Renewable Energy Breaks UK Record In First Quarter of 2020 (theguardian.com) 87
Renewable energy made up almost half of Britain's electricity generation in the first three months of the year, with a surge in wind power helping to set a new record for clean energy. The Guardian reports: The government's official data has revealed that renewable energy made up 47% of the UK's electricity generation in the first three months of the year, smashing the previous quarterly record of 39% set last year. The government's renewable energy data includes electricity from the UK's windfarms, solar panels and hydro power plants as well as bioenergy generated by burning wood chips instead of coal. The "substantial increase" in the UK's total renewable energy output was chiefly driven by a growth in electricity generated by solar panels and windfarms which climbed by more than a third over the last year, according to the government's energy analysts.
The report added that the start up of new windfarms combined with the UK's unusually wet and windy weather at the start of the year -- particularly storms Ciara, Dennis and Jorge -- helped to generate record wind power generation. Offshore windfarms powered the largest increase in renewable energy in the first quarter of the year, climbing by 53% compared with the previous year, while onshore wind generation grew by a fifth. In total, wind power generated 30% of the UK's electricity in the first quarter, beating the previous record of 22.3% set in the final months of 2019.
The report added that the start up of new windfarms combined with the UK's unusually wet and windy weather at the start of the year -- particularly storms Ciara, Dennis and Jorge -- helped to generate record wind power generation. Offshore windfarms powered the largest increase in renewable energy in the first quarter of the year, climbing by 53% compared with the previous year, while onshore wind generation grew by a fifth. In total, wind power generated 30% of the UK's electricity in the first quarter, beating the previous record of 22.3% set in the final months of 2019.
Well that was annoyingly easy (Score:1)
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Because it is not wrecking the planet, and the thing that is not wrecking the planet is not that readily fixable as the article headline suggests, and if this wind power thing is as cost effective as it is touted, we won't be doing this thing that is not wrecking the planet..
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Your edgy analysis omits the fact that there is a lot of power and money at stake in maintaining the status quot; you can't control and monopolize renewable energy, so you can't use it to leverage nations and make yourself stupidly wealthy with it.
THAT is why we continue to do the thing that wrecks the planet...
=Smidge=
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so you can't use it to leverage nations and make yourself stupidly wealthy with it.
Yes, I am sure that Nigeria or Venezuela or Saudi Arabia can as easily build high-efficiency photovoltaic cells and wind turbines as they pump up petroleum. /s
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Why are we headed towards wrecking the planet for something that is actually fixable?
The first 47% is the easiest.
Also, counting the wood chips is bogus because they aren't that clean. They are grown in America, consuming fossil fuels in the process, then pressed into pellets (consuming more fossil fuel), shipped across the Atlantic on fossil fuel power freighters, transported to the power plants in fossil fuel powered trucks, and then burned with ~30% thermodynamic efficiency.
Even if burning wood chips made sense, it would be way more cost-effective to burn them in America (which shares a
Re:Well that was annoyingly easy (Score:5, Informative)
"Base Load" is the minimum output of a power plant before it has to be turned off completely. If you don't meet the base load you don't get anything at all. At some point the idea of base load has been perverted into a defense of fossil energy, claiming that there is some inherent baseline demand that must always be met... but it only needs to be met because with traditional power plants you wouldn't get anything without that minimum. It's entirely artificial and based on the nature of the production, rather than the consumption, of energy.
The reality is power is fungible. It's true that solar is intermittent (though HIGHLY predictable) as is wind (also very well forecast), but these are also non-dispatchable sources; You either use the power when it's available or you lose it.
What you need to cover those gaps is not "base load" power, but dispatchable power: power that you can bring online on demand. Out of all the traditional power plants (coal, oil, nuclear, natural gas, hydro) only hydro and natural gas are considered dispatchable. In fact, non-dispatchable plants like nuclear actually make things *worse* for renewables: it forces renewable energy to shut down to avoid overproduction, because nuclear power can't reasonably be shut off.
