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It's a pretty solarpunk fact that small, distributed wind turbines use steel more efficiently than big centralised ones
(solar.lowtechmagazine.com)
everything about energy production
They use steel more effectively, but use other resources like wind, land, labor, and electronics less effectively, and all of which are harder to recycle. It also didn’t mention household or village scale as much as was still comparing very large grid scale systems, which is important as once you get much smaller than that energy efficiency falls off a cliff.
Finally, while a detailed look into a specific resource can be very interesting, it’s important to take a holistic look at how energy sources compare and not just evaluate on one figure.
Ultimately, as our ability to manufacture steel is not currently a major constraint to decarbonization, more important limitations like installation and maintenance costs are going to be dominant at least for the next few decades. Similarly as the low hanging fruit like electricity generation make up less and less of our collective GHG emissions, we’ll have more resources like plentiful wind energy to throw at problems like decarbonizing steel, as its still a problem will have to solve sooner or later.
Wind is a renewable resource. Saying wind is not easy to recycle is incoherent.
Electronics is the only one of the four you mentioned where recycling is a relevant concept.
As for wind farms being an effective use of land, that's just obviously wrong. You can't even have livestock near them.
As for less labour-efficient, I'd've thought that's part of solarpunk: being less capital-intensive/more labour-intensive.
Precisely, good stable wind blowing when we need power is not something we have an unlimited amount of, like times we can recycle steel. The steel in todays wind turbine is the steel in a thousand years from now’s turbine, where as the co2 that got pumped into the atmosphere because that turbine wasn’t enough is also the co2 killing people in a thousand years. The higher you get a turbine above the ground, the less turbulence it will see, and the more constantly it will be in the right range to generate power.
The more you can count on it, the less battery and hydro you need to cover when the winds not blowing, and thusly the less space and turbines you need.
As for labor efficiency, i’ve always though of the goal of solarpunk to be a world where we’ve settled out into a way of life that can be maintained long term and where people are free to do what they want and help out where they can instead of worrying about if they’ll earn enough from the megacorp to have heat and food next month.
While you still need someone to do dangerous and unpleasant things like climbing turbines, ideally you’re only asking as few people as possible to do so as you need.
And given that even in that future people will still be paying the price in lives for the GHGs we emit today, we owe it to them and possibly us if we live long enough to shrink the river of co2 we’re putting out as fast as we can, as every fossil plant that is replaced by clean energy today is decades of that’s plants cost gone.
FYI making steel emits carbon: kinda the main point of the article.
No shit, in a fossilized economy everything emits carbon, and low co2 new steel production is still in its infancy. Nevertheless it emits far, far less carbon than running a natural gas plant for the same power, and as the article points out, can and is continually reused forever with no new carbon emissions beyond that of the enegy used to transport the material and power the arc furnace.
The startup cost in carbon just means there is a delay in between when a turbine is built, and when it is produceing zero carbon energy. Studies show that even the most steel intensive offshore turbines repay this debt in under a year, and again, this is why we need to be getting as much wind energy online as soon as possible.
If going to a smaller turbine design means that you save four months worth of startup carbon, but means a wind farm only captures two thirds as much wind energy over its three hundred month design lifespan then going with the smaller design will have effectively cost nearly a hundred months worth of output to save four. While that two thirds number is going to very by project constraints, the reduction doesn’t need to be very large to work out to a net carbon savings, even if you couldn’t recycle steel at all.
As things like available project land, projected ongoing maintenance budget, and most often capital availabllity ultimately constrain a given projects size and net generating capacity, it makes sense to go for the larger turbines that more efficiently make use of these limited resources, instead of the practically unlimited in this context supply of steel.
In short, optimizing for steel use is effectively producing kilotons of ongoing co2 emissions to save tons of co2 once.