https://en.wikipedia.org/wiki/2016_South_Australian_blackout
Completely solved with lithium based grid storage at key locations btw. This grid storage has also been massively profitable for it's owners https://en.wikipedia.org/wiki/Hornsdale_Power_Reserve#Revenu...
Australia currently has 4 of the 5 largest battery storage systems under construction as a result of this profit opportunity; https://en.wikipedia.org/wiki/Battery_energy_storage_system#...
You can also read numerous stories of how Australia's lithium ion grid storage systems have prevented blackouts in many cases. https://www.teslarati.com/tesla-big-battery-south-australia-... The fact is that the batteries responsiveness is the fastest of any system at correcting gaps like this. 50/60hz is nothing for a lithium ion battery nor are brief periods of multi-gigawatt draw/dumping as needed.
There's even articles that if Europe investing in battery storage systems like Australia they'd have avoided this. https://reneweconomy.com.au/no-batteries-no-flexibility-spai...
Actually this is typically an issue for grid batteries.
Spinning generators can easily briefly go to 10x the rated current for a second or so to smooth out big anomalies.
Stationary batteries inverters can't do 10x current spikes ever - the max they can get to is more like 1.2x for a few seconds.
That means you end up needing a lot of batteries to provide the same spinning reserve as one regular power station.
What causes the Iberian blackout is excessive reactive power and a lack of compensation at a given time (due to multiple factors).
Compensation of reactive power has strictly nothing to do with localization of generation. It barely even can be assimilated to oscillations
That's complete garbage and it shows mainly you do not seem to know much about Electricity power in general.
Basically I'm dubious. I'm sure there are grids somewhere that have misprovisioned their inverter capacity, but I don't buy that battery facilities are inherently unable to buffer spikes. Is there a cite I can read?
Australia's largest power plant has 2.9GW of inertial generation assuming all generators are running at 100%. As in the small battery substation alone comes close to the countries largest power station. I'm not sure where the idea that lithium ion can't dump power quickly comes from. They are absolutely phenomenal at it. Australia's building dozens of these substations too since they are so cheap and reduce overall power costs. It's a win from all points of view.
Large spinning masses can provide several seconds of inertia. For 2GW of traditional turbine, you would have between 10-20 gigawatt-seconds of energy that is instantly available at any moment to resist RoCoF.
which they won't ever be given the habits of coal plants to suffer outages whenever it's convenient to pump the price up.
The whole point with actual inertia is that you get a large multiple of your maximum capacity without any redundant parts or added system complexity.
Keeping around 10x+ more semiconductors than you need to cover a tiny fraction of operational scenarios is difficult economics.
A semiconductor device cannot be overloaded like a spinning generator or transmission infrastructure can. You cannot trade temperature and maintenance schedule for capacity in the same way. Semiconductors have far more brittle operating parameters.
Not according to the prices I see. Digikey tells me I can switch a MW of power for about the price of a MBP. I ask again, is there a citation for this nonsense?
More inverters in parallel will achieve the same end goal - fast frequency response.
what's correct is that each individual inverter can only increase its power output momentarily to 20% or so above its maximum. Add more inverters and that problem is solved.
(And "reactive power" could be good too but not absolutely necessary to understand at first...
Although I’m hardly an expert on power lines(my factory produces HV switchgear), a 1s short circuit current rating of 10x(actually more) is normal, standard to IEC norms.
Misaligned oscillation can occurs under ANY load.
I'm very suspicious of this, because it would also imply 10x overcurrent on the associated transmission gear. There's limits on how much you can overcurrent a transformer before the core magnetically saturates, for example. Also I would expect protection systems to trip out at such a huge divergence from rated current. Do we have a citation?
That equivalent inertia can only be done for short periods but that's exactly what grids need in stability - there's generally no lack of total generation, just a need to jump in and smooth out spikes.
You can't build a dam for that price, nor could you do it in under 100 days from contract signing as that battery was built. Batteries are definitely the answer here. The 'more spinning mass' answers don't make sense since Australia literally solved the above problem in a much cheaper way already.
Is it that common that dams are already existing in nearby-ish pairs with the sufficient height difference? And that we haven't done this already?
Doing this is good where we can. But it has geographical limitations. Batteries don't so much.