So what you need to do; Have your solar and wind, which will provide a large chunk of the power you need when you need it. Supplement this with dispachable renewables: Hydro, solar-thermal storage and geothermal. You can then add traditional storage; Pumped hydro, compressed gasses, hydrogen, chemical batteries, point-of-use thermal storage, etc. (Those last two are the easiest to deploy widely distributed, and are actually optimal under that deployment strategy)
It works. [archive.org] [PDF warning]
=Smidge=
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And it is a natural evolution of generation for natural gas to be progressively relegated to being dispatched power only as the share of wind and solar come to dominate. The plants are already built, we just run them less and less, then only when there are gaps in the wind and solar supply. This takes us up to about 80% renewable (along with long distance power distribution, maximized use of opportunistic power consumption, etc.) before we need to start replacing the gas entirely with something else.
Re: Well that was annoyingly easy (Score:3)
For decades Switzerland has been about 60% hydro and 40% nuclear, for example. It works quite well, with nuclear covering the core needs (and even pumping water uphill if the needs go lower) then hydro doing the extra. But the nuclear plants are getting very old, and their licenses will not be renewed. So now what... land-based wind farms supposedly destroy tourism, there is no off-shore in a landlocked country, solar is highly variable and at industrial scale needs land (plus we are pretty far north). I wo
Re: Well that was annoyingly easy (Score:3)
Doesn't Switzerland have quite a few mountaintops above the clouds? That means guaranteed full solar power across the day. If industry products are manufactured while these solar panels are active...?
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https://psmag.com/environment/... [psmag.com]
Totally.
Also noted: "Of course, Kahl notes, the study doesn't address all of the potential hurdles to installing solar arrays in the mountains, including social acceptance, economics, logistics, and existing infrastructure—because the cost of installing solar panels in remote, rugged terrain and getting that energy onto the grid could outweigh the benefits. But Kahl is cautiously optimistic."
Mostly that people like unspoiled mountains without solar installations all ov
Re: Well that was annoyingly easy (Score:4, Interesting)
For decades Switzerland has been about 60% hydro and 40% nuclear, for example. It works quite well, with nuclear covering the core needs (and even pumping water uphill if the needs go lower) then hydro doing the extra. But the nuclear plants are getting very old, and their licenses will not be renewed. So now what... land-based wind farms supposedly destroy tourism, there is no off-shore in a landlocked country, solar is highly variable and at industrial scale needs land (plus we are pretty far north). I wonder if nuclear will be re-examined when it comes down to it.
I can't be sure about whether nuclear will be reconsidered - I'm guessing that's more a strategic question, but Switzerland has the advantage of being at the physical centre of the European grid. They can buy electricity when it's cheap (during high wind and / or strong sunshine) and sell it when it's expensive. Wind energy tends to come from the North West of Europe and be will be needed in the South and East for air conditioning. Solar tends to come from the South and East (remember large areas of Sunny Africa are within reasonably easy reach of Europe) and will be needed for heating in the North. Industry is all over but much of the most important areas are within striking distance of Switzerland in France and Germany. If Switzerland invests in major interconnection in all directions and battery storage so that they can react faster than hydro and corner the market in usage spikes (use the Hydro to ensure that the batteries are always full) they can probably do pretty well even with limited local power generation possibilities.
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Switzerland is actually planning to become the central power hub of Europe - building more hydro storage.
They already have lots of interconnects to the surrounding countries.
Unlike popular believe: most southern european countries don't have much AC.
Classical architecture is in a way that AC is not needed. That might change with climate change, though.
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Your definition of base load power is wrong.
Base load power is the minimum amount of power that needs to be delivered to the electrical grid over time. The size of the base load is the minimum amount of power people and businesses want to use over some period of time. It basically the troughs of the graph of power usage
The word "load" is the clue.
I don't know where you got your definition of base load from, but it's just plain wrong.
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Your definition of base load power is wrong. Base load power is the minimum amount of power that needs to be delivered to the electrical grid over time. The size of the base load is the minimum amount of power people and businesses want to use over some period of time. It basically the troughs of the graph of power usage The word "load" is the clue. I don't know where you got your definition of base load from, but it's just plain wrong.
