World’s Largest Wind Farm Attracts Huge Backing From Insurance Giant
The title of this post, is the same as that of an article in the Business pages of yesterday’s copy of The Times.
It is not often that three words implying something big appear in the same sentence, let alone a headline! Such repetition would more likely appear in a tabloid to describe something sleazy.
Until recently, wind power was just something used by those in remote places. I remember a lady in Suffolk, who had her own turbine in the 1980s. She certainly lived well, although her deep freeze was in the next door farmer’s barn.
Now, with the building of the world’s largest wind farm; Hornsea, which is sixty miles off the coast of East Yorkshire, wind farms are talked of as creating enough energy for millions of homes.
Hornsea Project 1 is the first phase and Wikipedia says this about the turbines.
In mid 2015 DONG selected Siemens Wind Power 7 MW turbines with 154 metres (505 ft) rotor turbines for the project – around 171 turbines would be used for the wind farm.
Note that the iconic Bankside power station, that is now the Tate Modern had a capacity of 300 MW, so when the wind is blowing Hornsea Project 1 is almost four times as large.
When fully developed around 2025, the nameplate capacity will be around 6,000 MW or 6 GW.
The Times article says this about the funding of wind farms.
Wind farms throw off “long-term boring, stable cashflows”, Mr. Murphy said, which was perfect to match Aviva policyholders and annuitants, the ultimate backers of the project. Aviva has bought fixed-rate and inflation-linked bonds, issued by the project. While the coupon paid on the 15-year bonds, has not been disclosed, similar risk projects typically pay an interest rate of about 3 per cent pm their bonds. Projects typically are structured at about 30 per cent equity and 70 per cent debt.
Darryl Murphy is Aviva’s head of infrastructure debt. The article also says, that Aviva will have a billion pounds invested in wind farms by the end of the year.
Call me naive, but I can’t see a loser in all this!
- Certainly, the UK gets a lot of zero-carbon renewable energy.
- Aviva’s pensioners get good, safe pensions.
- Turbines and foundations are built at places like Hull and Billingham, which sustains jobs.
- The need for onshore wind turbines is reduced.
- Coal power stations can be closed.
The North Sea just keeps on giving.
- For centuries it has been fish.
- Since the 1960s, it has been gas.
- And then there was oil.
- Now, we’re reaping the wind.
In the future, there could be even more wind farms like Hornsea.
Ease Of Funding
Large insurance companies and investment funds will continue to fund wind farms, to give their investors and pensioners a return.
Would Aviva be so happy to fund a large nuclear power station?
Large Scale Energy Storage
The one missing piece of the jigsaw is large scale energy storage.
I suspect that spare power could be used to do something useful, that could later be turned into energy.
- Hydrogen could be created by electrolysis for use in transport or gas grids.
- Aluminium could be smelted, for either use as a metal or burnt in a power station to produce zero-carbon electricity.
- Twenty-four hour processes, that use a lot of electricity, could be built to use wind power and perhaps a small modular nuclear reactor.
- Ice could be created, which can be used to increase the efficiency of large gas-turbine power plants.
- Unfortunately, we’re not a country blessed with mountains, where more Electric Mountains can be built.
- Electricity will be increasingly exchanged with countries like Belgium, France, Germany, Iceland, Norway and The Netherlands.
There will be other wacky ideas, that will be able to store GWhs of electricity.
These are not wacky.
Storage In Electric Vehicles
Consider that there are three million vehicles in the UK. Suppose half of these were electric or plug-in hybrid and had an average battery size of 50 kWh.
This would be a total energy storage of 75,000 MWh or 75 GWh. It would take the fully developed 6GW Hornsea wind far over twelve hours to charge them all working at full power.
Storage In Electric And Hybrid Buses
London has around 8,500 buses, many of which are hybrid and some of electric.
If each has a 50 kWh batttery, then that is 425 MWh or .0.425 GWH. If all buses in the UK were electric or plug-in hybrid, how much overnight electricity could they consume.
Scaling up from London to the whole country, would certainly be a number of GWhs.
Storage In Electric Trains
I also believe that the average electric train in a decade or so could have a sizeable battery in each coach.
If we take Bombardier they have an order book of over four hundred Aventra trains, which is a total of nearly 2,500 coaches.
If each coach has an average battery size of 50 kWh, then that is 125 MWh or 0.125 GWh.
When you consider than Vivarail’s two-car Class 230 train has a battery capacity of 400 kWh, if the UK train fleet contains a high-proportion of battery-electric trains, they will be a valuable energy storage resource.
Storage in Housing, Offices and Other Buildings
For a start there are twenty-five million housing units in the UK.
If just half of these had a 10 kWh battery storage system like a Tesla Powerwall, this would be a storage capacity of 125 GWh.
I suspect, just as we are seeing vehicles and trains getting more efficient in their use of electricity, we will see buildings constructed to use less grid electricity and gas.
- Roofs will have solar panels.
- Insulation levels will be high.
- Heating may use devices like ground source heat pumps.
- Battery and capacitors will be used to store electricity and provide emergency back up.
