TCASE 7: Scaling up Andasol 1 to baseload

It might be difficult to find that much cooling water in a prime solar location in Australia ie a flat plain with snow capped mountains nearby. Even some outback coal fired stations like Kogan Ck are air cooled. I wonder if 15-20 Mw is the seen-to-be-doing something size as we’ll get that in Australia for planned wood fired, geothermal and solar ammonia plants.

If I’ve read this right the capital cost for 90% reliability is 2.4 X $2.50 = $6 per watt. At $2.50 just for summer load following we could possibility retrofit buildings for passive cooling at similar cost.

LikeLike

BNC linked to BBC climate change article
http://news.bbc.co.uk/2/hi/science/nature/8376286.stm

LikeLike

Professor Brook said… “The estimated energy yield is 178 GWh / year (I haven’t seen reports of actual performance data)”… chances are, you’re just going to have to get used to it.

Evidently, there seems to be a “data collection” problem inherent to solar generation technology… obtaining “actual performance data” (ditto costs) has been difficult to impossible for decades. It is the perennial complaint of those who have tried to present factually indisputable analysis of solar facilities in the past. Obviously, this isn’t a technical problem…

For those facilities that have (and do) publish their performance data, it always serves as a stark reminder of the limitations and feeble output of solar power (hence the chronic reluctance of the majority to “air their dirty laundry” in public). Perhaps Andasol 1 will be more forthcoming… I hope so. I am eager to see what the folks on this site will do with the information.

BTW – what was the construction time for this facility?

LikeLike

Cyril R.:

The smoke detectors in your house each have about 1 MICROcurie.

LikeLike

Relocating solar thermal to the Sahara may not improve the economics if you factor in security costs and new transmission. Remember that the Dakar car rally was moved to South America in 2008 over security concerns. Underwater HVDC cables to Europe might see the Saharans toasting their marshmallows with German lignite power if the economics aren’t right; something akin to that happened with Australia’s Basslink. Solar thermal is one of those energy sources that aims to create a glow, as in warm inner glow of its supporters.

LikeLike

@Cyril R: I’m not a convinced nuclear advocate, but I do want to point out that the LFTR design has a degree of inherent load-following capability. Higher demand means greater cooling of the inner fuel fluid, leading to higher density, leading to increased fission; and vise versa.

@Barry: Have you heard/evaluated the idea that the necessity of “baseload power” is partly mythical, because flattish baseload demand curves have been artificially promoted via discount pricing etc in order to match the demand to the inflexible fixed output of coal and traditional nuclear generators? Hypothetically, could we similarly reshape our demand curves to better suit an electrical grid with a greater proportion of solar generation?

LikeLike

Barry and a lot of people here probably have seen it already, but there are some good points about a solar thermal electric grid from David Mills:

Click to access ausra_usgridsupply.pdf

LikeLike

Barry, I realize that you’re trying to get an apples to apples comparison, but you simply won’t achieve that this way. For most cases it is not ultimately useful to consider ‘ability to meet baseload supply’, for example it is quite expensive to build single cycle gas turbines for baseload but they are usually very profitable in peaking. So why consider peakers in terms of being able to meet baseload? This is not where such technology excels in and so should not be compared on such requirements.

Indeed the very notion of baseload suggests that you have intermediate and peaking loads as well; you’re thinking in terms of typical fossil powered grid terminology.

I would like to point out that the average system capacity factor of all USA power generating plants is under 50%. Evidently 100% baseload would be impossible, you need a mix if you’re using a lot of baseload plants.

Interestingly it turns out that when properly sited (Mojave for the US) the highest correlation with grid load is around 50-60% capacity factor solar powerplants. So why go higher?

This fact is reflected in the pool pricing of electricity; the sales price is higher for load following than for a flat block of power (ie baseload). From an investor’s perspective, the internal rate of return becomes lower by going for baseload over load following (40-60% capacity factor or so).

Nuclear is best run constantly whereas renewables have varying degrees of variability. So we have different requirements here, especially if you don’t want to use a lot of carbon fuels, since then you’d want to limit fossil backup. Are we really going to run nuclear powerplants in the 5-30% capacity factor range (ie peaking)? They are highly unlikely to be competitive in such markets. One option is to have a baseload plant that dumps a lot of energy but this is wasteful and expensive (because of lost revenues). Another option is to install storage with a baseload plant. This is also expensive and adds material requirements. Such things need to be considered in a post carbon world, there are just too many gaps in a baseload comparison method for it too be justified IMHO.

LikeLike

Just barely on topic: unlike ammonium nitrate, sodium and potassium nitrates, as pure substances, are absolutely stable. The oxygen that is bound to the nitrogen has no lower-energy place to go. Mixing them with reducing agents can provide such a place.

Also, nitrate ion is naturally the form in which biologically fixed nitrogen spends part of its time, so the amount one eats, in vegetables, is surprisingly large.

(How fire can be domesticated)

LikeLike

Barry,

This post is excellent. You make it so clear. This sort of information must be cutting through.