You can always use a ton more concrete and force new locations, but the best locations have already been utilized and scaling law of batteries has brought them to the point where they're more competitive than new hydro for this kind of use.
That's because Australia has a moderate amount of renewables and prefers to burn fossil fuels. Right now, around 25% of the electricity in Australia is generated by solar or wind.
Spain is past 50% of renewable generation, and their problems are much bigger.
> That problem may not have been entirely Spain’s fault, El País said. “Interconnections with the rest of the continent continue to be much fewer than the European Commission recommends, not because Spain isn’t interested, but because France has for years resisted expanding them.”
[1] https://en.wikipedia.org/wiki/List_of_countries_by_electrici...
[2] https://www.theenergymix.com/massive-blackout-in-spain-shows...
> The ultimate cause of the peninsular electrical zero on April 28th was a phenomenon of overvoltages in the form of a "chain reaction" in which high voltages cause generation disconnections, which in turn causes new increases in voltage and thus new disconnections, and so on.
> 1. The system showed insufficient dynamic voltage control capabilities sufficient to maintain stable voltage
> 2. A series of rhythmic oscillations significantly conditioned the system, modifying its configuration and increasing the difficulties for voltage stabilization.
If I understand it correctly (and like software, typical), it was a positive feedback-loop. Since there wasn't enough voltage control, some other station had to be added but got overloaded instead, also turning off, and then on to the next station.
Late addition: It was very helpful for me to read through the "ANNEX X. BRIEF BASICS OF THE ELECTRIC SYSTEM" (page 168) before trying to read the report itself, as it explains a lot of things that the rest of the report (rightly) assumes you already know.
https://www.boe.es/buscar/doc.php?id=BOE-A-2000-5204
7.1(b) seems to be saying that generators connected at 200kV adjust their reactive power generation/absorption in real time according to the voltage they observe, based on a lookup table provided by the grid operator.
This seems sort of sensible according to my limited understanding of the theory of AC grids. You can write some differential equations and pretend everything is continuous (as opposed to being a LUT with 11 steps or so), and you can determine that the grid is stable.
However, check out this shorter report from red eléctrica:
https://d1n1o4zeyfu21r.cloudfront.net/WEB_Incident_%2028A_Sp...
Apparently these 220kV plants are connected to the 400kV grid via transformers in substations that are not owned by the generator operators. And those transformers have “tap changers” that attempt to keep the 220kV secondary side at the correct voltage within some fairly large voltage range on the 400kV side. Won’t this defeat the voltage control that the 220kV generators are supposed to provide? If the grid voltage is high, then absorption of reactive power is needed [0], and the generators are supposed to determine that they need to absorb reactive power (which they can do), but if the tap changer changes its setting, then the generator will not react correctly to the voltage on the 400kV side.
In other words, one would like the generator to absorb reactive power according to P_reactive(primary voltage • 220/400), but the actual behavior is P_reactive(primary voltage • 220/400 • tap changer position), the tap changer position is presumably something like 400/primary voltage, and I don’t understand how the result is supposed to function in any useful way. Adding insult to injury, the red eléctrica repoet authors seem to be suggesting that a bunch of tap changers operators didn’t configure their tap changes well enough to even keep secondary voltages in range.
Does anyone with more familiarity with these systems know how they’re supposed to work?
[0] I can never remember the sign convention for reactive power.
- Fast Frequency Response (FFR), sub-second power adjustment following frequency table
- Frequency Containment Reserve (FCR), ~second power adjustment following frequency table
- Automatic Frequency Restoration Reserve (aFRR), ~second energy production following TSO setpoint signal
- Manual Frequency Restoration Reserve, ~minute energy production following TSO activation signals
My understanding is the primary failure in Spain was that 9 separate synchronous plants that had sold aFRR(?) to the TSO then failed to deliver, so when the TSO algorithms tried to adjust the oscillations, nothing happened. Everything else was kinda "as designed".
Oof. This sounds like a classic of "it's only needed in emergencies, so it's only in emergencies that we find out it doesn't work".
So if the grid wants to be at 400kV, and achieving 400kV under particular generation conditions requires 1500MVar of reactive power absorption by the grid (I made up that number), and the grid operator is relying on 220kV conventional generators to collectively have 1000Mvar of absorption available under said conditions, then something needs to communicate that need to those generators so that they actually absorb those 1000Mvar. And if the OLTCs fool the control algorithm into causing those generators to absorb only 400Mvar, then there’s a mismatch, and that mismatch doesn’t go away because the OLTCs are supposed to be slow.
