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Posts Tagged ‘energy

all renewable energy by 2050? Hang on a tick

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Sir David McKay, who died in 2016 of stomach cancer, aged 49. A great loss.

The late Sir David McKay, physicist, engineer, sustainable energy expert, Cambridge professor and Royal Society Fellow, has just become known to me through his 2012 TED talk and a lengthier exposition of the same ideas presented at Harvard. These talks were designed, to ‘cut through some of the greenwash’ and provide a realistic account of what can be done, on both the supply and the demand side, to reduce fossil fuel consumption and transform our energy economy.

As I need to keep saying, I’m far from an expert on this stuff, and I’m always impressed by the ingenious developments in the field and the promise of new technology, in batteries and other storage systems – like the compressed air underwater energy storage system being trialled in Lake Ontario, Toronto. But McKay’s contributions are helping me to think more realistically about the enormity of the problem of weaning ourselves from fossil fuels as well as to think more practically about my own domestic usage and the demand side more generally.

While McKay was no renewable energy sceptic or climate change denier, his ‘arithmetical’ view of the future poured a lot of cold hydro on the rosy idea that we’d be living in an all-renewables-powered biosphere within x decades. So I want to take a closer look at some aspects of what he was saying (he also wrote a highly-regarded book, Sustainable energy – without the hot air, available free online).

I particularly want to look at two forms of renewable energy that he talked about; wind and solar. He also talked at some length about two other energy sources, biofuels and nuclear, but I’ve never been much keen on biofuels, which in any case seem to have been largely taken off the menu in recent years, and nuclear, as McKay admits, has a popularity problem – a massive one here in Australia, unfortunately. What I say here about wind and solar will be gleaned largely fromMackay’s Harvard talk, but I’ve downloaded and plan to read his book in the near future.

Mackay has calculated that the current energy production of wind turbines in windy Britain is about 2.5 watts per square metre, and by multiplying per capita energy consumption by population density, you get power consumed per unit area, which for Britain is about 1.25 watts per square metre. This suggests that to cover the consumption of Britain solely by wind, you’d need an area, on land or sea, half the area of Britain. This is clearly not feasible, though of course nobody in Britain, I hope, was ever expecting to have all their energy needs provided by wind. The situation is vastly different for South Australia, two thirds of which is currently powered by wind. SA has vastly more land than Britain and vastly less people.

Though I’m sure it’s possible to quibble with Mckay’s figures and calculations, what he brings to the issues, I think, is a global, as well as a particular perspective that can be lost when you focus, as I have, on local success. For example, South Australia has been very successful in its deployment of wind power over a short period of time, and it’s easy to get carried away and think, if we can do it, why not state x or country y? But SA is a state with a small population and a very large area, and plenty of wind to capture. This just can’t be replicated in, say, Massachussetts, with more than three times the population, a thirtieth of the area, and little wind.

So McKay wasn’t offering global solutions, nor was he dismissing local ones. He was simply pointing out the complexity of the problem in physical and arithmetical terms of weaning ourselves from fossil fuels, as well as getting us thinking about our personal responsibilities on the demand side. Solar isn’t much of a national solution in Britain, though it could be in Australia, which could be a net exporter of renewables, as Elon Musk has suggested, but to which countries, and how exactly do you export solar energy? You’d need conversion and transmission and bilateral agreements. All of this while fighting entrenched interests and upsetting long-standing arrangements. Having said this, more people are hopping on the renewables bus and it’s almost becoming unfashionable, in most western countries outside of Australia, to be dismissive of them, a noticeable change in the last decade.

