TIL the cost of transporting energy around

Submitted ⁨⁨12⁩ ⁨hours⁩ ago⁩ by ⁨gandalf_der_12te@feddit.org⁩ to ⁨energy@slrpnk.net⁩

https://feddit.org/pictrs/image/889b8241-bdbf-4427-ace4-475503058b28.png

so the goal is to transport renewable energy from the point of production (e.g. coastline for offshore wind) to the point of consumption (e.g. big factory 300 miles from the coast).

what is the cost of doing this? when comparing different technologies. i.e. you can just build a cable and transport the electricity through that, or you convert the energy into hydrogen at the point of production, then pipe that hydrogen gas through a pipeline to the point of consumption. many big consumers can naturally consume hydrogen instead of electric power anyways, for example large steel mills. they require power for heating and reduction, but in both cases, both power sources can be used (for reduction, electrolysis vs. chemical reduction).

it’s well-known that the LCOE (levelized cost of electricity) for solar and wind is around 6 ct/kWh (citation needed, i’m citing from memory). so what is the cost of transporting that electric power over 300 miles? according to the diagram, it’s 4 ct/kWh over 1000 miles, so probably 1.33 ct/kWh over 300 miles using wires. so it makes a small part of the cost.

meanwhile if you use hydrogen, you have around a 70% conversion+storage efficiency (electric power -> hydrogen, plus storing it in an underground cavern) (source: this paper and german wikipedia about hydrogen storage). so to produce 1 kWh hydrogen, you need 1.4 kWh electricity at the cost of 1.4 * 6 ct/kWh = 8.4 ct/kWh. transmitting it over the pipeline, meanwhile, costs almost nothing, as seen in the diagram.

so in summary, producing+storing+transmitting hydrogen is slightly more expensive than just producing+transmitting electric power, but that already includes the storage cost. for electric power, you need additional batteries which i’m too lazy to write about now. just to give you an idea.

source

Comments

Sort:hotnew top

absGeekNZ@lemmy.nz ⁨4⁩ ⁨hours⁩ ago
I don’t get why materials for HVDC are so much higher than everything else. Towers and cables are relatively cheap, the substation hardware is not, but neither are pumping stations with all of the safety requirements.

Also why only 500kV when there are 1.2MV systems in the world. Not that it would make much difference since the bulk of the cost is down to materials.

I didn’t see the amortisation time in my quick skim through.

I know in NZ the compliance cost to get a pipeline through would kill any project that tried to do this.

Obviously leaks etc are ignored in this model, but they at a significant contributor to climate change.

source
sj_zero ⁨10⁩ ⁨hours⁩ ago federation: posted
I really like this post, it gets down to nitty gritty brass tacks and brings some data.

That's usually the thing that gets me grumpy about such conversations, people don't bother discussing the realities of actually doing the thing, they just trade feel good articles about how everything is fine.

One thing about the paper is, the cost of high voltage DC lines is likely assuming you're on land. Bringing the energy in from sea could be even more expensive, since you need much more expensive equipment, the environment is brutal, repairs involve sending people and material into that environment, and I have a feeling but I don't know, I think that the movement of the offshore wind turbines could be mechanically stressful on cables that are relatively safe up in the air only dealing with wind (and they still can cut right through insulators swinging in the wind and vibrating at 60hz)
JacobCoffinWrites@slrpnk.net ⁨10⁩ ⁨hours⁩ ago
Am I missing something? Isn’t this why we use AC power over long distances?

source
- dariusj18@lemmy.world ⁨10⁩ ⁨hours⁩ ago
  No, DC is for long distances
  
  source
  - JacobCoffinWrites@slrpnk.net ⁨10⁩ ⁨hours⁩ ago
    Yeah I started reading up on it more once I got thinking about it. Looks like AC was easier in the past, which is probably why we’re standardized on it for local grids
    
    source
    -> View More Comments
AllNewTypeFace@leminal.space ⁨11⁩ ⁨hours⁩ ago
Which is another good argument for decentralising generation; lots of small- to medium-scale renewable generators distributed around the area in which power is consumed would require less transmission than a few huge generators (especially if they’re things people would rather not live near, like coal turbines or nuclear plants).