If, as the writeup seems to suggest, the grid design also requires the OLTCs to operate quickly under large voltage fluctuations because the secondary side cannot tolerate the same fractional voltage swing that the primary side is specified to tolerated, then I would not want to be the person signing off on the grid being stable. (Writing the simulator could be fun, though!). Maybe the idea is that, if the primary voltage is stable at 10% above nominal, then the OLTCs are intended to be stable at a position that holds the secondary at 5% above nominal, and that in turn is intended to result in the correct amount of reactive power absorption?
If I were designing this thing from scratch, I would want an actual communication channel by which facilities that can adjust their reactive power can be commanded to do so independently of the voltage at the point at which they’re connected. And I would want a carefully considered decentralized algorithm to use these controls which, as a first pass, would take input from the primary side at the relevant substations. And then I would want to extend a similar protocol to most or all of the little solar generators at customer sites (not to mention the larger solar facilities that don’t dynamically control reactive power at all in Spain) because they, collectively, can quickly supply or absorb large amounts of reactive power on demand. (Large facilities would use fiber. Small facilities would use digital signals over the power lines or, maybe, grudgingly, the Internet. We really don’t want a situation where the grid cannot start up without customer sites having Internet access.)
Or I would dream of a grid that’s primarily DC with AC islands where the DC portions don’t care about reactive power or frequency at all and merely need to control voltage and power flow.
See Part C here (e.g., SOs having the ability to control generator setpoints): https://eur-lex.europa.eu/legal-content/EN/TXT/?uri=uriserv:...
And the original long PDF, page 21, mentions the use of Operating Procedure 7.4 Dynamic Voltage Control, and it very vaguely mentions programming of the RRTT (which seems to include the 7.4 schedule) the day before the failure and the day of the failure, but I didn't see anything about the operator programming the RRTT during the failure to control voltage.
It seems to be (and this is not any sort of control theory analysis) that, if the grid voltage is too high (in specified range, but high enough that tap changers must operate to avoid disconnecting generators) and additional reactive power absorption is needed, then the grid ought to react by operating the tap changers (because it's necessary) and by somehow instructing the generators to absorb additional power despite the operation of the tap changers. And I see plenty of discussion about the tap changers in the big PDF as well as plenty of discussion of data acquired via SCADA links, but I don't see anything about adjusting the reactive power schedules to compensate for the operation of the tap changers or about the use of any sort of real-time SCADA control to adjust reactive power.
While the overall reason for the mass failure you cite is correct - a cascading failure - the interesting bit here are the oscillations that lead to it.
It looks very much like this was driven by algorithmic volatility trading of electricity spots - overproduction, price goes negative, buys placed, production ramps in response to rising price, price rises, sells placed, production falls due to falling price. The period of the oscillations in the grid seen before the blackout suggest a relatively slow cycle, and what they describe in the report sounds very much like this was an interaction between price-driven supply and real world supply.
It does speak to there being inadequate storage available on the grid to smooth demand and therefore pricing, but it also suggests that in certain conditions a harmonic can be set up between the market and price-driven production with catastrophic consequences.
Yes, + less "reactive power stations" than expected was available (seems the day some unexpectedly went offline, and not enough safeguards/communication to realize this) + a switch between the French import/export that happened at the same time, leading to the overvoltage issue, which then spiraled.
As far as I read the report, there were multiple causes, not a single one like "algorithmic volatility trading of electricity spots" but a combination of the issues where one-by-one, things would have been fine but all together? Shit broke
Cybersecurity and digital systems was not the issue but gets thirteen pages of proposed measures. I feel this could have been left out.
Electric System Operation was the issue and gets seven pages of proposed measures.
https://d1n1o4zeyfu21r.cloudfront.net/WEB_Incident_%2028A_Sp...
It's pretty much their one and only chance to warn the authorities that there's a risk, so if they choose to ignore it, well, nobody can claim they weren't informed.
Sadly, some news outlets are probably only going to look at the recommendations and read "cybersecurity" and (even though they are common sense recommendations) assume there might be more to say about the matter.
Oh wait, they already did: https://www.telegraph.co.uk/business/2025/06/18/renewable-en...