The last paragraph of the part in yellow (the quote) is interesting. It says

“A fully loaded storage system can keep the turbine in operation for 7.5 hours, which means almost 24-hour operation of the power plant in during high sunshine periods”

That’s great for mid summer at latitudes where you would have 16.5 hours per when the sun is hot enough to generate power. I expect that requires at least 18.5 hours of sunlight per day, but more likely 20 hours of sunlight per day. What happens for the rest of the year. What happens in winter? Even the most optimistic projections for solar thermal do not forcast that solar thermal can provide baseload power – ie power on demand, 24/365, irrespective of how long the winter and how long are the longest periods of overcast weather over large areas.

LikeLike

Cyril R

Re #38351 I wonder if you can give me some figures or authoritative source in answer to these questions:

1. what are the capital cost ($/W) and energy cost for the solar plant with 40% to 60% capacity factor?

2. What is the availability of this plant to meet demand?

3. What is its availability to provide full-load generation on demand in mid-winter and throughought say 5 days of overcast weather?

LikeLike

Cyrl R,

You say:

“Barry, about the system perspective. One thing that you could do is look at the performance in terms of economics, materials, land use, water use, emissions etc. of a hypothetical 100% solar thermal grid, and compare it to a 100% nuclear grid.”

Something like you suggest has already been done on two other BNC threads:

Solar power realities – supply-demand, storage and costs

Solar realities and transmission costs – addendum

LikeLike

This is useful, just released today, on the Australian electricity market.

http://www.aer.gov.au/content/index.phtml?itemId=732297

LikeLike

DV82XL, as usual you’ve misinterpreted by position. The argument is simply one of methods, you have to compare real grid loads with load carrying capacity. If you are worried about natural gas use then you don’t want to build a baseload solar plant but a load following one since that reduces peaker natural gas use. There is no specious argument, I agree that storage and load control is easier and probably cheaper in a nuclear grid than in a solar grid. That does not excuse any of us from using fallacious methods like baseload normalization. I’ve made this point on various other blogs but most people react in a deliberately obtuse manner, some are agressively offended and miss the point altogether, others resort to their nuclear absolutism. This is not a discussion I wish to engage in because it is fruitless. I just like to see more studies that use realistic methods, that reflect real everyday concerns of grid operators and investors.

LikeLike

David Walters, Yes, nuclear can run in load following, though this is not ideal from a reactor operation and maintenance perspective (neutronics, poison buildup, and thermal cycling become worse) and it reduces the kWhs sold. I’m not saying it can’t be done, just that it has to be compared to other stuff like you say.

With a solar thermal plant, you start low in kWhs and actually increase that by adding storage. As long as the storage is cheaper than the turbine you can actually reduce the levelised cost of electricity, whereas with nuclear you’d be increasing it by going for a lower capacity factor, even if you can keep maintenance costs low (I have some concerns over this because of thermal cycling and varying radiation flux levels a couple of times per day).

Thermal storage is definately one that I’ve considered for a nuclear plant as well, though there are some complexities when doing this in a high temp reactor, it might be more practical to go for electric storage offsite such as pumped hydro or demand side storage in ice, hot water etc. But we’ll see about that, a combined baseload/peaker nuclear plant thermal storage system is definately a development that I encourage, the benefit is that the reactor can run full load all the time which is ideal. Using nuclear heat for a CAES system is also an interesting option, because it eliminates natural gas use.

LikeLike

Here’s the Sargent and Lundy cost trajectory estimates from NREL for CSP in the USA (Spain is more expensive since they have worse solar radiation and do not have as much experience with solar thermal as the US has)

Click to access 35060.pdf

If the deployment is met then this is plausible.

One major problem for CSP and nuclear in the US is that so little has been built in recent years, there is serious knowledge erosion and this has retarded the industry to quickly and effectively build powerplants. Combined with a more and more bureaucratic regulatory environment, the recent spike in materials and labor prices, and a weak US dollar, the power plant cost has inflated greatly…

LikeLike

Cyril R. – “DV82XL, as usual you’ve misinterpreted by position.”

I think not. You are a closet antinuclear agitator reduced to trying to flip firecrackers into everyone’s lap and I’m not impressed.

“That does not excuse any of us from using fallacious methods like baseload normalization. I’ve made this point on various other blogs but most people react in a deliberately obtuse manner, some are aggressively offended and miss the point altogether, others resort to their nuclear absolutism.”

That you would even consider using solar to supply peaking given its variability and unreliability demonstrates a laughable ignorance of how the electric power system works and to date I have seen nether reference or proof of your contentions about baseload and until such time I won’t give them any serious consideration. That is probably why no one else will ether.

“This is not a discussion I wish to engage in…”

What breathtaking arrogance and conceit. What makes you think that you can make whatever statements you want in a public forum like this and then demand that no one question them?

