Energy Storage - The
Holy Grail for intermittent electrical generators.
Reading the tweets and
articles from the wind and solar industries (and their avid
followers) you could be forgiven for thinking that large scale energy
storage was a done deal. Something that just needed the bureaucrats
in Westminster or Berlin or Washington to rubber stamp.
Sadly though, large
scale wind/solar energy storage is not only not a done deal it
is not even on the horizon. Even if it was it would still be very far
from being a “solution” to intermittent and dilute electrical
generation. But more on why that is in a later post.
First of all lets be
clear about what I mean by energy storage.
In a way, all current
thermal generation and hydro depend on “energy storage” The
difference between energy storage at (say) a coal plant and a wind
farm is that the coal plant stores its energy pre-generation (i.e. as
raw fuel) whereas a wind turbine has to convert its energy into a
non-electrical form after excessive generation in order to store it.
So the wind turbine has to convert its excess energy into some form
of fuel to be stored for later use. The coal plant simply does not
use the fuel until it is needed.
(by the way I am using
coal plant here because it is a good comparator – not because I am
a fan of coal generation – I prefer nuclear)
Typically the front
runners for renewable energy post generation fuel storage revolve
around two technologies:
- Pumped hydro (pumping water up hill into a reservoir)
- Or as is the fashion - in some form of Battery.
Pumped Hydro.
Pumped hydro is an old
and proven technology. It existed a long time before the current
wind/solar obsessions. Originally pumped storage facilities ( like
Dinorwig in Wales) were built to store energy when the price was low
(typically at night) and then sell that stored energy at peak demand
(when prices were high). Using this model, pumped hydro works very
well. It is a profitable and very worthwhile addition to the Grid.
But things change when
you try and use it to store excess solar and wind energy. You
essentially break the pumped hydro economic model, especially with
solar PV. (See Speigel Online article here )
You have to buy in
energy when prices and demand is high while sacrificing your
profitable market as well. Then you then have to sell on when prices
and demand is low.
It does not work. Even
if you created some subsidy regime to support this broken model, the number of potential
pumped hydro sites are very limited anyway.
But at least, individual pumped
hydro sites can store relatively large quantities of electricity.
Although UK pumped hydro could not deliver the energy quickly enough to actually take over the whole UK grid, they do hold enough energy to power the entire UK grid for about 1 hour.
Although UK pumped hydro could not deliver the energy quickly enough to actually take over the whole UK grid, they do hold enough energy to power the entire UK grid for about 1 hour.
While that may not
sound much, it is overwhelmingly better than any form of battery
storage.
When we get to battery
style storage the practicality and price viability of large scale
energy storage falls off a very high cliff.
Batteries
The biggest battery in
Europe is in Leighton Buzzard in the UK. It can store 10MWh of
electricity. It could (say) store half the output from a single small
10MW wind farm running at maximum output for two hours. It cost £20
Million. An average UK demand is around 30GWh. So this single
battery would power the entire UK grid for about 1.2 seconds.
OK, you may say – let
us distribute/duplicate it and use a cheaper technology After all why
not have a cheaper 10MWh battery for every (say) 5 wind turbines? You
know - Spread it out a bit.
Lets look at the
(arguably) most viable and cost effective large scale battery
technology available today – Vanadium Redox flow batteries.
(Incidentally - this is
VERY clever technology and has many potential applications – I am
not knocking the technology – only the application) .
Flow batteries store
the energy in the electrolyte. The consequence of this is that
theoretically the only limitation to the their storage capacity is
the amount of electrolyte you can to store.
Currently Vanadium Redox
batteries store about 20 Wh per litre of electrolyte. So for 10MWh
you need to store around 500,000 litres of highly corrosive Sulphuric
Acid based electrolyte.
Lets say technical
innovation decreases that by a factor of 10. You would still need to
pump/store/process 50,000 litres or nearly 100 tonnes of
electrolyte.
That is for 10 MWh. Or 1.2 seconds of nationwide
supply.
So, why not just store
more electrolyte? Simple eh?
But remember, this
stuff is lethal. It is massively corrosive and is a liquid. Then
remember this is one SMALL wind farm.
Multiply that by
thousands of wind farms. Then avoid killing anyone or regularly
risking massive environmental pollution. That really is a challenge!
Of course there are
other technologies (Lithium-ion being the other main and more
expensive player) but whatever you look at, the problems of large
scale energy storage are immense. They are effectively intractable.
Remember, what I have
discussed above is the LATEST and most promising technologies. On
Twitter people often eulogize about lead-acid batteries or compressed
air, but really their capabilities are far below pumped hydro or flow batteries.
But Tom Murphy on his appropriately named blog Do The Math has done a very good analysis of a theoretical (USA) National Lead Acid Battery and its practicalities On this Link
But Tom Murphy on his appropriately named blog Do The Math has done a very good analysis of a theoretical (USA) National Lead Acid Battery and its practicalities On this Link
A very interesting post on the EROEI (Energy Returned On Energy Invested) on storage with RE has been written by John Morgan On This Link
Large scale post
generation energy storage is not viable.
Bit even worse – not
only is it not viable, it is also potentially very, very (and
appallingly) dangerous.
But more on that in
another post.
(Here I am not
considering issues with charge/discharge rates, resource availability
or lifetime cycle expectancy – they all just make things worse)