Ed: Do I need a /s tag here or something? My point was that we shouldn't worry too much about about the presentation of the report, its actual contents will be spun to suit any narrative regardless.
The report actually says that there was a drop in solar generation.
Due to interactions between different generators, there can be instabilities causing voltage or frequency or reactive power to deviate outside of spec. A simple example might be two generators where one surges while the other drops back, then vice versa. The measurement (by the network operator) of these effects is poor for Spain - shown by the simple example that they have large oscillations that they couldn't explain.
There's path dependent healing and correction of problems by different generators, which overall leads to network stability. However the network operator here is not actually resolving cause and effect, and does not have the insight to manage their stability properly.
In this case you can see them trying a few things to inject changes that they hope will bring stability - e.g. tying many connections hoping that adding generators together into one network will resolve to a stable outcome.
Are there countries that have a better design for their electricity network control systems?
Disclaimer: I don't design electricity networks nor electricity markets. And the above is ignoring loads (loads are mostly less problematic for control than generation).
The actions that were taken did not strike me as out of the ordinary.
How do these oscilations start? I understand that voltage isn't necessarily equal across the network, where frequency is. But that only allows oscillating, it doesn't cause it. Is this a basis inductor capacitor oscillation? Is it the small delay in inverters between measuring voltage and regulating their output? (seems unlikely, given that renewables aren't blamed) or is there some other source of (delayed) feedback.
And why do generators cut off at a high voltage? Is it a signal of 'too much power'? Is it to protect the generator from some sort of damage?
For the oscillations, the European grid in general is large enough that the time it takes for the energy to flow (at some fraction of the speed of light!) from one side of it to the other is not negligible: it's not a case of delays at the power plant, but delays in the network itself which can cause the various natural and artificial feedback loops in the circuit to start to become unstable and oscillate. In this specific incident, there's some implication in the report that the largest oscillation was unusual and may have been generated by single plant essentially oscillating on its own, for reasons unknown.
In either case, the oscillations were not the direct cause of the blackout: they were controlled, but the steps to control them put the system into a more fragile state. This is because of reactive power. The voltage in the system is due to both the 'real power', i.e. the power generated by the plants and consumed by consumers in the grid each cycle of the 50Hz AC, but also 'reactive power', which is energy that is absorbed by the consumers and the grid itself (all the power lines and transformers) and then bounced back to the generators each cycle. This is the basic 'inductor-capacitor' oscillation. This reactive power is considered to be 'generated' by capacitance and 'consumed' by inductance, though this distinction is arbitrary.
So, after the grid operator had stopped the oscillations, the grid was 'generating' a lot more reactive power, because damping down the oscillations generally involves connecting more things together so they don't fight each other as much. It also _lowered_ the grid voltage on average, so various bits of equipment were essentially adjusting their transformer ratio with the high-voltage interconnect to try to adjust for it.
Apart from these measures, the generators on the grid are generally supposed to contribute towards the voltage regulation, which helps with both damping these effects and reducing the change of the runaway spike that happened. But crucially, there's a difference between what they (by regulation, not necessarily technical capacity!) do. The traditional generators have active voltage control, which means they actively adjust how much reactive power they generate or absorb depending on the voltage on the lines. Renewable generators, by contrast, have a fixed ratio: they will be set to generate or absorb reactive power at a certain percentage of the real power (a few percent usually), they don't actively adjust this (they're not allowed to under the rules of the grid).
So, after the oscillation, the grid is generating a lot of reactive power and the power plants are absorbing it, but there's a lot of renewables around, which can't actively control voltage, they're just passively contributing a certain amount. Then there's a fairly rapid drop in real power output, which seems to be related to the energy market as some plants decide to curtail. This is expected, but renewables can do it pretty quickly compared to conventional plants. This means that the amount of reactive power being absorbed drops, i.e., counterintuitively a plant producing less power means the voltage rises.
In theory, there should be enough voltage control from conventional sources to deal with this, but in general they prove to not absorb as much reactive power as they were expected to, and the report calls out one plant which seems to just not be doing any control at all, it's more or less just doing something random. This means the voltage keeps rising, and, perhaps in part due to the adjustments in the transformer ratios, this means another plant trips off, at a lower voltage than it should (this is, basically, for protection: the equipment can only take so much voltage before it's damaged, but there's rules about what level of voltage it should withstand and, in extreme cases, for how long). This then makes the voltage rise more, and it's a fairly rapid cascade of failure from there, and many plants kick offline in a matter of seconds, and only then does the frequency of the grid start to drop significantly, but it's already too late because there's too much demand for the supply.
