![]() What will happen in this case is that on the next tick oxygen (~888 g) will be generated and since it is a much larger mass the existing hydrogen will be deleted and replaced. The tiles left, right and down are all full of liquids, and the tile above is blocked with a solid tile. The hydrogen (~112 g) is now trapped and can't move anywhere. But the real magic happens when you block the location immediately above with another tile. This cycle will repeat, creating a mix of hydrogen and oxygen in the open space above. The gas would then diffuse upwards, allowing the liquid to move back into place. The important thing to know is that it always generates gas in the upper left-hand tile, and it alternates between generating hydrogen and oxygen.With the above design the gas being generated would push aside the liquid in the upper left-hand tile, forcing it to merge with the identical liquid either to the left or the right. Yeah that's definitely not going to catch on, so I guess we'll just stick to calling it a SPOM :) I thought it'd be fun to make up a new name for such an electrolyzer-based power plant, so I came up with Hydroelectric Oxygen Producing Power Plant or HOP3 ("hope"). For that reason I expect this SPOM to be plugged directly onto your main power spine, and I wired the internals with heavy watt wire. As long as you can supply enough water (1kg/s per module, 5kg/s for a full stack) the stack could produce 3-4 kW of excess power. The submerged electrolyzer mechanic supports an entirely different concept where your electrolyzers can be a major power producer for your colony. This ensures that in times of intermittent power issues the electrolyzer wouldn't be interrupted, or even worse run out of stored hydrogen, lose power completely, and need a jumpstart from a hamster wheel. ![]() For that reason I always built my SPOMs on their own electrical network, isolated from my main grid. Typical SPOMs just barely power themselves, and have next to no power leftover to feed into the rest of your colony. Speaking of power output, it hardly seems right to call this design a SPOM. Finally, the entire stack can optionally be turned into a power plant to increase power output. Pumps can be added to either the hydrogen or oxygen side as needed. Additional modules, up to a stack of 5, can be constructed below the first to increase the total oxygen output. A hydrogen generator can optionally be put in the hydrogen side, creating a Self-Powered Oxygen Machine or SPOM. One side of the "v" will fill with hydrogen and the other with oxygen. The design consists of a series of modules, each one containing a small "v" shaped cavity with a submerged electrolyzer. I won't judge either way anyone's single-player game experience, but at least now I'll have a guide available for both groups of players. That combination of perks makes conventional electrolyzer designs obsolete, unless you happen to consider submerged vents and infinite gas storage an exploit of unintended game mechanics. With one small exception, discussed later, you get "fail safe" operation for free.Because of the above, you also get "infinite storage" of both H2 and O2 for free.They will never over-pressurize, so you get 100% uptime / efficiency for free.There is neither a power cost nor a "mechanical filter" required.They exploit a game engine quirk to automatically filter hydrogen from oxygen for free.Nowadays submerged electrolyzers are the rage, and they have some distinct advantages over conventional designs: My previous guide set out to solve that issue, but in the year-plus since then the ONI meta has changed. Both designs served me well, but I always ran into (self-inflicted) issues when my water supply would get cut, or an output pipe would back up, and the whole electolyzer system would start mixing gasses, potentially even needing to be opened up, vacuumed and re-primed. I later discovered the Kharnath design in the Amazing Compendium here on Steam. Like many of you my first couple colonies used a "Rodriguez" design, popularized by Francis John. The design in that guide had a singular purpose, to ensure that H2 and O2 gasses would never mix in the output pipes from the electrolyzer. Some of you may be familiar with my original guide on Fail-Safe Electrolyzers.
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