Frankly, to date I have found none of the things you have written here or in the other places our paths cross demonstrate any depth of understanding of the subjects you seem to think you are qualified to pass comment on. Has it occurred to you that this is the reason the stuff that you write is not given any more than passing consideration by others?

LikeLike

DV82XL, thanks for confirming my thoughts about you.

Peter Lang, the Sargent and Lundy firm has done analysis for fossil and nuclear power systems as well, they were chosen because of their independence to NREL. They’re a highly regarded engineering and consulting firm in power plants and power systems.

If yo look at studies for full external cost accounting for properly sited solar thermal electric, you’ll see its generally very low, much lower than coal. It’s uneconomic, but important to understand that there isn’t even one GWe of it today, so it’s a very immature industry.

There’s no need to bash David Mills ad hominem, it’s his methods for looking at correlation with annual loads that’s interesting here. See the paper on usgridsupply.

I’ve crunched the numbers on LCA and LCI, and concluded that when done right this is a much lower impact technology than coal will ever be. It’s almost as good as nuclear in fact.

If you want to see lifecycle studies, just google it! Indeed this thread has the NEEDS report referenced above, it has plenty of information for you.

LikeLike

Cyril R –

Coward.

Just like I said, you can only flip firecrackers into people’s laps, you can’t make a real defense of your position.

LikeLike

Peter

You might be interested in another EPRI report (page 2-2). It discussed two alternative scenarios for US emissions reductions over the period 2009 – 2025, with some interesting trends:

* Renewable 4% to 15% (starting NOW, mostly wind, ex. hydro)
* Nuclear 21% to 28% (starting ~2020)

I think that most observers not ideoligically wed to a particular solution (nuclear XOR renewables) would agree that a raft of solutions are required & that picking a single technology ‘silver bullet’ isn’t an option. The mix will vary country to country.

Nuclear has obvious CO2 benefits but also obvious problems, same for renewables. Thinking that these issues are all going to be resolved or massively scaled-up in the near term is willful ignorance.

I think advocating Nuclear for Australia is silly and demonstates no understanding of what is required to make this happen. If USA can’t bring online meaningful increases of Nuclear power in the short term, what chance does a Nuclear virgin like Australia have? I think you’re wasting your time argueing about it. Maybe down the track when those new reactors have been operating as fantastically as some suggest we’ll adopt it too. I say this because Japan & France had a go at fast breeders in the 90’s = expensive failure – of course new Gen 3/4 will be much improved. I think a wait & see approcah is appropriate for Australia before we leap in.

Nuclear is definitely a good fit for some countries in the short term. Just don’t underestimate NIMBY in Australia. We’re a conservative lot & for once we might be a the money.

Maybe I’ve got the wrong blog. This isn’t about climate change (SFA posts on COP15).

LikeLike

Dow A, First the Indians are having a go at liquid metal fast breeders and they seem to have cut their price dramatically. I say this even though I am not a fan of fast breeders and believe there are better options. In addition the Indians plan to operate their FBRs with a new fleet of thermal breeders. The whole Indian system is designed to cost far less than less advanced western nuclear technology, and Indian reactors are suitable for operation in less developed countries at a price that is competitive with coal. Of course Australia would not have the human capacity to operate such machines.

LikeLike

Dow A<

Thank you for the link to the EPRI report:

"The Power to Reduce CO2 Emissions: The Full Portfolio – 2009"

http://my.epri.com/portal/server.pt?Product_id=000000000001020389

This is not actuall the same report as I quoted. The report I quoted was:

EPRI, (2009) “Program on Technology Innovations: Integrated Generation Technology Options – November 2009,” gives the projected cost of electricity in 2025 from nuclear as US$75/MWh, from solar thermal as $225 – $290/MWh
http://my.epri.com/portal/server.pt?Product_id=000000000001019539

It is interesting to note that the cost of electrcity from solar thermal has increased by 30% in one year.

The price in the second link is $225/MWh. The price in the first link is $175/MWh. This price comes from the 2008 version of the first report above.

LikeLike

Dow cites a report on nuclear power building and states: For me, what gives this report credibility is that it quotes nuclear industry sources & was sponsored by the German government which already has a number of nuclear facilities.

The fact that a report on nuclear power comes from the German government should give you a red flag immediately that it’s probably bogus. Just beginning to read that that report you linked to, it’s clear from the get-go that it’s slanted against nuclear power, e.g. “At best, over the next two decades, Finland and France each will build one or two new reactors; China will
build an additional 20 plants…” Someone ought to tell the Chinese, who plan to build over 30 GW of new nuclear before 2020 acccording to this report. The rest of what I saw (admittedly I didn’t read the whole thing, seeing it’s obvious bias) was similarly slanted.

The German government publishes outright anti-nuke solar fantasy propaganda on their official government sites. Germany is a case of a country that has gone eco-correct to the point of denying reality as a matter of public policy. You may want to read this for a sample of how their economics and politics have been skewed to their great detriment. They do provide a wonderful model, though, for what NOT to do.