The recommendations of the report basically boil down to:
- Figure out why the plants (renewable and conventional) didn't have the capabilities the grid operator thought they did (or why they were actively causing problems), and fix them.
- Fix the regulations so renewable plants are allowed to contribute to active voltage control, and incentivize them to do so.
- Adjust the market rules so that plants have to give more notice before increasing or decreasing supply in response to prices
- Improve the monitoring of the grid and add other tools to help with voltage control (including better interconnects with the rest of Europe)
Could this have been a deliberate attempt to crash the grid?
Now I'm curious about what's in the confidential version of the report.
> Incidents detected during equipment start-up - Firstly, there is information consistent with the fact that several installations with the obligation of autonomous start-up were finally unable to provide this service in a stable manner, joining the system only once voltage had arrived from outside (from another of the "islands", normally anchored in one of the interconnections). This slowed down the start-up of the "skeleton" of the electricity system that would later make it possible to replenish the supply to demand.
The rest of the ~2 pages in that section is redacted.
Oscillation -> damping -> possibly faulty equipment and possibly lack of power plants to absorve the reactive load -> 0 voltage in two countries and some neighbouring regions
There's also the possibility that Portugal put too much demand on the market due to negative prices, but I'm not sure if it was explained how much that had an effect on the whole thing.
I would like to see: "We have simulated the complete 200 and 400 kV grid of the iberian peninsula and western europe, and can reproduce the situation that occurred. Any one of the following changes would have prevented the issue, and we suggest implementing them all for redundancy. This simulation will be re-run every day from now on to identify future cases similar incidents could occur"
> However, as is common in networks and information systems in any sector, other risks have been identified, such as vulnerabilities, deficiencies or inadequate configurations of security measures, which may expose networks and systems to potential risks, for which a series of measures are proposed.
Based on this comprehensive report on the April 28, 2025 electrical blackout in Spain, I can summarize the key reasons why it happened:
## Primary Cause: Voltage Control Crisis
The blackout was fundamentally caused by *insufficient dynamic voltage control capacity* in the system, which led to a catastrophic "chain reaction" of overvoltages. Here's how it unfolded:
### The Perfect Storm of Contributing Factors
*1. Inadequate Voltage Control Resources* - Only 11 thermal power plants were coupled with voltage control obligations (the lowest number recorded in 2025) - One planned voltage control plant in the southwest failed the previous evening and wasn't replaced - Several connected plants didn't provide expected reactive power absorption during critical moments
*2. System Oscillations Weakened the Grid* - Multiple oscillations occurred throughout the morning (starting at 5:49 AM) - Two major oscillations at 12:03 PM (0.6 Hz) and 12:19 PM (0.2 Hz) significantly stressed the system - The first oscillation was traced to anomalous behavior at a specific photovoltaic installation - Measures taken to dampen these oscillations (increased grid meshing, reduced interconnection flows) inadvertently contributed to voltage increases
*3. The Fatal Chain Reaction (Phase 2-3)* Starting at 12:32 PM: - Voltages began rising rapidly across the transmission network - Generation facilities started disconnecting due to overvoltages, beginning with renewable plants - Each disconnection removed reactive power absorption capacity and reduced line loading - This caused further voltage increases, triggering more disconnections - The process accelerated into an unstoppable cascade
### Key Timeline - *12:32 PM*: Sustained voltage increases begin - *12:32:57*: First major generation loss (355 MW at Granada) - *12:33:16*: Second major loss (730 MW at Badajoz) - *12:33:17*: Third major loss (550 MW at Sevilla) - *12:33:30*: Complete system collapse to zero voltage
### Why Couldn't It Be Stopped?
Once the chain reaction began, stopping it would have required massive reactive power absorption capacity that simply wasn't available. The system's protective mechanisms (like demand disconnection) actually made the overvoltage problem worse by further reducing grid loading.
