> To facilitate this synchronisation, stable base-load power is required, which is normally provided by nuclear and other large gas and hydroelectric facilities. These sources act as a natural buffer against disturbances, helping to keep the frequency stable in the face of sudden changes in generation or demand.
In theory, it seems like you could instrument a photovoltaic array to carry some "inertia" with the right control system.
If you need to feed power, you run some power point tracking algorithm, and if you need to consume power, you just overbias the cells and heat them up.
In a system of micro-inverters, they need something to synchronize with. There needs to be a "truth" reference, so they can push their power onto the grid by slightly leading the phase of that.
If some critical mass of PV micro-inverters exceeds the traditional generators, they'll push so hard that the grid itself will change phase, and blackouts are the result.
One possible solution might be to use a better oscillator in the micro-inverter and limit the rate of phase shift. Unfortunately, the grids of the world have been moving in the opposite direction and now allow more drift than in the past, so where do you draw the line?
> they'll push so hard that the grid itself will change phase
That's a thundering herd problem: where all invertors have the same set-points and they all are synchonised to push in the same direction at once.
In networks, thundering herd problems are fixed by given each sender different random delays.
For power networks we could choose statistical methods to get individual solar generators to lead or lag so that the frequency becomes an aggregate vote.
Given that part of the blackout was due to large amounts of solar going offline at the same time, it's possible that all invertors with common software were tripped at the same set-point.
So trip conditions also need to be randomly fuzzy. E.g. if frequency drops below 49Hz +/- random spread of 0.5Hz.
Although it's difficult to match financial incentives against random variations (individual generators are incentivised to power outside of boundaries to keep getting paid, and a trip event can be expensive - due to restart costs).
Electricity market design is hard because the design needs to be resilient to perverse incentives.
Conceptually, your idea seems reasonable, but because the goal is to put the power from the solar micro-inverters onto the grid, they must lead the grid phase by a few degrees. If they lag instead of leading, they are draining power from the grid and not supplying power into the grid.
People with PV arrays want to make money by selling power into the grid. Perhaps if they were a little less greedy, they could back off the phase difference if they detect the grid phase drifting from too much "pushing." After all, they can't sell any power at all while the grid is down.
Yep it’s called synthetic inertia. Solar and wind can both offer it. Wind can actually offer loads of it it’s just not as easy since it’s not synchronous.
you have panels connected to grid thru inverter and that can modulate output in any way needed in few milliseconds.
same as inverter in electric car providing power to motors.
or inverter providing power to coils in your loudspeaker/ headphones.
inverter can adjust phase, voltage, frequency. it can means it is job of inverter to provide that in normal operation. that is why it is there in first place.
In theory, it seems like you could instrument a photovoltaic array to carry some "inertia" with the right control system.
If you need to feed power, you run some power point tracking algorithm, and if you need to consume power, you just overbias the cells and heat them up.