LikeLike

Hi Peter,

The projected cost rates for CSP are hardly set in stone. This technology is just starting to be deployed at large scales and no economies of scale or supply chain exist. Have a look at how wind has advanced since the 80’s to now where it is competitive. Over that time there was significant investment in technologies with multiple competing vendors bringing the costs down. It would be naive to suggest the same process will not make CSP more competitive. Lets not nail up the coffin of this technology just yet.

I would be more interested in your thoughts w.r.t the slow scale up of Nuclear even in the worlds greatest nuclear power (USA). For a technology that’s got ‘all the answers’ & been around collecting massive subsidies for so long, it seems a little sluggish to me.

Is there an explanation for this? I guess they don’t need to work around dissenting views in China – just stick one up wherever you want – maybe not a good role model for Australia though – NIMBY NIMBY NIMBY OI OI OI !.

I’ve said it before, Nuclear has a role to play, no doubt Australia will flog as much Yellow cake as possible to all suitable buyers. The world will see more Nuclear energy – it’s a reasonable choice for a country with those competencies, a willing public & limited other choices. Australia has no competencies, an unwilling public & other options to choose from.

LikeLike

Hi Tom,

You seem a little one eyed. The Merkel centre-right Democrats were re-elected in September this year with a clear majority. Most likely they will be extending the life of existing Nuclear power stations. Not typical for an evil propaganda organisation. Here’s link to a reputable information source:

http://www.timesonline.co.uk/tol/comment/leading_article/article6851531.ece

I tried to view the propaganda page that you linked (@ deplatedcranium.blog – fun name). The link to the German government page that offended your blogger didn’t exist, so it’s hard to comment further. The depletecranium blogger seems to talk lots about various crackpots & conspiracies around the globe – I can only assume he/she wasn’t the victim of misinformation. Do you have any other references that would backup your claim that;

“The German government publishes outright anti-nuke solar fantasy propaganda on their official government sites.”

I’m not dismissing your claim, it’s just that I’d like to see some reputable sources before taking on such information.

As for your query about the numbers in the report, I’ll see what I can find. In my experience, it is not common to add appendices of all source data to such reports. I do agree that this data should be able to be publicly verified. I’ll do my best to find out for you. The absence of this data should not be taken as proof of bias until proven – do you any competing data that invalidates this report?

While we’re talking about references, that Mineweb site you quoted didn’t provide any sources either – I’m sure they weren’t just talking up Uranium resources were they? I’d like to see the same information from an international nuclear industry organisation – could you oblige?

He’s the World Nuclear Industry Report 2009 link again, if anyone’s interested in validating/discrediting the actual data it contains. It’s full of references that I plan to check.

Click to access welt_statusbericht_atomindustrie_0908_en_bf.pdf

Thx for reading this far.

LikeLike

Hi Peter,

I’ve had a quick look at your write-ups. You lost me as soon as you started stacking up ALL (insert renewable) versus ALL NUCLEAR. It’s a classic FUD argument against renewable energy sources. Of course it will be very expensive to be 100% any SINGLE renewable source – their intermittence means you need lots of expensive redundancy. Try modelling multiple sources; PV, wind, CSP etc. This is that approach that electrical power engineers are using to determine an achievable penetration of renewable into the grid.

Nobody in the renewable industry would suggest such a singular approach – why do you? Are your write-ups open minded musings on the subject or point scoring for Nuclear?

Regarding subsidies, $/MWh your suggested ratio would hide the real numbers; $ and MWh discussed separately would show the full picture.

The $$$: Nuclear has received phenomenal amounts of money – it probably can’t be known for sure since for many countries their nuclear industry was an extension of their military programs & they don’t publish those numbers. (Insert renewable) every government grant to the renewable industries is published – because they have to be accountable (unlike nuclear state secrets).

The MWh: Nuclear has generated far more power than (insert renewable).

If you did the math it would probably look favourable toward poor little unsupported Nuclear. Looking at the raw numbers is a different story. They’re still putting their hands out in the US.

Don’t blame anti-nuclear agitators, the Nuclear industry screwed up, they used to be the darlings once upon a time:

1. Chernyoble – ‘nuf said.
2. Massive cost blowouts – what some recent links? Try EDF in France (the nuclear darlings), they can’t delivery on time or budget. Think Nuclear virgins like Australia will fare better?
2. Massive delays (as above).

Peter – you’re a geologist I understand, do you mind if I ask if you have any shares in uranium mining? Being an ardent nuclear supporter & a geologist I would think it a natural conclusion, but I didn’t want to make assumptions.

I’m happy to disclose that I’m an electrical engineer, with no share or interests in any energy or resource company.

LikeLike

DV82XL

I just used the search function in Acrobat reader. There’s plenty of ‘India’ references. Here’s a favourable one mentioning Indian successes with short delivery times – is it true or not?

“In contrast, it took five years on average to complete the ten units that were connected to the grid in China, India, Japan and South Korea.”