So what’s the point of this post? It’s to heed McKay’s advice that we need to recognise the complexity of the problem, to keep all possible reasonable solutions on the table, to become more aware, as individuals, communities and states, of our energy consumption, and to recognise that there’s never going to be a one-type-fits-all fix. Environments and needs vary widely, so we need to find particular solutions and we also need to find ways of joining and mixing those solutions together in effective networks. It all sounds pretty daunting, but the fact is, we’re already moving in the right direction, and there’s much to be positive about. Technology and engineering are international, and those in the business are hunting out solutions across the globe and thinking of harnessing and adapting them to their own region, in the process building communication, sharing information and expertise and raising consciousness about energy supply and consumption. And another positive is the endless innovation that comes with thinking about energy solutions in new ways, like small, cheap solar panels to provide energy in developing regions, backyard or small-scale wind-turbines in suitable locations, processing waste to fuel, new developments in batteries and EVs, and so on. So, while there aren’t major, mind-blowing solutions to our fossil-fuel dependence in the offing, we are making progress, incrementally, and the effects of climate change, as they become more impactful, will no doubt accelerate our progress and innovation. We have no option but to think and act positively.

portable solar panels can be surprisingly useful, and cheap

In a future post I’ll look at the demand side, following McKay and many others. Having just moved house, and sadly leaving solar panels behind, it’s time to find out where my meter is, and check our consumption.

 

On Trump’s downfall: Fire and Fury, the overly-discussed tell-all book about Trump and the White House, is unlikely to affect Trump’s base though it will hopefully toughen the opposition. Trump’s rating remains below 40% and nothing much has happened so far this year. There’s talk of Oprah Winfrey standing for the Presidency in 2020 – please no! – but Trump will be in jail by then and Americans will have lost their appetite for ‘celebrity’ candidates. I’m looking out for Elizabeth Warren.

Written by stewart henderson

January 11, 2018 at 9:03 am

the battery, Snowy Hydro and other stuff

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Let’s get back to batteries, clean energy and Australia. Here’s a bit of interesting news to smack our clean-energy-fearing Feds with – you know, Freudenberg, Morrison and co. The Tesla Big Battery successfully installed at the beginning of summer, and lampooned by the Feds, turns out to be doing a far better job than expected, and not just here in South Australia. Giles Parkinson reported on it in Renew Economy on December 19:

The Tesla big battery is having a big impact on Australia’s electricity market, far beyond the South Australia grid where it was expected to time shift a small amount of wind energy and provide network services and emergency back-up in case of a major problem.

Last Thursday, one of the biggest coal units in Australia, Loy Yang A 3, tripped without warning at 1.59am, with the sudden loss of 560MW and causing a slump in frequency on the network.

What happened next has stunned electricity industry insiders and given food for thought over the near to medium term future of the grid, such was the rapid response of the Tesla big battery to an event that happened nearly 1,000km away.

The Loy Yang brown coal fired power station is in south eastern Victoria, so why did South Australia’s pride and joy respond to a problem in our dirty-coal neighbouring state? It surely wouldn’t have been contracted to, or would it? Parkinson also speculates about this. Apparently, when a power station trips, there’s always another unit contracted to provide back-up, officially called FCAS (frequency control and ancillary services). In Loy Yang’s case it’s a coal generator in Gladstone, Queensland. This generator did respond to the problem, within seconds, but the Tesla BB beat it to the punch, responding within milliseconds. That’s an important point; the Tesla BB didn’t avert a blackout, it simply proved its worth, without being asked. And it has been doing so regularly since early December. It seems the Tesla BB has cornered the market for fast frequency control. Don’t hold your breath for the Feds to acknowledge this, but they will have taken note, unless they’re completely stupid. They’ll be finding some way to play it (or downplay it) politically.

As Parkinson notes in another article, the energy industry has been slow to respond, in terms of regulation and accommodation, to the deployment of battery systems and their rapid charge-discharge features. Currently, providing FCAS is financially rewarded, which may have to do with costs involved but the cost/reward relationship appears to be out of kilter. In any case, battery response is much more cost-effective and threatens the antiquated reward system. The AEMC is planning to review frequency control frameworks, but it’ll no doubt be a slow process.

This is an incredibly complex area, combining new, barely-understood (by me) technologies of generation and storage, and the transformation of long-standing energy economies, with a host of vested interests, subsidies and forward plans, but I intend to struggle towards enlightenment, as far as I can.

