this post was submitted on 04 Sep 2023
323 points (93.1% liked)
Asklemmy
43870 readers
1990 users here now
A loosely moderated place to ask open-ended questions
If your post meets the following criteria, it's welcome here!
- Open-ended question
- Not offensive: at this point, we do not have the bandwidth to moderate overtly political discussions. Assume best intent and be excellent to each other.
- Not regarding using or support for Lemmy: context, see the list of support communities and tools for finding communities below
- Not ad nauseam inducing: please make sure it is a question that would be new to most members
- An actual topic of discussion
Looking for support?
Looking for a community?
- Lemmyverse: community search
- sub.rehab: maps old subreddits to fediverse options, marks official as such
- [email protected]: a community for finding communities
~Icon~ ~by~ ~@Double_[email protected]~
founded 5 years ago
MODERATORS
you are viewing a single comment's thread
view the rest of the comments
view the rest of the comments
Storage. Coal, natural gas, and nuclear generate power regardless of weather, day and night.
Solar generates plenty of electricity (with enough panels installed), but it slows down significantly under cloudy skies and stops entirely at night.
Wind generates plenty as well…unless the wind stops blowing.
The grid needs power all the time, not just when it’s sunny and windy. For renewables to actually compete, the excess power they generate during sunny and windy times needs to be stored for use when it’s dark and still.
As much as we applaud lithium batteries, our energy storage technologies are abysmally inefficient. We’re nowhere near being able to store and discharge grid-scale power the way we’d need to for full adoption of renewables. The very best we can do today (and I wish I were kidding) is pump water up a hill, then use hydroelectric generators as it flows back down. Our energy storage tech is literally in the Stone Age.
Don't underestimate the battery potential of gravity!
According to https://en.m.wikipedia.org/wiki/Pumped-storage_hydroelectricity#:~:text=The%20round%2Dtrip%20energy%20efficiency,sources%20claiming%20up%20to%2087%25. The round-trip efficiency of pumped storage is 70-80%, that's pretty darn good for cheap mass-storage. There's not much more to gain there.
Pumped water is about the only practical gravity battery, but it has limitations.
So it's great stuff, but I don't think it's going to be the backbone of any storage solution we have.
It works very well, not disputing that.
But, like geothermal power generation (which is also very good), it’s extremely dependent on location. Most populated areas don’t have the altitude differential (steep hills) and/or water supply to implement pumped hydro storage.
Where it can be used, it should be (and largely is - fossil fuel generation does better with some storage as well, since demand is not consistent), but it’s hardly something that can be deployed alongside solar and wind generators everywhere.
With some high voltage long-range transmission lines you could viably do it pretty much everywhere. Just requires some cooperation.
Yes it will slightly reduce efficiency over very long distances, but it's not unreasonable amounts.
Long range transmission of AC power is limited to about 40 miles. DC can be transmitted much farther, but the infrastructure is substantially more expensive (because it’s more dangerous), so that’s only done for extreme need.
We aren’t getting away from having many power generators all over the place, so one location-dependent storage solution isn’t going to solve all the problems.
I might also add there's smart algorithms being developed for about 5y+ now that distribute power surplus and deficiency over a grid. This will probably be key. Just take a look at "energy metering".
ah you already beat me to the response, pumped hydro is already utility scale baseline power supply