system to help support the blades would reduce friction and increase stability.

I wouldn’t be surprised if the whole thing falls apart from the vibrations it generates. Getting that to scale up will be pretty difficult.

Hmmm? I'd like to see a small pilot build on top of a skyscraper just to see the power generation results.

Just an idea: if height is a major issue, but you don't want to have to build a brand new base, why not add it to skyscrapers (say an unused floor that is for mechanical stuff anyways) or to radio/cell towers? The latter one especially, as they need a power source anyways. It could add great resiliency to them in the case of natural disasters as a side benefit.

As a fellow (30+ years on the water) windsurfer and engineer, I have some questions:
Rig size? In windsurfing the sail range is 3 to 10 sqm, depending on the wind, to get the same power.
Shape? How will the "sail" swap profile when changing directions? Or are they not used on the way back?
Angle to the wind? I think 90' is the best, but wind is rarely coming from the same direction. Maybe in gorges or something, but those are rare.

It looks interesting. I think a twin track would make it more stable and the use of magnets to levitate the track and reduce friction would also help and reduce noise.

Cable rotation failure is my guess on the number 1 problem. Especially with dust/salt/ice etc. I hope it works!

I wish there was more emphasis on energy storage. Everyone is so interested in clean energy creation but little is said about storage. Electricity is easy to make but that is useless if it is not there when needed. Every solar/wind energy fan I know quickly changes the subject when storage comes up, there is this thought that there is this big storage battery that will solve all the problems.

One thing to consider is land area and multi-use. Traditional turbines are often installed on farmland, causing only the footprint of the tower to be unavailable for farming. For these to be deployed at scale would take significantly more land from whatever other use it might have, be that farming or solar.

The one thing that looks to mostly be missing for this system is sensitivity to wind direction changes. I presume that the plan is to set this up to work with prevailing winds, but even the VAWT systems out there all are set up to point into changing winds in one way or another. I don't see this working for an oval track that's affixed to pole's set in the ground. There may be some reduced sensitivity in some way, but I suspect it makes a difference on performance.

I just drove through Texas and the miles of wind turbines were the ugliest thing I’ve ever seen. Couldn’t wait to get out of there.

Tell them I volunteer to set up and direct some third party testing.

Thanks for the video. I agree. A fair dose of skepticism is reasonable at this point.

I'm curious about ice and snow protection. My understanding is that traditional windmills use electric or air to heat the blades much like an airplane wing. These would presumably not be able to have electrics inside without over complicating things. So how would you protect them from or remove ice after a good winter storm or freezing rain? Never mind that accumulation of material such as snow and ice would be more likely to jam up this type of mechanism.

As soon as I saw it I instantly thought of the 80s clothesline style. I was hanging out laundry and my fiancé who never had a clothesline, asked why not in the dryer? I told him I could have my clothes dryer faster with no electricity if I put it out for 45 minutes. It’s a great warm windy day. Please do a video of other turbines. I’ve been looking for something for two years

I conceptualized this idea 30 years ago. Only my idea was on a larger scale, use railroad tracks and flatbed rail cars with huge semi ridged and retractable sails. It idea could actually be built on barges out on the sea as well.

i wonder if they besides being modular, could also be stackable, if they're as efficient as the claims, then stacking them would save on land use as well.

I think one of the best systems is derived from a gyro-kite acting as a turbine, because it has the potential to tap right into jet-stream winds. However the problems with airborne systems is that it requires restricted airspace and may have location issues with current air traffic routing. If it weren't for that aspect, I'd think that system would be seeing some good traction by now.

I have a feeling this will be an item that looks good on paper but doesn't work in reality. The one factor I see blocking this is the one you touched on a bit. One of the reason turbines are so tall is consistent wind is usually only found at higher altitudes. If I make a super efficient and cheap ground turbine, that's great, but it's not so useful if it only rotates once a day instead of constantly. Only time will tell.

