Europe’s First Hydrogen Fuel Cell Sea-Going Ferry Is Powered by Renewable Energy(autoevolution.com)
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Europe’s First Hydrogen Fuel Cell Sea-Going Ferry Is Powered by Renewable Energy
https://www.autoevolution.com/news/europes-first-hydrogen-fuel-cell-sea-going-ferry-is-powered-purely-by-renewable-energy-172235.html
34 comments
I agree with what you're saying - hydrogen propulsion will make the most difference for large fleets over long distances. Right now, in the pacific northwest BC Ferries and Washington State ferries are moving to electrify their fleets. The crossing distances of these boats are much larger (The most popular BC ferries route looking to be more than 20x longer). As I recall, the procurement process for these much larger boats that go much further distances didn't include all battery (because the weight/space would have been prohibitive) or hydrogen electric (because the technology is too immature).
I don't think it's reasonable to be experimenting with new technologies on 200 car ferries so even if hydrogen is not the ideal use case for this crossing, I'm excited to see this technology build a track record so it becomes a more feasible option for the large scale where it does make sense.
I don't think it's reasonable to be experimenting with new technologies on 200 car ferries so even if hydrogen is not the ideal use case for this crossing, I'm excited to see this technology build a track record so it becomes a more feasible option for the large scale where it does make sense.
Less efficient, but when the energy is used, the weight is gone. And that turns out to be important for efficiency.
What I'm curious about his how long will they last in that harsh salty environment?
What I'm curious about his how long will they last in that harsh salty environment?
Sure, aircraft work with this a lot (some can't even safely land with full fuel load) but I wonder how important this is for boats ?
Also for boats you need to account for shifting center of mass as the fuel gets used up, which is not an issue with batteries.
Also for boats you need to account for shifting center of mass as the fuel gets used up, which is not an issue with batteries.
I don't understand this thinking at all. Hydrogen itself doesn't weigh much but the containment does. The actual change in mass due to hydrogen being used up should be <1% of the ship mass. This is entirely unlike aircraft.
From my reading of the article I think the ferry is intended to service inter-island hops on Orkney where a 200 car ferry would be overkill.
Also as the article reports, Orkney has an idiotically huge amount of renewable power available, far more than the islands can consume, and far more than the interconnect from Orkney to mainland Scotland can handle. So using it to create hydrogen seems like a fair use of that surplus power.
Also as the article reports, Orkney has an idiotically huge amount of renewable power available, far more than the islands can consume, and far more than the interconnect from Orkney to mainland Scotland can handle. So using it to create hydrogen seems like a fair use of that surplus power.
got to remember small ferries do not have long stops to top off batteries. river crossing ferries night only load 4 cars in 2 minutes and then swap sides
What are the refule time comparisons?
"Thanks to the local process of obtaining hydrogen, using only excess wind power, this will be the first European ferry powered entirely by renewable energy. Both the production process for hydrogen and its use as fuel don’t emit any toxic by-products."
Intriguing, since hydrogen production is almost universally a byproduct of fossil fuel production. Not a ton of information here...
I did a little digging, and indeed this project is using electrolysis powered by wind / tidal energy projects on a small Scottish archipelago named Orkney. They produce 130% of the power they consume, so they turn the remainder into H. Smart.
Here's a really interesting article with lots of details: https://www.bbc.com/future/article/20190327-the-tiny-islands...
Intriguing, since hydrogen production is almost universally a byproduct of fossil fuel production. Not a ton of information here...
I did a little digging, and indeed this project is using electrolysis powered by wind / tidal energy projects on a small Scottish archipelago named Orkney. They produce 130% of the power they consume, so they turn the remainder into H. Smart.
Here's a really interesting article with lots of details: https://www.bbc.com/future/article/20190327-the-tiny-islands...
Hydrogen seems like a really interesting potential solution to the renewable storage problem. I've done a bit of research in the past and seen that there are some early stage projects investigating this, but I'd be curious to hear from anyone who might know more.