## Broader Context
The report emphasizes this was a *multifactorial event* - no single failure explains it entirely. Contributing factors included: - Low electrical demand creating capacitive effects in the highly meshed grid - Quarter-hourly market changes causing rapid generation adjustments - Spain's weak interconnection with Europe (only 3% vs. 15% target) - Complex renewable evacuation infrastructure with inadequate protection settings
The restoration process took until 7:00 AM the next day to reach 99.95% supply restoration, though it was considered exemplary by international standards.
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I don't see that.
> and factually incorrect.
Then substantiate your point.
Stability is one of the things grid operators pay for-- not just production.
Read the report. Power systems are complicated and not as easy as just "build another nuclear plant". It was (by regulation) conventional units that were required to provide voltage support, and it was in part their failure to operate according to their requirements that lead to the voltage excursions that caused the system collapse. The renewable systems that were capable of providing voltage stability were not allowed to do so.
It's also a bit of a straw-man to put your own version of what someone's saying in their mouth.
Buying insurance and other mitigations against rare circumstances, outside of well regulated and well understood products in stable marketplaces, is really hard. You need to do your homework with the counterparties and be sure that incentives align well enough to get what you want.
Unfortunately, when you set up an incentive system, you tend to get exactly what you pay for-- whether that's what you want, or not.
The stability of a nuclear plant vs the instability of a solar far when a cloud passes over.
Your other comment probably got flagged because it started with a huge straw man and had multiple unwarranted jabs in it.
Also, have you read after the market part? Please watch this video https://www.youtube.com/watch?v=7G4ipM2qjfw if the last quote is gibberish to you. It discusses somewhat different issues, but the point still stands.
Why is the problem the cheap source of supply rather than the market rules and incentives that made everything act the way it did?
Your comment suggests move back to good ol' expensive fossil generation instead of looking at how to bring the market rules up to date with evolving technologies.
I explicitly mentioned this line of argument in the GP. The problem is that renewables only sometimes cheap and plentiful and often not when we want it. Even without accounting for the politically-driven preferential treatment covered in the sibling comment, from the purely technical point of view intermittency above certain threshold wreaks havoc in the traditional grid architecture designed for the traditional easily controlled "rotating" generation. It becomes really hard to manage the grid with existing tools when you have too much of intermittent highly distributed generation and in the extreme it leads to collapses like this.
As I wrote, yes, you could upgrade the grid, increase transmission redundancy, add battery/pumped/flywheel storage, introduce "smart" tools to manage the grid, and do a plethora of other things to accommodate renewables. Hell, you could even migrate the grid to DC!
But the cost of doing it is substantial. It's effectively a form of externalities of renewable generation, which are not accounted for in naive "cheap" $/kW metrics. Properly accounting for those externalities and adding them to the cost of renewable generation is possible, but politically unappealing.
>Your comment suggests move back to good ol' expensive fossil generation instead of looking at how to bring the market rules up to date with evolving technologies.
No, I believe we should remove the politically motivated shoehorning of renewables at the cost of grid stability. There should be a limit on how much intermittent generation we can have depending on the preparedness of the grid and we should pay less for power from such sources, not guarantee purchase from them!
As you say, we should have proper incentives structure which accounts for various externalities (including CO2 emissions!). We need to remove the existing subsudies on renewables which made sense in the early days, but not now. Let the generation sources play at the even field.
> Properly accounting for those externalities and adding them to the cost of renewable generation is possible, but politically unappealing.
Implying this was/is not done and should be done. As a certified fan of looking out for (cost) dependencies, I agree with this to put it very mildly. I find it unlikely this wasn't done however, rather, I think renewables were likely onboarded harder than the externalities were taken care of to allow for it, possibly due to political pressure and/or mismanagement. Or at least, that rings all too familiar to me personally, not just from real world topics, but even from work. But then what you actually propose is:
> There should be a limit on how much intermittent generation we can have depending on the preparedness of the grid and we should pay less for power from such sources, not guarantee purchase from them!
Which is a different concern.
Also, this reads to me awfully like just flowery language for "hey, what if the obviously bad thing that happened wouldn't be allowed to happen anymore" with the logic retconned into it, but then I'll never have a way of proving or demonstrating that conclusively.
Finally,
> We need to remove the existing subsidies on renewables which made sense in the early days, but not now. Let the generation sources play at the even field.
This further doesn't follow from even your own explanation (i.e. "which made sense in the early days but not now" is not a substantiated claim). It's just your own political stance on the matter to the best I can tell.