Here I was thinking on a AC Power Grid the 'load' is nearly instantaneous and supply and demand for Electricity has to be matched almost perfectly for it to work https://en.wikipedia.org/wiki/... [wikipedia.org]
and No Base load is not about power people and business want over a period of time there are several definitions for it but it generally refers to the demand needed to keep Coal fired Powerplants running.
https://www.abc.net.au/news/sc... [abc.net.au]
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From your link:
"[Base load] refers to the minimum level of output that these big power generators could go to, before they turned off."
It has nothing to do with demand. They could run at base load and pump all their power straight into a space laser. They just can't run at less than base load. Your sentence literally just rephrased itself.
Demand only dictates if it makes sense to run at base load.
Also I like in their analysis they would still have to use gas-fired plants. Oh, but bio-fuel! No problems
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From your link:
"[Base load] refers to the minimum level of output that these big power generators could go to, before they turned off."
It has nothing to do with demand. They could run at base load and pump all their power straight into a space laser. They just can't run at less than base load. Your sentence literally just rephrased itself.
Demand only dictates if it makes sense to run at base load...
Did you even read the article or skim through it ? I will rephrase the first part of the article , The reason why 'baseload' is so important to Coal fired power plants is that if they don't have enough demand the power plants switch off,
power plants that take days and cost millions of dollars to start up again.
Also I like in their analysis they would still have to use gas-fired plants. Oh, but bio-fuel! No problems there!
I will give you that one its a bit of a crutch. ;-)
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Then your article is wrong.
You never have power demand below base load, unless you have a grid failure somewhere.
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Then your article is wrong.
You never have power demand below base load, unless you have a grid failure somewhere.
hmmm your source for this definition of base load please ?
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Source: working for + 10 years in power companies.
But you can read up here:
https://en.wikipedia.org/wiki/... [wikipedia.org]
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"Base Load" is the minimum output of a power plant before it has to be turned off completely
without Coal fired Powerstations there would be no need for the term baseload. Now in the article I linked we have two very distingished professors in their fields who are saying the same thing, could they be wrong ?
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They just can't run at less than base load. Your sentence literally just rephrased itself.
They can. But they usually don't.
As you have a "fleet of power plants", base load plants usually run at around 95% max capacity.
If one fails the others ramp up a bit.
The only thing distinguishing fossile base load plants from others is that they are cheaper and run on cheaper fuel - otherwise you can just dispatch them like any other plant. They are only slower (because that is cheaper).
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That is actually not the definition of base load.
You have a load curve over a typical day (changes during seasons).
The lowest point in that curve - and the area below it: that is base load.
You can fulfill that demand with base load plants that run 24/7 all year: that is base load.
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That is actually not the definition of base load.
You have a load curve over a typical day (changes during seasons).
The lowest point in that curve - and the area below it: that is base load.
You can fulfill that demand with base load plants that run 24/7 all year: that is base load.
The problem with this definition is everyday it would change and Why would you want to produce a minimum amount 24/7 even at times when their is no need? and more importantly What happens when there is no demand?
The last question is what Coal fired power stations have to deal with and make sure there is an enough demand to keep the power stations running and their solution
was to make sure that there was always a minimum demand which they called the 'base load' and this is why we have 'off peak' devices
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Smart grids and micro grids are also coming to the party which will displace the traditional power plant. The key is local electricity generation and storage. Solar farms and wind farms are more friendly to populations than coal, gas and nuclear plants. Electric cars are also coming with new technology of vehicle to grid which allows the car to power the home and to sell the electricity back to the grid for profit. Domestic solar can be added and suddenly the home can become self-sufficient for certain peri
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The National Grid (UK grid controller) actually considers wind to be one of the most reliable sources, more reliable than nuclear or fossil. Reason being that a single turbine failure has a small impact, not gigawatts suddenly dropping off the grid. Therefore it needs less standby reserve.
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"Base Load" is the minimum output of a power plant before it has to be turned off completely.
No, it is not.
Base Load is a grid term and not a power plant term. It is the valley in the load curve over a day, that is base load.
Out of all the traditional power plants (coal, oil, nuclear, natural gas, hydro) only hydro and natural gas are considered dispatchable.
That is wrong, all of those are dispatchable. Only the speed of reaction varies.
it forces renewable energy to shut down to avoid overproduction, becau
Re:Well that was annoyingly easy (Score:4, Informative)
Exactly, renewables do not solve the base load problem.....