Very interesting. Seems useful when you have lots of space. Totally unclear how stable the blades on the rail are. It may produce electricity at low cost, but unfortunately very little of it.

It's possible that this is a work-around for the blade length problem of maximizing swept area, but I don't see the short towers as a viable path here. You can't get around the lower wind speeds/higher turbulance problems of short towers. I'm also concerned about the potential differential loading of wind shear on the multiple towers involved: those on the leading edge will experience more shear than those on the trailing edge. That's going to cause the track to flex and warp. It's almost certainly a solvable problem, but how expensive will it be to solve? Also, the oval shape feels like magic sauce to me. Even if we assume that there is something to it, it's got to be relative to the direction of the wind. Are they going to rotate the oval with respect to the wind direction? That would be tough to say the least with the tower setup they have.

Several thoughts come to mind. There was no mention of problems with bird strikes or noise levels. Admittedly, it seems too early to know much about either of these two items.
The bigger question for me is, why a loop pattern? Would this not be affected by wind direction. If the wind hits the broad side, the power output would be different than if it hit the narrow end. I could be completely wrong about this. But, if it had a circular pattern, then wind direction should not matter. Correct? And if a circular pattern is better, then you do away with the cable and put the blades on the tips of lightweight arms and basicly build a horizontal ferris wheel. This would put all of the friction back on the central hub.

This is essentially like a squirrel cage fan design but just implemented differently. If you can set it up so the long side faces dominant winds I could see it having an advantage over simply using a round design the same size. Seems like lot of moving parts to worry about though, like the track system etc.

Couple of notes: onshore wind power (and offshore wind power is hot on its heels) is one of the cheapest forms of electricity. You can’t “side step” the issue of height. Wind speed inevitably increases with height and wind power is proportional to the cube of wind speed.
I’d like to see a working prototype at, say 100kW. I think there would be some pretty difficult issues to do with side loading and flapping or instability of blades. Also, I think each installation would have to be made as a bespoke item to take account of rolling ground, trees etc, while you can stick a wind turbine wherever is convenient.

I have decided that you always provide excellent information! 😊

"NIMBY Resistant" can honestly be a mighty claim tbh, it's frustrating that so many people will say they care but only oppose it for just the SAKE of opposing projects like these. Regardless, keen to see all these technology prove their worthiness :D

While unlikely to be a universal solution, such a system (assuming it works as claimed) would be a particularly good fit for specific types of locations such as ridgelines that run perpendicular or nearly so to the prevailing wind direction. The ridge acts like a natural pylon to lift the wind turbine into the faster air at higher altitudes.The ridge also acts as a concentrator that increases the wind velocity close to the ground at the top of the ridge. This would especially benefit the horizontal racetrack configuration where the tops of the blades are not very high. And with it oval shape, a series of this type of wind turbine could form a continuous line along the ridgeline to capture the maximum amount of the higher wind speeds. The benefit of ridgelines is of course already well known, which is why large horizontal axis wind turbines already are popping up like enormous dandelions along just about every suitable ridgeline.
But there is considerable resistance to placing these highly visible and to some very ugly large wind turbines on top of ridgelines, which to the detractors only serves to make them visible from even further away. This is especially the case in place with more "natural beauty". The low height of AirLoom wind turbine would mean it is less visible along the ridge. And straight and lightly loaded blades of the AirLoom turbine makes them less susteptible to thermal effects (warping, cracking, delaminations) than highly loaded blades of horizontal axis wind turbines and thus are not likely to have to be painted white to control solar heating. And because they are shorter they don't have to be painted white to increase their visibility to aircraft pilots. Thus they could basically be painted in a "camo" pattern to blend into their surroundings.
As for offshore installations, even relatively large Airloom installations won't have to be too far offshore before they disappear over the horizon due to the curvature of the earth. From the second story of a house on the beach (20 ft above sea level), a 100 ft tall Airloom wind turbine located 18 miles off-shore would be completely below the horizon while a 200 foot tall version would need to be 23 miles offshore before it disappeared. This compares to the 41 miles off shore an 850 ft tall (to the tip of the rotor) GE Haliade-X would have to be located before it would disappear below the horizon.
And one last potential benefit is that the lower speed of the blades along the track as compared to the high tip speed of a large HAWT means that should be easier for birds to see and bats to echo locate and thus avoid colliding with them.
I, like you, am very skeptical until hard data from independent sources is available. But it does break the mold on the monopoly of single axis wind turbine (either horizontal or vertical). And so this one goes on my watch list.