This is also factually incorrect (unless Spain are now doing some country level subsidies on renewables). Fact is, new solar and new wind offer the lowes average power generation costs of any method. Regular market forces (without susidies) will favor renewables over anything else. Hydro being the most profitable.
Market-based economies are great to follow technology trajectories and are efficient at capital allocation but even for them we need additional incentive structures to speed up the process.
I also think that most countries have massively reduced subsidies for new projects but existing subsidies will still be served for a long time.
Something like: the first 10Gw after start and the last 10GW before a stop make 50% of the revenue than the rest. That should disincentivize suddenly turning everything on or off depending on energy prices.
I'm glad people are coming around to accepting that renewable energy has problems. We have some solutions to these problems but we do not have experience with them.
I agree entirely - the externalities of renewable energy are significant and are not paid for by the source of the problem - the renewable generators themselves.
Just as one example, what is the solution to an extended wind drought, say of a week or ten days? All the batteries in the world could not store enough energy for that.
A major challenge with renewable energy is that it is intermittent and variable but also unpredictable. it is impossible to predict wind speeds more than 24 or 36 hours out and even those predictions are often inaccurate. just building more wind turbines or solar panels won't cut it.
There is also the reluctance of grid operators to use the capacity available in renewable energy generators. The majority of wind turbines are capable of active and reactive power control but most grid operators either don't use this capacity or use it minimally.
A distribution connected wind turbine could do wonders for reactive power control but this is rarely done. More grid operators should pay for reactive power, like the UK is starting to do. This should also be sourced from EVs and small solar inverters.
I wonder how much is the near-complete inability for grid operators to communicate with smaller systems. My little solar inverter is capable of reactive power control over a respectable range of phase angles, and the grid operator has absolutely no ability to invoke this ability short of whatever formula the combination of PG&E, the various regulators, and the UL stuck into some standard for how small inverters are supposed to behave under various voltage and frequency conditions.
Never mind that inverters could also be fooled into thinking they’re islanded and therefore disconnect themselves if the grid frequency is too far out of range. This is usually designed to occur at above-nominal frequency, which is at least mostly not what happened in this event.
This is all very much possible and the tech to do it is relatively basic. Grid operators do not because the market rules were written by larger generators to favour those larger generators.
Looks like there are a multitude of schemes of various vintages in Spain, which tl;dr basically give you a guaranteed price per MWh you generate. So imagine you get a 100eur/MWh subsidy for a (legacy) solar plant. The market price is €-20/MWh. You will still continue to produce power until the price reaches -100MW/h. Even worse are some contracts for difference (poorly thought through) which give you a guaranteed price regardless of what the market is at. So even if the price was -1,000eur/MWh the government or grid operator would still give you your €50/MWh (and the subsidy would be 1,050/MWh!).
The problem is if you reform this (and it is happening worldwide) solar is much, much less appealing. Because suddenly your solar plant which was getting (say) a guaranteed 70/MWh all year round suddenly does not make money for 6 months of the year at least at peak sun hours.
On top of all this, you have a lot of domestic solar in places like Spain. The grid operator _cannot_ control these assets in nearly all circumstances. They will continue to dump power into the grid regardless of the market price. This again will change but it requires an awful lot of work to retrofit invertors with remote control capability OR a lot of public backlash for charging end customers who bought solar in "good faith" now getting hit with peak time negative prices (so they change their behaviour).
I think my core message would be _any_ negative power prices is a sign of market failure. Acceptable in rare extreme occurrences, but the fact most of europe has highly negative prices very frequently is telling you the grid and market design is not able to handle what is going on.
This massively simplifies reality.
E.g. in Finland where I live we also have issues with negative power prices. A few years ago we had some really low prices. It turns out, a fair bit of wind power producers never opted to add to their windmills any remote shutdown possibility, nor did they have the ability to monitor prices and react to them automatically. I.e. they just kept generating no matter the price, and had offers in at the network level at the lowest permissable price.
Since then, when they lost a non-insignifcant amount of money by running at negative prices, they've started installing control electronics in windmills and building IT systems and prediction algorithms to be able to react to this.
In the EU it is not as simple as "turning off when the prices are negative" since producers offer a certain capacity to the grid in an auction system the day before. You have to predict the weather + overall demand and set your offer accordingly.