source
lemmysmash@piefed.social ⁨11⁩ ⁨hours⁩ ago
What about Uranium? How expensive is that?

source
- Allero@lemmy.today ⁨1⁩ ⁨hour⁩ ago
  We talk energy transmission here. And it’s not that small-scale reactors are so common, cheap and safe that we can use uranium on the spot.
  
  source
andrewrgross@slrpnk.net ⁨11⁩ ⁨hours⁩ ago
Why is DC power so much more expensive than pipelines?

source
- Nomecks@lemmy.ca ⁨10⁩ ⁨hours⁩ ago
  Because DC is produced electricity, and it takes burning around 10x the joules or more of hydrocarbons to match that power
  
  source
- sparkyshocks@lemmy.zip ⁨10⁩ ⁨hours⁩ ago
  Pipelines are absurdly efficient because moving liquid or gas through a pipe is absurdly efficient per kilogram per kilometer, and the energy density of fossil fuels is absurdly high.
  
  A Tesla supercharger v4 can deliver 500 kW of power. BYD has launched chargers that can deliver 1000 kW (aka 1 MW) to a single car. Naturally, each kW of power is capable of delivering 1 kWh per hour.
  
  What is the equivalent flow rate in gasoline? 1 gallon of gasoline contains the equivalent of 33.4 kWh (1 L contains 9 kWh). So 1000 kW would be the equivalent of 30 gallons per hour (110 L/hr), or 0.5 gallons (1.85 L) per minute. That’s 5% of the rate of a typical gasoline pump in the United States.
  
  Plus exposed high voltage wires need to be maintained in weather and around vegetation, so they have high operating costs. Then there’s higher capital costs of making sure that there are transformers and safety equipment that step the voltage up and down and sync with the rest of the grid.
  
  In the end, it really is that power lines aren’t capable of carrying nearly as much energy as the chemical fuels that flow through a pipe, so on a per joule/kwh basis, there’s less economy of scale from power lines.
  
  source
  - Tobberone@feddit.nu ⁨4⁩ ⁨hours⁩ ago
    I would think that the graph would be rather different had it been “last kilometer”? I’d expect to see electricity at the bottom there.
    
    source
    -> View More Comments
  - andrewrgross@slrpnk.net ⁨8⁩ ⁨hours⁩ ago
    Wow, that’s a lot of food for thought.
    
    source
    -> View More Comments
- brucethemoose@lemmy.world ⁨11⁩ ⁨hours⁩ ago
  Power transmission is hard.
  
  The wire, the complex components, keeping it all in phase and steady and not exploding, the maintenance…
  
  I cannot emphasize this enough. People tend to trivialize this when talking about remote production, but moving electricity long-distance is basically the hardest part. And pipes really are dead-simple in comparison.
  
  It’s also why local production is so appealing.
  
  source
  - andrewrgross@slrpnk.net ⁨11⁩ ⁨hours⁩ ago
    I was aware conceptually that it’s really complicated, but where are the costs going? Is this due to labor costs? Material costs? something else? What makes it so expensive to build and to operate, especially compared to pipelines.
    
    source
    -> View More Comments
DarrinBrunner@lemmy.world ⁨11⁩ ⁨hours⁩ ago
You know what costs even more? Burning fossil fuels. I suspect this little bar graph doesn’t take into account those costs.

source
spinne@sh.itjust.works ⁨11⁩ ⁨hours⁩ ago
what is going on with those error bars

source
- Allero@lemmy.today ⁨58⁩ ⁨minutes⁩ ago
  Wildly depends on location, I reckon
  
  source