Without Coal there is no 'base load problem' as the term base load means the minimum power generation needed to keep the Coal powered generators running.
https://www.energymatters.com.... [energymatters.com.au]
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Indeed. To mesh with renewables you need flexible peakers, which are the opposite of "base load".
But much of the problem can also be solved with flex-pricing. Cut the price when surplus power is available, and jack up the price when supply drops. Plenty of customers will adapt. Many refrigerated warehouses already pre-chill at 4am when power is cheap and "coast" through the afternoon when demand peaks.
My home AC compressor is attached to my smart meter and will automatically shutoff if there is a power
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No, it does not.
It is the minimum demand of the grid.
Has nothing to do with power plants at all.
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No, it does not.
It is the minimum demand of the grid.
Has nothing to do with power plants at all.
Huh? ummm can you quote your source for this please? Thats the original term for baseload as Coal fired power stations will switch off when there is too low a demand.
Re: Well that was annoyingly easy (Score:3)
Coal is taking carbon from millions of years ago and releasing it into the atmosphere today. Wood chips take carbon from a few years ago and allow for a closed loop. (plant, grow, collect, burn, repeat) Wood chips arenâ(TM)t perfect but they are not the same as coal.
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Re: Well that was annoyingly easy (Score:4, Informative)
So don't burn the wood chips, and it doesn't release CO2 into the atmosphere. In fact, you could sequester that wood into abandoned coal mines. There is zero environmental difference between 5 year old carbon and million year old carbon.
If you put wood into old coal mines then you have to ensure that they stay dry so that the wood doesn't rot. Coal doesn't do that which means that maintaining coal underground forever is much easier than wood. The carboniferous period occurred before fungi had developed the ability to digest lignin and the same conditions will never occur again.
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The money going into wood chips would be far better spent on more wind or solar.
It would be. But the companies burning wood chips would be stuck with a woodchip burning generator not making any money.
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They said we would never get above 15% renewables or it would destabilize the grid and the lights would go off. They were wrong.
As renewables keep growing there will be more and more money to be made from interconnection and storage. The problem resolves itself through economics, driven by policy.
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In Ireland around 65 to 70% can be renewable currently, there are also interconnectors between countries which help theres a 1000MW between 2 interconnectors between the Ireland of Ireland and mainland UK Theres around 3000MW between the English South Coast and Mainland Europe. Current system demand in Ireland is 3763 MW and 2784MW of that is being generated with Wind the interconnectors are exporting 487MW.
There is also demand side generation and response, and battery systems which can provide fast freq
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The biomass money would be better spent on grid electricity storage technologies and domestic electricity storage systems (micro grids).
The humble domestic gas boiler is going extinct this decade for new buildings in the UK. Electric domestic heating needs to get ready to fill in the gap. Cheap off-peak electricity can be stored at home in a big lithium-ion battery (14kWh and higher) during the night or when there is too much renewables. This battery can then power the electric domestic heating during the d
A few reasons (Score:3, Informative)
There are a few reasons this wasn't mostly solved 40 years ago. It could have been. A few things got in the way. Mostly it's all about the mix. Providing the world's energy needs, in a way that actually works to provide you power, and without costing $80,000/year per household, requires a flexible mix of different sources and strategies. Being a fan of one thing is basically a vote to stick with coal, because whatever your "one thing" is, it won't work by itself.
In particular, the solar-electric industr
Ps the eye is logarithmic (Score:4, Informative)
Maybe I should have mentioned, your eye perceives brightness in log scale. That's so you can see both outdoors at noon and by candlelight.
When I mentioned a 1,000 mile system of making the whole country cloudy, you might think "the sun is only half as bright when it's cloudy - the sun is still there". You might say the same about evening time, or morning. What your eye perceives as "half as bright" is more like 90% less light because your eye perceives brightness logarithmically.
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You may be correct about the power of the wind vs. speed, but your calculations regarding the amunt of power extracted by turbines are off. This is because turbines have a maximum power output and they feather th
Guess what the speed is? (Score:2)
>> Within each cyclone itself there were wind speeds well over 100 MPH, but across the UK it was 50 MPH or whatever.