Please can you share a source that explains your info?
Nuclear is not well suited at all to being curtailed, I also suspect it would be worth paying negative prices to avoid it to a certain level - the French reactor cracking problems (earlier design though) are hypothesized from what I read to becaused by a lot of demand curtailment putting stress on the various metals as they heat and cool frequently because of reducing output.
No, that is not what the report says. It says, just like you say, that renewables reacted to market prices, causing a generation drop. It then says explicitly that synchronous generation caused oscillation, while PV plants showed a flat non-oscillating pattern.
From your comments I worry there are emotional factors clouding how you're reading the report - this was a systemic failure involving many separate technologies:
- Market signals - negative prices - caused a drop in PV generation (as frequently occurs)
- Synchronous plants caused oscillations as a side effect
- Plants procured to dampen exactly those oscillations did not deliver as requested
- TSO then took measures using interconnections to stabilize via other balance area
- This caused - presumed - overvoltages in distribution grids
- PV inverters then shut off, as mandatory by regulatory requirement in response to over voltage
You're absolutely right that PV played a large role here, but that point is diminished by making it out that PV is both the source of the initial generation drop and the source of the oscillations; it is neither.
The market design caused the generation drop, synchronous generators caused the oscillations, TSO action caused distribution overvoltages and regulatory requirements on PV firmware design in response to overvoltage caused the final blackout.
The reality is that electricity is complex and that renewable energy presents a new set of problems, problems to which we do not yet have complete solutions.
But that takes time and requires some rebalancing, because much of that capacity is not closest to the producers. It also requires water, which becomes scarcer in the autumn (not the case here).
So the price can and does become negative for a window. “High frequency trading” the spot prices probably contributed to the problem.
In the case of Cruachan Power Station: “It takes just two minutes for a turbine to run up from rest to generate mode,” says Martin McGhie, Operations and Maintenance Manager at the power station. “It takes slightly longer for the turbines to run down from generate to rest, but whatever function the turbines are performing, they can reach it within a matter of minutes.”
https://www.drax.com/power-generation/in-energy-storage-timi...
There is not much fast trading to be done on a nuke/gas/coal/hydro powerplant ramping up or down, but there is a lot of instability (and thus market volatility) to be found in fast varying solar/wind conditions.
Renewables just change one set of challenges for another set, at the end of the day it's all manageable.
Don't forget rotational inertia. This gives the system a high-frequency response mode: it can resist sudden demand changes through stored kinetic energy, effectively acting as a low-pass filter with a fast dominant pole.
As you get a smaller share of generation with rotational inertia, you need a lot more buffering on short to medium timescales.
And, of course, it doesn't help for longer timescales that in many places renewable production slopes off in the late afternoon right when demand slopes upwards for cooling.
Demand rises because that's how people have their system set up. That cooling load can be shifted earlier in the day by using a slightly smarter thermostat to precook your house when the electricity is plentiful.
You can do this a bit, but the insides of houses don't have that much thermal mass and the best insulated houses add a pretty large phase delay that makes the quickest rise in internal temperatures during the late afternoon as framing in the attic heats up.
I don't have a lot of luck in accomplishing meaningful precooling in my house. My best plan is to suffer until the late afternoon, turning on the AC at the end of the peak demand period when at least outside temperatures are lower, my AC units are shaded, and the cooling is more efficient.
The incident was NOT caused by a lack of system inertia. Rather, it was triggered by a voltage issue and the cascading disconnection of renewable generation plants, as previously indicated. Higher inertia would have only resulted in a slightly slower frequency decline. However, due to the massive generation loss caused by voltage instability, the system would still have been unrecoverable.
(Spinning mass on its own doesn't do much to deal with the voltage fluctuations. It's entirely something that's reactive to grid frequency, which is the most 'global' indicator of supply vs demand in a grid, since it can't fluctuate locally. But voltage and current can vary wildly in different parts of the grid, and required separate management)
– the concrete causes of this specific blackout; – how the existing grid is not prepared to deal with the current energy mix; – the energy policy of the past decades, from the nuclear moratorium in the 80s to the large subsidies for renewable generation of the past couple decades.
A person's strong opinion on any one of these issues will inevitably influence their opinion on the others.
>the most plausible explanation is that it is due to market reasons (prices)
Seems to be market conditions or manipulations or inefficiencies in the market.