[Earw0rm]

Ugh, turns out I suck at math too. At least attempting it before coffee.

The ship's capacity in MWh is 18620t x 33MWh/t = 614460MWh.

At 45MW generating capacity, an electric hydrolyser at 80% efficiency delivers hydrogen at a rate of 36MW. That will unfortunately take about 70 years to fill the ship to its maximum capacity.

On a more positive note, 36MW is still a heck of a lot of power, plenty enough to run a mid-sized cruise liner or warship. So a marine generating station with three of these turbines could, for example, refuel a liner once a month, and then that liner have enough fuel to cruise for a month, and so on.

This would require a fuel tank with a more reasonable 750 tonne capacity. That's still several times more than the Shuttle, but not beyond the realms of feasibility - and a stronger, heavier tank allows higher pressures / smaller volumes.

[ccozan]

I am totally mesmerized by the idea of a floating hydrolizing platform , where ships can dock and load hydrogen fuel ( not sure what form suits best ).

Must start some economics of it. Also marine environment is very unforgiving...

[usrusr]

Platforms are does-not-scale hard though: they require mooring and every bit of ocean floor is different. Drilling platforms come in multiple "species", as different as spiders, fish and birds. Roaming hydrolysers on the other hand would be one design fits any ocean. You'd want to build lots of them, more Model T than Death Star. And where a stationary platform would have to be able to brace a hurricane, the roaming unit would just go to a neighboring sea with a friendlier forecast. Or ride along on the edge, if power throughput has enough headroom.

[Earw0rm]

It is. But if we can handle maritime oil and gas rigs, which load/unload to tankers, hydrogen isn't MUCH worse.

It wouldn't be floating exactly though. Moored and piled into the sea bed, sitting above the waves like rigs and wind turbines.