It’s not really that advantageous for energy storage. The round trip energy efficiency is less than 50% so half of any stored energy is wasted.
Perhaps surprisingly, the round-trip efficiency of an energy storage medium becomes relatively unimportant when the top-line cost of production gets low enough. Other costs come to dominate.
The odds-on favorite for utility-scale battery storage is iron-air batteries. Nobody even mentions the round-trip efficiency of those, so it must be pretty awful. But they are darned cheap. We can expect solar, in particular, to be routinely massively over-provisioned, so that much of the time most of the output would otherwise be wasted if not used opportunistically to charge batteries or hydrolyze water to synthesize H2 or NH3.
The odds-on favorite for utility-scale battery storage is iron-air batteries. Nobody even mentions the round-trip efficiency of those, so it must be pretty awful. But they are darned cheap. We can expect solar, in particular, to be routinely massively over-provisioned, so that much of the time most of the output would otherwise be wasted if not used opportunistically to charge batteries or hydrolyze water to synthesize H2 or NH3.
Iron-air batteries are literally just fuel cells that involve iron instead of hydrogen. THe odds on favorite is hydrogen fuel cells and it probably can’t be anything else (short of some kind of nuclear solution).
You keep saying so, but what I am seeing is serious plans for iron, and synthesizing NH3 as portable fuel, but very little activity on H2. Is there actually any current work on industrial-scale H2 synthesis for storage, as opposed to for use in e.g. steel production or fuel?
It should be noted that using hydrogen for steel or fuel production lead almost directly leads to some kind of hydrogen storage. If you can make that much hydrogen, it just becomes a natural step to use it as a energy storage system.
Also, the scale of hydrogen storage facilities far exceeds anything else ever proposed: https://www.pv-magazine-australia.com/2021/10/23/weekend-rea...
It's clear that obsessing over the last step is unnecessary. As soon as you have the hydrogen available, there will be many obvious solutions available.
Also, the scale of hydrogen storage facilities far exceeds anything else ever proposed: https://www.pv-magazine-australia.com/2021/10/23/weekend-rea...
It's clear that obsessing over the last step is unnecessary. As soon as you have the hydrogen available, there will be many obvious solutions available.
I don't doubt that, once hydrogen becomes heavily used as a fuel--exclusively for aviation, I expect--it will then also become useful, secondarily, as a storage medium for utility power. But the first condition is barely even in planning stages, if there. By the time hydrogen as bulk fuel does happen, other storage for utility power will be very mature, and hydrogen will need really compelling advantages to be able to compete in places where it is not already being stored as aviation fuel.
The cited article points out that utility-grade storage in salt caverns is still a wholly hypothetical possibility, and speculates on problems that might yet render it impractical.
The cited article points out that utility-grade storage in salt caverns is still a wholly hypothetical possibility, and speculates on problems that might yet render it impractical.
It's advantage is that fact that it stores multiple orders of magnitude more energy than anything else, at a cost level that is orders of magnitude cheaper too. It's a matter of when, not if, hydrogen becomes the primary energy storage mechanism.
Storing hydrogen underground has existed for decades. It's already been accepted by people in the industry that this is a solved problem.
Storing hydrogen underground has existed for decades. It's already been accepted by people in the industry that this is a solved problem.
Yet, the article you cited yourself says the opposite: that it needs study to determine its practicality.
I don't doubt that whatever problems turn up will be solved, in time. Underground storage of liquified hydrogen, rather than gas under high pressure, seems like a great idea, since earth is such a good insulator, but they don't seem to be talking much about LH2.
The methods used to oxidize H2 seem to produce a great amount of waste heat. If you have uses for the heat, that may be not so bad. But producing power from stored H2 at GW rates would produce more heat than is easily used on the same schedule as the power is demanded. The heat could also be banked underground, maybe, but there remains the problem of delivering it where it is actually needed.