Here’s another, the Indian nuclear guru lamenting that lack of human resources – if he’s been misquoted, he should sue.

“The Indian nuclear executive Shreyans K. Jain, then newly elected President of the World Association of Nuclear Operators (WANO), stated in his acceptance speech in September 2007:
The key issues that demand world attention today, in my opinion, are those related to the ageing work force, ageing reactors, global increase in the fleet of nuclear power plants and probably, the hesitation of the younger generation to embrace this technology as a profession. It is also a fact that with the increased turnover of work force, the invaluable tacit knowledge, built up through years of experience, is steadily being lost. It is therefore absolutely essential for all of us to put on our thinking caps and evolve methods to tackle these serious issues.”

Look on page 90 among others for Canadian references. He’s a quote from the Canadian guru, saying the same thing as the Indian guru:

“The President of the Canadian Nuclear Safety Commission (CNSC) has stated that CNSC is “facing many of same issues as the rest of the nuclear industry”, including a 10% annual turnover and 23% of the workforce eligible to retire in the next five years”.

Don’t take my word for it, use the search function. If you disagree with the content, provide verifiable alternative sources. This way we’ll get to the truth without having to dismiss too many things off hand.

There may well be bias I just haven’t been able to verify it yet.

LikeLike

You are trying the tired tactic of attempting to change what I said. I did not write that the report contained no mention of Canada and India. I accused it of discounting their contributions by not using them as examples of how the problems the authors outlined can be solved.

As for the quotes about lack of skills, that is refrain that is playing in every technical sector at the moment, it is not something unique to nuclear energy, and will have just as large an impact in those areas as the Baby Boomer generation ages out of the work force.

LikeLike

Nice one, you’ve done a bit more research than normal.

Blue Ajah & DVXL – Do you have real names too? You’re brave posting links to me while hiding behind those names. If you are so sure about your viewpoints, why not stand by them?

I notice that you guys don’t usually answer question directly, but prefer your buddies to chip in. I was asking Peter a relevant question & was clear about my position – I don’t have any fiscal interest to declare, apart for a large HECs debt.

I have enjoyed studying these subjects. I’m not working in the industry, but I’m sure it will prosper & so will I. Anything untoward in there?

Thx for the free publicity, but I’d prefer if you didn’t publicise any other elements of my identity.

LikeLike

Dow A,

You’ve missed the point of the papers which use the ‘limit approach’ to allow you to see the wood in the trees.

Regarding subsidies, wind power is subsidised by at least 100% on the energy produced plus far more in funding for R&D and all the other perks it gets. Conversely, nuclear is not subsidised for production costs and gets far less per MWh or per MW than wind power. Just pulling numbers out of the air with out any basis on the amount of energy each produces is silly – or biased. Solar receives far more subsidies than even wind. Nuclear subsidises everything else, including coal in Germany!

You say “The $$$: Nuclear has received phenomenal amounts of money”. Yes, and it generates phenominal amounts of electricity, unlike renewables!! Adjectives are useless. Have you read David Mackay’s “Sustainable Energy 0 Without the hot air”?

Regarding nuclear stuffed up. Sorry, that is your opinion. I think the anti-nuclear ignoramuses (your predecessors) stuffed us all up.

Chernobyl was an industrial accident. On the scale of industrial accidents, the consequences are very small. Very small compared with the other energy chains. I accept that it was not handled well politically and publicity wise. But intelligent people should be able to get through the hype and understand the actual numbers. You can read the WHO report for yourself.

“Massive cost blow outs”. More adjectives. Compared with what? Compared with wind and solar? Take a look for yourself.

Your question about being a retired geologist and my share holdings is childish. What motivates you? But anyway, the answer to your question is no.

LikeLike

Hi Finrod, Blue Ajah, DV82XL (protector of the innocent), Peter, anybody else I’ve tussled with here,

It’s been fun but ultimately unrewarding… me spending time trying to track down credible expert sources to have them dismissed “as usual… (insert off hand dismissal about evil bias)”. I wish you luck on your quest & trust you are it because of a desire to abate climate change through any means possible. Please indulge a parting summary of my perspective. It’s only about Australia, the only country we have some small influence over:

1. Energy efficiency will save GHG in the short term – see McKinsey Report; An Australian Cost Curve for Greenhouse Gas Reduction for ideas.
2. In parallel we move on as many fronts possible to de-carbonise our economy – CCS, renewable energy etc.
3. Longer term electricity/H2 economy is the way to go.

You may see Nuclear in there, in Australia I doubt it. They just can’t get their shit together in a credible way – there’s enough evidence, a critical eye would tell you that – single exceptions don’t count, we need net industry competency, there’s not enough examples yet. Nuclear, if ever, will be decades away.

We didn’t talk about the fact that electricity is a small fraction of our energy needs. We’ll need biofuels & CNG/LPG fleets for transition, before you replace every vehicle with an electric one.