I love innovations because that's how we get to the really good ideas. Of course, that also means that we go through a lot of ideas that just don't deliver. What we need is real data.

Good afternoon Matt this is brilliant, this system can be installed on skyscrapers in cities on the top floors maybe 1 to 2 systems deployed on each skyscraper the city’s in all countries could produce mega watts of power. I love this idea.

Damnit, my invention once again. Seemed many were working on it

My concept was to basically have a wire grid with lots of fans fixed onto it. No single point of failure, but a lot more electrics needed to add up the voltages together. Hopefully funnel the wind in with well planted conifers. As others have mentioned something like this gets much more cost effective with efficient funneling, so slow wind speeds are boosted. i.e. work on increasing the wind capture area, but it needs people who understand aerodynamics, and can rapid prototype using a wind tunnel, which isn't exactly cheap. Computer modelling sounds great but far too easy to waste time, just looking busy.

Several sailboats, connected to two horizontal wheels, being attached to a loop of cable, could sail around this, " Track," turning the wheels connected to a generator. One wheel would be on land, the other fixed in the sea. The wind would need to prevail on the long run. They could automatically self-tack.

If the blades are not performing in both directions, too much energy will be lost to bring them back. On the contrary, if the blades are performing in both directions you cannot choose an efficient airfoil. It wil have to be symmetrical and will need complex gimbal control. Furthermore, many wings mean many wingtips and therefore energy loss due to tip turbulence. Also, the wings downwind perform in the windshadow of upwind wings. Also, the structure cannot turn with changing wind direction. Also, high friction. It is a complete waste of time.

Disappointing that there was not even a simple description of how the system works. I assume the track is perpendicular to the prevailing wind and the airfoils can be rotated to make them efficient in both directions. No mention of the impact of wind coming from other directions. Should’ve supplied more information about the basic concept.

In principle just a vertical axis windturbine, with the central axis replaced by a rail system. The thing is: modern windturbines are on high towers for a reason. The higher up you are the stronger the winds, and sinds the power in the wind depends on the cubed windspeed, it is hard to see how such a system so near to ground can compete with regular wind turbines.

Absolutely, moving the parts of a HAWT are troublesome because of their sheer size. While driving cross country I was once stuck for an hour behind a single blade on the back of a semi trying to negotiate a sharp turn. Then of course once they reach end of life and have to be dissembled what to do with the parts becomes an issue.

I wrote them a message several days ago with a few questions. Unfortunately, they did not even acknowledge the message, let alone send a reply:
1. Whether you are ready to undertake a pilot project of a 20 MW plant or turnkey contracts for several 20 MW plants in various locations in a developing country in Asia. If yes, what will be the approximate all-inclusive cost per MW?
2. What the typical time period is from site handover to commissioning and what the prerequisites are for you to commence work on the site? You may also include here your requirements regarding site conditions.
3. What the operable wind speeds are and whether there are any problems associated with extremely high wind speeds.
4. If you have the provision to train the key people who will finally operate the plant after commissioning. Please provide the details of such training in terms of duration; location; cost; training content; certifications, if any; and the candidate education and background.
You can decide whether it's just hype or not.

Those who believe green energy and carbon taxes are critical should come up with scientific methods to track the carbon footprint of artificial intelligence, cloud computing and virtual currencies.
Bill Gates should be the perfect person to lead this position, as he is a major owner of Microsoft Azure and artificial intelligence development, as well as a large amount of farmland.