I was recently told by an electrical engineering lecturer that the black start plan here in Ireland is to use the DC interconnectors with the UK to provide startup power to a synchronous generator.

With the new wexford-wales interconnect that went live last month, and another one planned from Cork (?) to France things might be even easier in the near future I reckon.

Did he mention the UK's plan in case they have a full blackout?

https://www.nationalgrid.com/sites/default/files/documents/H... (2017, probably current)

"it is prudent that the cost of maintaining Black Start Capability should demonstrate value to the end consumer"

That sounds like someone explaining why the solution is so bad, before describing what the solution is.

Your incentive "analysis" is wildly incorrect.

Electricity markets and electricity networks are designed by the regulator.

Incentives are planned by the regulator so that individual stations or companies have the correct incentives to have capabilities that the network grid needs.

One example is financial incentives to provide black start capabilities. Another example is incentives to provide power during peak loading (peaker plants). There are many more examples of incentives designed so that the needs of the whole network are met.

If an operator is incentivised to act selfishly in such a way that the grid will fail, then that is a failure of the regulator (not the individual operator).

Blaming individual people or companies for systemic faults is generally a bad thinking habit to form. There are too many examples where I see individuals get blamed. Fixing our systems is hard but casting blame in the wrong places is not helpful. It's difficult to find a good balance between an individual's responsibilities and society's responsibilities.

> Meanwhile, there is no centralized capacity market or centralized incentives for black start and grid forming functionality.

There absolutely is. Look up terms like "Frequency Containment Reserve" and "automatic Frequency Restoration Reserve". The European energy market takes transport capacity in account, and there is separate day-ahead trading to supply inertia and spare generating capacity. Basically, power plants are being paid to standby, just in case another plant or a transmission line unexpectedly goes offline.

Similarly, grid operators offer contracts for local black start capacity. The technical requirements are fixed, and any party capable of meeting those can bid on it.

It's quite a lucrative market, actually. If during the summer a gas plant is priced out of the market by cheap solar, it can still make quite a bit of money simply by being ready to go at a moment's notice - and they'll make a huge profit if that capacity is actually needed.

No, there isn't. FCR market is not pan-European, and even where it's in place, it's basically in the name only. It's basically only countries that already use rotational generation, so it's not really a stretch for them to participate.

Spain and Portugal are not members, btw.

And the same applies to capacity markets. I believe, there is a plan to come up with a plan for it by 2027.

> Similarly, grid operators offer contracts for local black start capacity. The technical requirements are fixed, and any party capable of meeting those can bid on it.

And I don't believe there are ANY solar/wind plants that have black start capacity in Europe. The current incentives structure makes that a near certainty.

> there is no centralized capacity market or centralized incentives for black start

There certainly is in New Zealand, although the dollar amounts are quite small. If your countries regulator doesn't incentivise the capability, I believe that is a fault of your regulator.

Transpower (NZ) says:

  We may enter into black start contracts with parties who can offer the black start service compliant with our technical requirements and the Code. Black start is procured on a firm quantity procurement basis (via a monthly availability fee and/or a single event fee for specified stations). Black start costs are allocated to Transpower as the Grid Owner (see clause 8.56 in the Code for details)

FYI: here's a list of other contracted services that are procured to benefit network reliability/restart/resiliancy: https://www.transpower.co.nz/system-operator/information-ind...

The UK has pumped storage facilities that we can use to black start the national grid.

Connect with Ireland

Isn't that backwards? When grids interconnect via DC wouldn't there no longer be a need for the grids to synchronize frequency?

With the DC interconnect, your DC to AC conversion equipment would need the capability to provide synchronized power to the generator you are trying to start. With the synchronized grid tie, your are pulling the generator into the running grid.

Does the source of "truth" matter? You still have to turn everything off, bring your generators up, each in sync and then allow load back on slowly.

The UK keeping its own time just makes things easier for it IMO.

A synchronous interconnect provides not just a source of truth but also stabilizes your grid frequency. If you have an isolated grid you have to match generation to demand to keep the grid frequency stable. If you have a 1GW interconnect that means you can mismatch generation and demand by up to a gigawatt and still be fine. I imagine that makes for a much faster startup procedure

If the isolated grids all each synced to a source of truth first (GPS?), would it be possible for them to immediately connect afterwards?

You can connect two running grids. Earlier this year the Baltic countries disconnected from the Russian grid, and synchronized and then connected to the European grid.

I imagine you can get close enough by syncing to a shared time source like GPS or the DCF77 signal, as long as you communicate how the phase is supposed to match up to the time source. Or at least you could get close enough that you can then quickly sync the islands the traditional way.

The question is if it's worth the effort and risk. Cold starting a power grid is a once in a lifetime event (at least in Europe, I imagine some grids are less stable) and Spain seems to plan to have everything back up again in 10 hours. Maybe if the entire European grid went down we would attempt something like that by having each country start up on their own, then synchronize and reconnect the European grid over the following week.

https://en.wikipedia.org/wiki/Baltic_states_synchronization_...

Nothing that complicated. You just carefully synchronize the state of the grid on both sides of the interconnect, and when they are perfectly matched, you throw the big switch.

It's a bit difficult in another way: Obviously 50/60hz is not such a high speed that it's difficult to synchronize.

The harder part is this: To pump power into the grid you lead the cycle ever so slightly, as if you were trying to push the cycle to go faster. If instead you lag the phase the grid would be pumping power into you.

That lead is very very small, and probably difficult to measure and synchronize on. I would imagine that when the two grids connect everything jumps just a little as power level equalize, it probably generates a lot of torque and some heat, I would assume it's hard on the generator.

From a physics point of view, by leading the cycle you introduce a tiny voltage difference (squared), divided by the tiny resistance of the entire grid. And that's how many watts (power) you are putting into the grid.

Yes, but that actually makes it harder to start up.

To synchronize the isolated grids, they all need to operate with an exact match of supply and demand. Any grid with an oversupply will run fast, any grid with an undersupply will run slow. When it comes to connecting, the technical source-of-truth doesn't matter: you just need to ensure that there will be a near-zero flow the moment the two are connected - which means both sides must individually be balanced.

And remember: if you are operating a tiny subgrid you have very little control over the load (even a single factory starting up can have a significant impact), and your control over the supply is extremely sluggish. Matching them up can take days, during which each individual subgrid has very little redundancy.

On the other hand, the interconnect essentially acts as a huge buffer. Compared to the small grid being connected, it essentially has infinite source and sink capacity. For practical purposes, it is operating at a fixed speed - any change is averaged out over the entire grid. This makes it way easier to connect an individual power plant (it just has to operate at near-zero load itself, move to meet a fixed frequency target [which is easy because there is no load to resist this change], and after connection take on load as desired) and to reconnect additional load (compared to the whole grid, a city being connected is a rounding error).