Grid forming gets you part of the way there, but there are still things that the traditional synchronous machines provide that you cannot get. The instantaneous, control-free response mechanism is not to be understated. It is rooted in pure physics and electromagnetics. It is entirely automatic and error-free in its operation.
> And in an innovative twist, the battery site can also provide short-circuit current in response to a fault, just like conventional power generators.
Sure. But, how much? The turbine at a nuclear/coal/CH4 power plant can handle upward of 10x the rated current for several cycles. The amount of fault current that synchronous machines can provide will always run circles around solid state solutions. This capability is essential for stability in downstream fault scenarios.
You can't really "saturate" a synchronous machine in the same way you can a farm of solid state electronics. Certainly, the 1GW turbine will eventually fail from an overcurrent situation, but it's going to last way longer than a semiconductor junction in the same situation.
thebruce87m · 19m ago
Sure. But, how much?
> It programmed Blackhillock’s inverter to hit 250 percent above nominal current to deliver the 140-millisecond pulse that NESO requires, says Aaron Gerdemann, a business-development manager for SMA. After that, the device will back down, allowing the circuits to cool.
olddustytrail · 1h ago
A response in milliseconds is effectively instantaneous. Also there is no coal in Scotland since 2016.
And if you want physical spinning machines, there is hydro which is obviously big in Scotland because there's plenty rain.
ViewTrick1002 · 2h ago
Seems incredibly expensive to build spinning rust generators with the sole intention to solve ancillary services?
We can of course also simply add a clutch between the turbine and the generator allowing the grid to drive the generator and providing that physical response if we somehow realize we can’t do without it.
metalman · 3h ago
It's not solid state,just non mechanical, lithium batteries do undergo a chemical and toacertain degree physical state change as ions move and covert compounds from one to another.
True solid state would use so called "supper caps", which provide physical spaces for electrons to rest, until discharged, with at present no swelling or physical movement,though swelling might become apparent with high enough capacities, which on consideration seems like it could come with a whole new way for things to go suddenly and drasticaly wrong, where something goes from a solid to a completly disasociated plasma instantly.
nothing that will surprise an experienced linesman
as initialy it would probable sound alot like the insulation starting to break down just before something carrying a lot of current at very high voltages makes just befor it finds ground
> And in an innovative twist, the battery site can also provide short-circuit current in response to a fault, just like conventional power generators.
Sure. But, how much? The turbine at a nuclear/coal/CH4 power plant can handle upward of 10x the rated current for several cycles. The amount of fault current that synchronous machines can provide will always run circles around solid state solutions. This capability is essential for stability in downstream fault scenarios.
You can't really "saturate" a synchronous machine in the same way you can a farm of solid state electronics. Certainly, the 1GW turbine will eventually fail from an overcurrent situation, but it's going to last way longer than a semiconductor junction in the same situation.
> It programmed Blackhillock’s inverter to hit 250 percent above nominal current to deliver the 140-millisecond pulse that NESO requires, says Aaron Gerdemann, a business-development manager for SMA. After that, the device will back down, allowing the circuits to cool.
And if you want physical spinning machines, there is hydro which is obviously big in Scotland because there's plenty rain.
We can of course also simply add a clutch between the turbine and the generator allowing the grid to drive the generator and providing that physical response if we somehow realize we can’t do without it.