Ah, hacker news, from “ No, absolutely not.” to already being done in 3 comments.

To be fair, first operational in 2019. Variable speed cooling fans, for heat loss regulation, are bleeding edge tech, in the world of aluminum.

I just wish people would be more open minded and curious by default.

They only are if they're incentivized: most ignore the rewards, those you admire who don't ignore self-motivated open-minded-ness and curious-ness, they must have already been rewarded previously for having these traits, and so they continue to express them.

Here are some pdfs:

How it works: https://enpot.com/assets/pdfs/enpot-how-it-works.pdf

Energy modulation: https://enpot.com/assets/pdfs/Enpot-Energy-Modulation-of-Alu...

First was operational since 2019. If you push past the “virtual battery” marketing nonsense, a summary of the tech is… they modulate the cooling fans for closed loop thermal regulation, regardless of processing rate (+/- 20% long, 30% short term).

Talk about low hanging fruit.

This is particularly interesting to me because we currently have some unanswered questions about how viable renewable energy is for ~100% of generation.

As we get to higher total renewable contribution, presumably we’d see a more dramatic price difference in energy at different time of day.

This tech suggests to me that, as you say, there is low-hanging fruit that could be harvested, and which perhaps isn’t cost-effective yet with a small diurnal energy cost-delta, but with a higher peak-to-trough cost difference might become viable to extract.

It’s worth noting here that seasonal variations seem harder to deal with, and varying the energy intensity of industrial processes doesn’t seem helpful for that issue due to capex/utilization concerns.

And for diurnal fluctuations, batteries are actually not too expensive these days.

Interesting, thanks!

> The “virtual battery” concept relies on installing adjustable heat exchangers that can maintain the energy balance in each electrolysis cell irrespective of shifting power inputs. Since aluminium production requires a constant energy supply, any fluctuation could have heavy consequences for the molten metal. The technology also ensures that grid power fluctuations do not affect the magnetic fields in the electrolysis cells.

This seems to be solving the even-harder problem of handling on-demand/dynamic fluctuations rather than planning for a diurnal cycle. I wonder if there is scope to use a heat reservoir (molten salt or similar) as a buffer for these sorts of process; basically if you need to dump heat into a process perhaps you can shift the heat production but leave the process itself unchanged.

Amusingly I was reading the wrong Wikipedia last night and it’s mentioned right there too:

> Particularly in Australia these smelters are used to control electrical network demand, and as a result power is supplied to the smelter at a very low price. However power must not be interrupted for more than 4–5 hours, since the pots have to be repaired at significant cost if the liquid metal solidifies.

https://en.m.wikipedia.org/wiki/Aluminium_smelting