I don't doubt that whatever problems turn up will be solved, in time. Underground storage of liquified hydrogen, rather than gas under high pressure, seems like a great idea, since earth is such a good insulator, but they don't seem to be talking much about LH2.
The methods used to oxidize H2 seem to produce a great amount of waste heat. If you have uses for the heat, that may be not so bad. But producing power from stored H2 at GW rates would produce more heat than is easily used on the same schedule as the power is demanded. The heat could also be banked underground, maybe, but there remains the problem of delivering it where it is actually needed.
I don't think you are even trying to read what they are saying. All they're testing is how well the hydrogen will stay underground and how tight the seal is for all of the various formations. We already know it works.
The only GW-scale H2 storage I find is the project in Utah, which starting 2025 and for the foreseeable future will be used to augment CH4 combustion to drive turbines.
I Googled around for this some time ago and found quite a few grid-storage projects in the US and Europe (both public and private), but I don’t have links handy at the moment. They all seem to be pretty early-days IIRC. But yes, mostly you have to sift through a lot of results related to transportation fuel cells.
If that energy would otherwise be wasted (because of an excess of supply in the market) then perhaps the efficiency doesn't matter so much.
It always struck me that 50% efficiency is better than 0%.
> Orkney’s excess renewable energy could be used to produce hydrogen, which would then be stored under pressure and used to power local transport, such as a ferry fleet.
Maybe not actually powered by renewable energy but potentially so.
Maybe not actually powered by renewable energy but potentially so.
Orkney is known to have an abundance of community wind energy, which they are unable to export to Scotland due to cable capacity limitations.
They're experimenting with H2 generation instead.
They're experimenting with H2 generation instead.
There will be good reasons to produce NH3, as well. But that also needs H2.
H2 is not a super-great long-term storage medium. NH3 is a good choice to use to fuel retrofitted transport shipping (which would just need new tankage and plumbing, not new engines) and to drive generators in places where solar is not practical much of the time, such as north of 55 degrees latitude.
H2 is not a super-great long-term storage medium. NH3 is a good choice to use to fuel retrofitted transport shipping (which would just need new tankage and plumbing, not new engines) and to drive generators in places where solar is not practical much of the time, such as north of 55 degrees latitude.
NH3 = Ammonia.
I wonder why they don't experiment with a bigger cable...
Are grid interconnectors much more capital intensive or higher maintenance than Hydrogen generating plants? (Genuine question - I have no idea of the relative costs here)
Are grid interconnectors much more capital intensive or higher maintenance than Hydrogen generating plants? (Genuine question - I have no idea of the relative costs here)
I heard that hydrogen, in the form of Ammonia, is the Next Big Thing for shipping, which is nice because those container ships are pretty nasty.
https://spectrum.ieee.org/why-the-shipping-industry-is-betti...
https://spectrum.ieee.org/why-the-shipping-industry-is-betti...
Does anyone have any good numbers on the efficiency of hydrogen fuel cells vs batteries? Naively, I would expect that it would be lighter to "store" electricity by electrolysizing water and storing the hydrogen, then running the hydrogen through a fuel cell.
Transport & Environment have done some studies - https://insideevs.com/news/332584/efficiency-compared-batter...
Turns out battery charging and inverting has lower losses than electrolysis and compression.
Turns out battery charging and inverting has lower losses than electrolysis and compression.
love this one. We are making great steps towards a cleaner future
I love this. It's democratising fuel production, which is important step towards redistribution of wealth around the world. Anyone who can tap into cheap renewable energy source can make a profit.
Hydrogen is a less efficient way of using renewable energy than using electricity directly via batteries. The only reason to use it in shipping is that for larger ships and larger distances batteries are not feasible.
DFDS is planning to convert a large ferry between copenhagen and Oslo to hydrogen: https://www.dfds.com/en/about/media/news/hydrogen-ferry-for-...
That's the kind of project where hydrogen makes sense.