> > Because the power is the CUBE of speed, a 50 MPH wind has sixteen times as much power as 20 MPH wind. That's a lot of power.
> your calculations regarding the amunt of power extracted by turbines are off. This is because turbines have a maximum power output and they feather the blades to stop the generation
Yep, and guess what the max speed is for most turbines, tje speed at w
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"Rated speed" for most turbines is 25-35mph. I don't know where you get the number 59.23, except for the record speed (in knots) that a sailboat reached (note: it was probably travelling faster than the wind).
So the calculations in your rant about power that wind turbines extract are wrong, because you put the wrong numbers into it.
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You are trying to change the subject. We aren't talking about the speed at which it achieves nameplate power rating.
We're talking about the wind speed at which "they feather the blades to stop the generation". That speed is, most commonly, 26.5 m/s. Aka 59 MPH. Siemens puts out some good information about their turbines if you'd like to look at more details.
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We started by talking about how your calculations are wrong. You are now diverting from that.
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Dude, it's okay to learn something new, really.
When someone tells you something, like the speed setting, "oh, interesting" is a perfectly good reply.
By trying to pretend you already knew everything, here's what we ended up:
Me: Wind speed was 50 MPH over a large area. 50 MPH wind has 16x the power as 20 MPH wind
You: You're wrong! Turbines shut down in high winds
Me: What speed do you think they shut down at? (Hint 59)
You: 25-35mph
By fighting SO hard against learning anything because you wanr to act like you'v
Ps - see our thread about the Korean war (Score:2)
Ps I think our thread about the Korean war is a good example of a useful and enjoyable conversation. Would you agree?
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This thread started because you misrepresented what I wrote.
What I wrote:
"This is because turbines have a maximum power output and they feather the blades to stop the generation exceeding this. "
How you quoted this and then misrepresented it:
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Let's start over, because maybe you're trying to something different than what I think you're trying to say.
I said they make a lot more power at 50 MPH than they do at 20 MPH.
You replied "your calculations regarding the amunt of power extracted by turbines are off. This is because turbines have a maximum power output and they feather the blades to stop the generation exceeding this."
You then started talking about nameplate power at 23-35MPH.
Are you under the impression that the maximum power they can genera
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Are you under the impression that that power output of wind turbines increases with wind speed until the turbines shut down at their max wind speed? If so, please review the graphs below and tell me at what wind speed the max power output is reached.
Hint: it is a lot lower than 50mph.
https://www.researchgate.net/p... [researchgate.net]
https://electricalacademia.com... [electricalacademia.com]
https://www.windpowerengineeri... [windpowerengineering.com]
https://i.ytim [ytimg.com]
Thanks! (Score:2)
Thanks for that info. Much appreciated.
Now I'm kinda wondering what's going on. I'm pretty sure the sample data I looked at from Siemens had the curve going up much further to the right. Which makes sense, because the available power isn't just a little more, it's a LOT more. I'm wondering if what I looked at is just outdated or if it was an unusual design or what. My best, most likely guess is I was looking at a design that was new at the time and not actually produced in quite that way.
I wonder what eng
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I assume that the cost of the generator is very closely related to the power output. Thus, planning for high winds adds a lot to the cost, but most of the time (when the winds are normal) this extra capacity isn't used.
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I imagine that it's economics. To build out all the devices in the power chain to be productive and reliable above 24kmph, with adequate longevity, might be cost-prohibitive.
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....One last thing. It's very easy to confuse energy and electricity. You hear that the UK (a cold country) got a significant percentage of its ELECTRICITY from whatever I a given month and sometimes you are encouraged to forget that's a tiny fraction of the ENERGY. They heat their houses, their hot water, etc by burning oil and gas (over 80% of UK homes) and some wood. Just home heating is 11% of UK CO2 and that energy isn't considered when you see a reference to "percent of their electricity".
UK (a mild country) could very easy do away with the need to burn oil by doing what other European country's are doing with better insulation and Geothermal heating.
https://www.greenmatch.co.uk/g... [greenmatch.co.uk]
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Re:A few reasons (Score:4, Interesting)
When I first switched to 100% renewable energy it cost about 10% more than fossil. Now it's considerably cheaper, in fact sometimes the electricity prices go negative and I'm paid to consume it.