Well that’s what I think now. I like to keep abreast and revise my opinion when there is a sufficient body of evidence to justify it. Unfortunately, on this site, I found many pro-Nuclear pundits here have a profound inability to acknowledge ANY potential issues with Nuclear. You will find that anybody that has studied renewable energy will acknowledge the shortcomings. It’s in the textbooks & it gets discussed openly. We also discuss Nuclear – the pros & cons, unfortunately a number of you have only got one eye for the subject.

I can tell you it’s a turn-off, if you are trying to win people over. That’s obvious by the lack of diversity of voices here – just the cocksure & me – annoying you all, by questioning your conclusions.

Good luck gentlemen (apologies ladies, it’s hard to know).

Collectively I hope we achieve our goal.

Dow

LikeLike

I can tell you it’s a turn-off, if you are trying to win people over.

Yes, right, of course, ye of the open mind, whilst doing a “Masters in Renewable Energy” (whatever that is).

LikeLike

Hi DowA,

I think you’ll find Barry, and probably many of us here, agree with your three point perspective, though with nuclear replacing your hydrogen economy component. In fact, thats pretty much Barry’s sketch plan for transition to a zero carbon economy (time for an update, Barry, there’s been a lot of water under the bridge here since January).

Following your comment, I reread the recent comments here. It didn’t strike me that the responses to you were particularly unreasonable or dismissive (Finrod’s outburst aside). If people deliver their viewpoints with some confidence, thats probably because these discussion points have been well ventilated in the many thousands of comments on this site (and elsewhere), and these positions pretty thoroughly tested.

However, it does take some time to assimilate this information and its implications, especially if it involves a significant change to one’s thinking, and I think we’d do well to realize not everyone has been through that process. I have wondered how to shortcut that process for new readers, and I think thats partly what Barry is trying to do with his TCASE and IFAD series of posts.

I think Peter’s articles deserve more consideration than you’ve given them. Their point was not to prove you can’t power a whole grid with a single renewable source, and their conclusions – namely the high cost and even the ultimate feasibility of significantly reducing emissions with renewables – apply in broad sweep to combinations of these types of power source. There were over one thousand comments on these articles, most of it technical argument, and my view was that Peter’s argument held up to that storm. I think its a critically important part of the renewables story that is not widely appreciated, hence DV82XL’s comment on renewables being a Trojan horse for gas. It would be a disaster if we do a once in a generation build out of power infrastructure only to discover that it doesn’t abate GHG emissions, and doesn’t free us from a finite fossil fuel resource.

I agree that Australia will find a transition to a nuclear economy challenging, as we would be building an industry from scratch. The workforce issues are real. But its not impossible. Its a problem to be solved, not a show stopper.

While you obviously advocate renewable power sources, I note that you’re not close minded on nuclear. As such, I’m sure your comments here would be valuable. If you don’t comment further here, I likewise hope we achieve our goal of a zero carbon economy, and I hope you approach it with ruthless objectivity, as we’ve tried to do here,

regards,
john

LikeLike

Barry Brook, on December 17th, 2009 at 10.57 — The ethree study, commissioned by and for the State of California, listed the technologies in the order of busbar costs. You can find the link to the paper on the same SourceWatch page as well as elsewhere.

Similarly for the Lazard Ltd. study, which is linked on the SourceWatch page. I only choose SourceWatch because somebody else had; I know nothing more about the site.

Now I strongly suspect that Lazard Ltd. as did a commisioned study, just as ethree did. So it is probably the case that various powers-that-be are indeed paying attention to these.

As I understand the figures, no storage nor backup is included. Consider CCGT: storage is provided by the natgas pipelines and tanks, those costs are reflected only in the estimates of the price of the natgas; backup is not included at all, but is required since modern CCGTs have but 92% availablity.

And I didn’t “cherry-pick” either the ethree or the Lazard studies. I simply present the two as electrical energy cost studies to be taken with some seriousness. That even these two offer rather different prices for various technologies suggests to me that various local factors are being taken into account, as well as different estimation methods for the future of the prices for the different technologies.

Definitely makes it rather messy, but at least both of these studies agree that biogas is the lowest cost. So maybe we should be considering expanding that technology?

LikeLike

Cyril R,

Sorry, I forgot to add the two links. Here they are:

Click to access lang_solar_realities_v2.pdf

https://bravenewclimate.com/2009/09/10/solar-realities-and-transmission-costs-addendum/ .

LikeLike

It must also be repeated that ANY storage solution that will make renewables viable for short peaking can also be charged with surplus nuclear generated power.

For seasonal peaking some reactors like the CANDU 6 can operate continuously in the range from 100% to 60% of rated. These reactors can operate at steady-state at 60% power, and can return to full power in less than 4 hours.

Canada has seasonal loads as well.

LikeLike

If a week goes by in the winter when it’s cloudy, you’re doomed. Also, it uses way, way too much water, something very scarce in the desert. How would the workers get to work every day when 50,000 square miles of this stuff is in the desert? What is the EROEI?