- Electric vehicles will be connected into the network.
- The system will sell electricity back to the grid, as required.
Will anybody want to live in a traditional house, that can’t be updated to take part in the energy revolution?
Will The Electricity Grid Be Able To Cope?
National Grid have been reported as looking into the problems that will happen in the future.
- Intermittent power from increasing numbers of wind and solar farms.
- Charging all those electric vehicles.
- Controlling all of that distributed storage in buildings and vehicles.
- Maintaining uninterrupted power to high energy users.
- Managing power flows into and out of the UK on the various interconnectors.
It will be just like an Internet of electricity.
And it will be Europe-wide! and possibly further afield.
Conclusion
The UK will have an interesting future as far as electricity is concerned.
Those that join it like Aviva and people who live in modern, energy efficient houses will do well.
The Silent Transport Revolution
Today, I rode in two battery-powered modes of transport.
Returning from Kings Cross, I was a passenger in one of London’s new black cabs; the LEVC TX.
Earlier in the day, I’d ridden in a battery-powered version of the Class 230 train.
Both vehicles are quieter than diesel-powered versions, as is to be expected.
But what surprised me about the Class 230 train today, is that you can have a normal conversation in the train without raising your voice. The D78 trains from which the Class 230 train has been developed, weren’t that quiet.
The Class 379 BEMU, that I rode in three years ago, was also quiet.
I came back from Scotland in a Standard Class Mark 4 Coach, which was also quiet, but it is a trailer without motors and probably plenty of sound-proofing.
Does the design of a battery-electric vehicle with regenerative braking reduce the noise and vibration emitted?
The Class 230 train has an electrical system based on DC batteries and AC traction motors. So there must be aone very clever heavy electronics to manage the power. So there is orobably little in the electrical system to make the clatter one typically hears on a train. The train obviously has a mechanical brake for emergencies and to bring the train to a funal halt, but that was not used in anger on our short trip.
Clean Drivers To Sport Green Numberplates
The title of this post is the same as that as an article on page 11 of today’s Sunday Times.
The first paragraph gives a few more details.
Electric and hydrogen-powered cars, vans and taxis may be awarded green numberplates in a public display of virtue.Chris Grayling, the transport secretary, said giving clean vehicles a “green badge of honour” was a “brilliant way of helping increase awareness” ans “might just encourage people to think about” getting one themselves.
I think it’s a good idea and apparently Norway, Canada and China have green plates.
I like it as it would be easier to spot a battery taxi, which are so much nicer than the older models.
Jesse Norman, a junior Government minister is also thinking about tax breaks for e-Bikes and for ecargobikes for “last mile” deliveries.
First Sighting Of A Battery Taxi
London is getting battery taxis. They are officially called LEVC TX.
I took these pictures from the back platform of a New Routemaster bus.
It certainly looks good from the front. And I’ll try one when I can!
I have a feeling that, because it looks right, the early adopters will do well, as punters will want to give it a try.
If it is reliable and the costs stack up for the drivers, I think it could sell well.
This is a review of the LEVC TX.
If it ends up in large numbers on the streets of London and other British cities, it may actually start a substantial move to electric vehicles.
Imagine coming into St. Pancras on Eurostar and then you and your family take an electric taxi home to Hampstead, Kensington or like me, to Dalston! Will your kids, badger you to get an electric car, because it is good for the environment and so cool?
I don’t know! But electric taxis could be the advertising for all electric vehicles!
Existing EVs Could Steer Energy To 300,000 Homes
The title of this post, is the same as this article on the Utility Week web site.
This is the opening two paragraphs.
Existing electric vehicles (EVs) in the UK could contribute more than 114MW to the National Grid, enough to power over 300,000 homes.
Research commissioned by Ovo Energy suggests the figure could be achieved based on the current 19,000 Nissan Leaf EVs registered in the UK using new vehicle-to-grid (V2G) chargers.
The article goes on to discuss this in detail.
So what is vehicle-to-grid?
Wikipedia has this summary.
Vehicle-to-grid (V2G) describes a system in which plug-in electric vehicles, such as electric cars (BEV), plug-in hybrids (PHEV) or hydrogen Fuel Cell Electric Vehicles (FCEV), communicate with the power grid to sell demand response services by either returning electricity to the grid or by throttling their charging rate.
Vehicle-to-grid can be used with gridable vehicles, that is, plug-in electric vehicles (BEV and PHEV), with grid capacity. Since at any given time 95 percent of cars are parked, the batteries in electric vehicles could be used to let electricity flow from the car to the electric distribution network and back. This represents an estimated value to the utilities of up to $4,000 per year per car.
If you are thinking about buying an electric car or van, read the article and other sources. Wikipedia seems a good start.
At its simplest, it would appear that if you buy an electric vehicle, it would be prudent to fit a V2G charger in your garage or parking space.
I would expect, that the charging system is sophisticated, so that if you want to use the car, there is sufficient charge and the power hasn’t been sold back to the grid.
It will be very interesting to see how this technology develops.
The Anonymous Widower 