Every year as people compare energy suppliers to reduce their bills more and more are switching to renewable only because it's cheaper.
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Check out Octopus and their Agile tariff.
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It doesn't even make sense - even if there is "too much" energy, you should be charged something for the depreciation of the lines to get it to you and the infrastructure in general.
In any case, too much energy should always just bottom at "free" - and then excess profits in a publicly owned utility should go back to ALL subscribers - instead paying you for no reason to burn energy for no reason.
Also, if renewables were really always cheaper as Ami thinks, no one would be having this conversation. I'm on t
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A record output -- that is the problem (Score:2, Interesting)
That wind power achieved a record contribution to electric demand over a 3-month period is the problem with it.
It has a seasonal variation that is very hard to counteract with battery or even pumped storage.
Re:A record output -- that is the problem (Score:5, Informative)
But is easy to counteract with solar energy, which is highest in the months when wind is lowest (June, July and August) [ox.ac.uk].
In fact when you look on UK renewable charts that is what you see, a pretty flat production of renewable energy (wind plus solar) [googleusercontent.com] across the entire year.
Re:A record output -- that is the problem (Score:4, Funny)
I'm sorry but I was assured that if renewables ever exceeded 15% of generation the entire grid would collapse and we would be plunged into a second Dark Age. Reality must be wrong!
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You're in complete denial, you said that like it'd be impossible to do and 'it's a problem'.
The actual fact is this happened and it is not a problem, it's a good thing.
Renewable or Non-Carbon? (Score:2)
It is that latter that counts.
The difference is nuclear, of which the UK has quite a bit.
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47% renewable and another 15% nuclear on top. And the vast majority of the rest was gas. Coal was under 4%. It was right there at the top of the article for you to read
When you're burning wood chips... (Score:2, Troll)
Re: When you're burning wood chips... (Score:4, Informative)
The tree grow/burn cycle is short and shouldn't (averaged over the course of a few decades) contribute to the amount of atmospheric CO2. But the tree/coal lifecycle is long - releasing CO2 that can't immediately be returned to coal. Unless averaged over thousands of years - which is bit of a problem given our more immediate climate concerns.
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That is actually simple to explain.
Dead trees regrow.
Dead coal does not.
I guess you grasped that car analogy.
So hurry up and smelt some steel this week! (Score:2)
When the wind dies down again, you can go back to baking artisanal bread for the village in your solar ovens.
Good news for global warming (Score:1)
Thanks Scotland! (Score:3, Informative)
Scotland, with 8% of the UK population creates more than 25% of the UK's renewable energy, exporting around 28% of its generation. Renewable energy now makes up over 90% of annual Scottish generation with a target to reach 100% by the end of this year. Wales is pulling its weight, with around 50% of consumption coming from renewable energy. Northern Ireland gets 45% of its consumption from renewable energy. The remaining country in the union only publishes UK figures. ;-)
Re: Thanks Scotland! (Score:3)
I worked on quite a few Scottish wind farms. Its windy and there is lots of land! Most of the labour was from the Midlands and Northern England however as there isn't that many Scottish Engineers these days... Its a shame as they blazed the way during the enlightenment! I think you will find it's the same with the capital and debt that finances these projects too which was something the Scottish pioneered! :)
Nuclear power (Score:2)
Nuclear power is the only practical way forward. It is safe, reliable, and inexpensive. Low-cost electricity is essential to human health and development. Existing nuclear power plants should continue to be operated. Recently closed, but not yet dismantled plants, should be retrofitted with newer technology and brought back online. Breeder reactors should be built, in order to turn nuclear waste into fuel. SMR (Small Modular Reactors) should be embraced by markets and governments and brought towards regulat
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You must be stuck in the fifties, Nuclear is not cheap. AFAIK "turn nuclear waste into fuel" is horrendously expensive. Fusion is probably 60 years away and the complexity involved means it'll likely never be a cheap form of power, complexity is expensive.
Wind power is sticking a motor on a stick attached to a turbine, you can't beat that for simplicity. Solar is even more simple, a slab off material that converts sunlight into electricity, you can't beat that for simplicity either.
Solar and wind can provid