Neoen’s Hornsdale Wind Farm

Regardless of regulation and grid problems, renewable energy projects keep on popping up, or at least popping into my consciousness through my desultory reading (NY resolution: inform myself much more on what’s going on, here and elsewhere, in clean energy). For example, the Murra Warra wind farm’s first stage will have an output of 226MW,  which has already been sold to a consortium of Australian corporations including Telstra and ANZ. The farm is near Horsham in western Victoria, and will finally have a capacity of up to 429MW, making it one of the biggest in the Southern Hemisphere. And of course there are many other projects underway. Back in August, the Renewable Energy Index, a monthly account of the renewable energy sector, was launched. Its first publication, by Green Energy Markets, was a benchmark report for 2016-7, all very glossy and positive. The latest publication, the November index, shows that rooftop solar installations for that month broke the monthly record set in June 2012 when subsidies were twice to three times what they are today. The publication’s headline is that the 2020 RET will be exceeded and that there are ‘enough renewable energy projects now under development to deliver half of Australia’s electricity by 2030’. The Clean Energy Council, the peak body for Australian dean energy businesses, also produces an annual report, so it will be interesting to compare its 2017 version with the Renewable Energy Index.

Hydro is in fact the biggest clean energy provider, with 42.3% of the nation’s renewable energy according to the 2016 Clean Energy Australia Report. Wind, however, is the fastest growing provider. This brings me to a topic I’ve so far avoided: The $4 billion Snowy Hydro 2 scheme.

Here’s what I’m garnering from various experts. It’s a storage scheme and that’s all to the good. As a major project it will have a long lead time, and that’s not so good, especially considering the fast growing and relatively unpredictable future for energy storage. As a storage system it will be a peak load provider, so can’t be compared to the Hazelwood dirty coal station, which is a 24/7 base load supplier. There’s a lot of misinformation from the Feds about the benefits, eg to South Australia, which won’t benefit and doesn’t need it, it’s sorting its own problems very nicely thanks. There’s a question about using water as an electricity supplier, due to water shortages, climate change and the real possibility of more droughts in the future. There are also environmental considerations – the development is located in Kosciuszko National Park. There’s some doubt too about the 2000MW figure being touted by the Feds, an increase of 50% to the existing scheme. However, many of these experts, mostly academics, favour the scheme as a boost to renewable energy investment which should be applied along with the other renewables to transform the market. In saying this, most experts agree that there’s been a singular lack of leadership and common-sense consensus on dealing with this process of transformation. It has been left mostly to the states and private enterprise to provide the initiative.

 

With each post I’ll add something on the projected Trump downfall.

Just watched a CNN special report: The Trump Russia Investigation. It suggests to me that the notorious Trump Tower meeting, while nothing much in itself, is but a small piece of the growing case against Trump. It filled me in muchly on the much-discussed ‘dossier’ released just before Trump’s inauguration, the commandeering of Facebook by Russian operatives for a disinformation campaign, stirring up issues on immigration, gays, guns, etc, and much more. I still maintain that he won’t be in office by year’s end.

 

 

Written by stewart henderson

January 6, 2018 at 7:20 pm

more on Australia’s energy woes and solutions

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the SA Tesla Powerpack, again

Canto: So the new Tesla battery is now in its final testing phase, so South Australia can briefly enjoy some fame as having the biggest battery in the world, though I’m sure it’ll be superseded soon enough with all the activity worldwide in the battery and storage field.

Jacinta: Well I don’t think we need to get caught up with having the biggest X in the world, it’s more important that we’re seen as a place for innovation in energy storage and other matters energetic. So, first, there’s the Tesla battery, associated with the Hornsdale wind farm near Jamestown, and there are two other major battery storage systems well underway, one in Whyalla, designed for Whyalla Steel, to reduce their energy costs, and another smaller system next to AGL’s Wattle Point wind farm on Yorke Peninsula.

Canto: Well, given that the federal government likes to mock our Big Battery, can you tell me how the Tesla battery and the other batteries work to improve the state?

Jacinta: It’s a 100MW/129MWh installation, designed to serve two functions. A large portion of its stored power (70MW/39MWh) is for the state government to stabilise the grid in times of outage. Emergency situations. This will obviously be a temporary solution before other, slower reacting infrastructure can be brought into play. The rest is owned by Neoen, Tesla’s partner company and owner of the wind farm. They’ll use it to export at a profit when required – storing at low prices, exporting at higher prices. As to the Whyalla Steel battery, that’s privately owned, but it’s an obvious example, along with the AGL battery, of how energy can be produced and stored cleanly (Whyalla Steel relies on solar and hydro). They point the way forward.