LikeLike

Patrick,

Thank you for your contribution on solar thermal. The NREL (2003) report you have provided has a lot of information, but is a bit dated now. NEEDS (2008) supersedes this:

Click to access RS1a%20D12.2%20Final%20report%20concentrating%20solar%20thermal%20power%20plants.pdf

NEEDS (2008) considered four types of solar thermal power station and provided cost estimates for Solar Thermal Trough and Solar Tower. They concluded that Solar Tower was the more prospective option and provided more detailed cost projections for it. Even if Solar Tower does turn out to be cheaper than solar thermal trough eventually, there is no indication at this time that the difference will be substantial.

The NREL report was highly optimistic when written, and has proved to be so. This is demonstrated by the projection that 100 MW of solar tower capacity would be in operation by 2008, with 73.2% capacity factor and 13 hours of energy storage (Table 5-20). The estimated electricity costs appear to be too low by about a factor of four when compared with EPRI (2009).

This report is typical of the highly optimistic analyses and projections that have been presented by the solar power researchers for 20 years.

We still do not have any competitive bids for solar thermal power stations so we have no actual cost figures to use. If the researcher’s cost figures quoted here were even close to reality, commercially astute organisations would be building large solar thermal power stations all over the world. They are not.

The learning curves applied in analyses like this and NEEDS (2008) are not appropriate. A learning curve applies to the cost reductions that accrue when building many identical plants. This is not the case with solar thermal. Solar thermal is in the early stages of RD&D. Technology development would continue for decades, so every plant will be an advance on the previous one. Learning curve does not apply. The rate to apply is a technology development curve, not a learning curve. NEEDS projected a cost reduction of around 10% per year starting in 2007. However, the estimated the cost of electricity from solar thermal trough increased by 30% ($175/MWh to $225/MWh) between 2008 and 2009 (EPRI, 2008 and EPRI, 2009). This demonstrates that the learning curves applied are unrealistically optimistic. I give little credence to estimates for the cost of electricity in these reports.

Following are some brief responses to your comments (off the top of my head)

#1 The current grid runs at ~50% capacity factor in Australia and most black coal plants run around 50-65% Capacity Factor — have a look at Liddell(http://www.macgen.com.au/GenerationPortfolio/LiddellPowerStation.aspx), Eraring(http://www.eraring-energy.com.au/Uploads/Documents/2009%20ERARING%20ENERGY%20ANNUAL%20REPORT_20091201050109.PDF) etc — Do not confuse availability factor with capacity factor.

This point is irrelevant. It is not a fair comparison. The coal power stations have excess capacity to allow us to meet peek load, unscheduled and scheduled outages. The average capacity factor of around 50-65% you quote reflects this. The coal power stations run when ‘dispatched’ to do so by the grid operator. So of course their average capacity factor over a year is substantially less than their availability. As an aside, the entire fleet of nuclear power plants in the USA averages about 90% capacity factor.

The situation with solar thermal is that its capacity factor is constrained by the hours when the sun is hot enough to generate power (perhaps 5 to 6 hours in winter) and the hours of storage at the power station. It is important to cut through the solar advocates spin and ensure that we talk about the hours of hot sunlight in winter, not the average over the year. This is important if we are comparing the capacity factor of solar thermal with that of coal, as Patrick has done here. If we assume 6 generating hours per day in winter without storage, then the maximum capacity factor would be 25%. Add say 12 full load hors storage for maximum total generating time of 18 hours – or 75%. But it is nowhere near this high. The sun is not equally hot for the 6 hours of sunshine. So we have to decide what capacity is our generator. Is it based on the minimum heat output from the solar array for 6 hours per day, or a higher heat but for a shorter time? Also, we have to consider how many hours per year the plant will be under cloud cover and dust storms. Without going to far into this, whatever way we look at it, we cannot get 75% capacity factor from a plant with 112 hours of storage. The comparison of capacity factor for a base load coal fired power station and a solar thermal plant is not a valid comparison, until the solar thermal power station has sufficient energy storage for 24 h/d full load generation even under overcast conditions.

#2 No one in their right mind would scale up Andasol to 90% capacity factor unless they were in the tropics in an area with no cloud cover. Trough plants suffer projection losses due to lack of elevation tracking and therefore require more mirror field. Tower plants with heliostats do not have this problem.

Sorry Patrick. This is exactly want the NEEDS analysis does assume. It assumes 8000 hours of full load generation per year by 2020 for solar power stations located in the Sahara Desert – equivalent to our desert areas.

#3 What they would do is install a 24×7 Molten Salt Power Tower 50, 75, 100 or 220 and run it as a 75% capacity factor plant. As per the gold standard report on the subject from Sargent & Lundy LLC reviewing US DOE Sandia Laboratories and NREL Solar Programs and technologies.

This report is now 7 years out of date and superseded by the more recent NEEDS (2008) report.

