In a recent study, researchers from the European Environmental Bureau (EEB), the Stockholm School of Economics (SSE), and the Potsdam Institute for Climate Impact Research (PIK) questioned the planned development of new nuclear capacities in the energy strategies of the United States and certain European countries.
Storage, there are many options. Pumped hydro is great for places with elevation change, molten salt is great for desert climates. Batteries, green hydrogen, compressed gas, etc.
We’ve been storing energy for thousands of years. It’s not difficult in the way nuclear fusion, SMRs, or thorium are difficult.
We’re also moving towards EVs. I’d like to see investment in using a fleet of connected EVs as a giant battery. Your energy company can pay you for making 10-15% of your EV battery available for grid storage and you can opt out if you need that extra range for a trip.
The largest battery on the planet would power my workplace for less than two hours- if it could meet the instant demand, which it cannot.
I’m all for energy storage, but I realise there’s a lot of work to do.
1,200MW isn’t enough? Where do you work?
Why do you think batteries can’t meet instant demand? That’s kind of their whole thing.
https://www.theguardian.com/australia-news/2021/feb/05/worlds-biggest-battery-with-1200mw-capacity-set-to-be-built-in-nsw-hunter-valley-australia
We draw a very consistent 950MW, 24hrs a day.
The battery you linked, if it goes ahead, will max out delivery at 400MW, which it can sustain for 3 hours before its 1200MWh storage is exhausted.
Batteries can deliver power instantly, but not beyond their max output.
There’s heaps of interest and proposals, and I hope they go ahead. But there’s a lot of work to do.
Right, but you realize that’s far from typical for a workplace?
The article talks about the coming droughts and water shortages. Pumped hydro is nice, if you have water.
There’s evaporation, which can be mitigated by floating solar panels, but pumped hydro is a closed system, it doesn’t consume water.