#4 They would then add Air Cooling which would derate the Solar 220 by just 3MWe, so it’s NET output will be 217MWe

Yes to air cooling, but I expect the efficiency loss in practice would be more than you state. We would still need perhaps ten times more water for concrete during construction of the solar power station than a GEN III nuclear power station of equivalent output.

#5 Air Cooling drops water requirements for a molten salt tower by 88% and adds a minimum parasite (3MWe)

I can’t comment except to say I expect all the figures here are likely to be highly optimistic, given the statement from solar power advocates over the past 20+ years.

#6 Also I am reporting these figures as NET electricity to the grid – the actual plant is a Gross 245MWe plant. So the AP1000 also needs to be derated for its onsite parasitic electrical loads

All the figures in this paper are ‘sent out’ figures.

Click to access lang_2010_emissions_cuts_realities_v1a1.pdf

#7 Finally no one would run their 100% renewable grid with gas backup. For solar thermal plants geographical diversity will take care of most coincidence of cloud cover affecting output at mulitple sites over a few days. However a small contingency ~5 days of crop residual biomass would easily cover any uncertainty that the Solar Thermal power plant geographical diversity wouldn’t cover 365days 24×7.

OK, so not only do we need massive redundancy in the capacity of solar thermal power stations to cover for the worst periods of overcast conditions in winter which can extend over a large part of the continent for days at a time, we also need to duplicate the capacity with crop residual biomass generators. So we have the full cost of solar thermal plus the full cost of the biomass, with the latter having a low capacity factor and having to store crop for long periods to be ready for use when needed. Rough guess we are looking at electricity ten times the cost of coal or nuclear !!!

#8 Sargent and Lundy’s and US DOE cost projection for these plants is 5.0 cents per kilowatt hour (Adjusted for AU and 2010 dollars) after just 8700MW installed globally at just 2600MW installed 10cents per kilowatt hour, cheaper than todays nuclear power plants.

EPRI (2009) estimates the cost of electricity from solar thermal at 22.5 cents per kilowatt hour, or 4.5 times the cost you quoted. NREL is a renewable energy research organisation. EPRI has a reputation in the industry for reliable projections. I’d trust their figures as being far more reliable than NREL’s

Also note that the figure you quote here is for power when the power station wants to supply it, not for power on demand. For power on demand you need reliable back up.

#9 2PJ/400GWh Thermal primary biomass energy from 0.25% of the Australian wheat crop residual. will provide the 5 days backup for 1000MW worth of 24×7 Molten Salt Power Towers. To cover any unlikely 5 days a year of coincidence output from multiple geographically diverse solar sites.

Please give me the cost of electricity for this scheme. What are your assumptions for cost of fuel, fuel storage, capital costs, and capacity factor, etc.?

#10 Currently these proejcts are under construction
**Solar Reserve (Rocketdyne Subsidary — guys who put the Apollo rockets into space.)
100MWe@ 55% capacity factor Tonopah NV 150MWe@50% Rice Solar CA
50MWe@70% Alcazar de San Juan Spain
**SENER – the guys who built the working Nuclear plants in Spain (As opposed to the 6Billion Euro’s of Nukes that FAILED in Spains failure 70s and 80s nuclear program.) who have now moved onto Solar Thermal
17MWe@75% Torresol Gemasolar –
UAE – 50,75 and 100MWe plants to go ahead once Gemasolar is finished (JV partner with SENER in Torresol is Masdar Corporation)

These are all “Being built” and we have no figures. So it is all conjecture. The capacity is tiny.

Solar Thermal is at the RD&D stage of the technology life cycle. That is before the “Bleeding Edge” stage – see here: http://en.wikipedia.org/wiki/Technology_lifecycle

Technology Life Cycle:
From a layman’s perspective, the technological maturity can be broken down into five distinct stages.
1. Bleeding edge – any technology that shows high potential but hasn’t demonstrated its value or settled down into any kind of consensus. Early adopters may win big, or may be stuck with a white elephant.
2. Leading edge – a technology that has proven itself in the marketplace but is still new enough that it may be difficult to find knowledgeable personnel to implement or support it.
3. State of the art – when everyone agrees that a particular technology is the right solution.
4. Dated – still useful, still sometimes implemented, but a replacement leading edge technology is readily available.
5. Obsolete – has been superseded by state-of-the-art technology, maintained but no longer implemented.

LikeLike

Mathew Wright,

I look forward to the new report from the solar power advocates. I hope the projections are a lot more realistic this time.

LikeLike

That would provide a useful application for the depleted uranium that the government is trying to get rid of. Use it to make a 44,235 pound weight. The weight would be suspended at a height of 60 by a cable wound around a drum. When the power fails, the weight would turn the drum as it falls, thereby driving a generator. That would provide 1 KW of power for 1 hour. And, when the power returns, a motor would drive the drum to lift the weight back up to the height of 60 feet.

LOL! (I’m guessing this is parody…)

Cool. One whole hour of backup. That’s so much better a use for 20 tonnes of DU than the 20GW.Ye you could get from it using a fast breeder.

LikeLike