Canto: Okay here’s a horrible question, because I doubt if there’s any quick ‘for dummies’ answer. What’s the difference between megawatts and megawatt-hours?

Jacinta: A megawatt, or a watt, is a measure of power, which is the rate of energy transfer. One watt equals one joule per second, and a megawatt is 1,000,000 watts, or 1,000 kilowatts. A megawatt-hour is one megawatt of power flowing for one hour.

Canto: Mmmm, I’m trying to work out whether I understand that.

Jacinta: Let’s take kilowatts. A kilowatt (KW) is 1,000 times the rate of energy transfer of a watt. In other words, 1000 joules/sec. One KWh is one hour at that rate of energy transfer. So you multiply the 1000 by 3,600, the number of seconds in an hour. That’s a big number, so you can express it in megajoules – the answer is 3.6Mj. One megajoule equals 1,000,000 joules of course.

Canto: Of course. So how is this working for South Australia’s leadership on renewables and shifting the whole country in that direction?

Genex Power site in far north Queensland – Australia’s largest solar farm together with a pumped hydro storage plant

Jacinta: Believe me it’s not all South Australia. There are all sorts of developments happening around the country, mostly non-government stuff, which I suppose our rightist, private enterprise feds would be very happy with. For example there’s the Genex Power solar, hydro and storage project in North Queensland, situated in an old gold mine. Apparently pumped hydro storage is a competitor with, or complementary to, battery storage. Simon Kidston, the Genex manager, argues that many other sites can be repurposed in this way.

Canto: And the cost of wind generation and solar PV is declining at a rate far exceeding expectations, especially those of government, precisely because of private enterprise activity.

Jacinta: Well, mainly because it’s a global market, with far bigger players than Australia. Inputs into renewables from states around the world – India, Mexico, even the Middle East – are causing prices to spiral down.

Canto: And almost as we speak the Tesla gridscale battery has become operational, and we’ve gained a tiny place in history. But what about this National Energy Guarantee from the feds, which everyone seems to be taking a swing at. What’s it all about?

Jacinta: This was announced a little over a month ago, as a rejection of our chief scientist’s Clean Energy Target. Note how the Feds again avoid using such terms as ‘clean’ and ‘renewable’ when it talks or presents energy policy. Anyway, it may or may not be a good thing – there’s a summary of what some experts are saying about it online, but most are saying it’s short on detail. It’s meant to guarantee a reliable stream of energy/electricity from retailers, never mind how the energy is generated – so the government can say it’s neither advocating nor poo-pooing renewables, it’s getting out of the way and letting retailers, some of whom are also generators, deliver the energy from whatever source they like, or can.

Canto: So they’re putting the onus on retailers. How so?

Jacinta: The Feds are saying retailers will have to make a certain amount of dispatchable power available, but there is one ridiculously modest stipulation – greenhouse emissions from the sector must be reduced by 26% by 2030. The sector can and must do much better than that. The electricity sector makes up about a third of emissions, and considering the slow movement on EVs and on emissions reductions generally, we’re unlikely to hold up our end of the Paris Agreement, considering the progressively increasing targets.

Canto: But that’s where they leave it up to the private sector. To go much further than their modest target. They would argue that they’re more interested in energy security.

Jacinta: They have a responsibility for providing security but not for reducing emissions? But it’s governments that signed up to Paris, not private enterprises. The experts are pointing this out with regard to other sectors. More government-driven vehicle emission standards, environmental building regulations, energy efficient industries and so forth.

Canto: And the Feds actually still have a renewable energy agency (ARENA), in spite of the former Abbott government’s attempt to scrap it, and a plan was announced last month to set up a ‘demand response’ trial, involving ARENA, AEMO (the energy market operator) and various retailers and other entities. This is about providing temporary supply during peak periods – do you have any more detail?

Jacinta: There’s a gloss on the demand response concept on a Feds website:

From Texas to Taiwan, demand response is commonly used overseas to avoid unplanned or involuntary outages, ease electricity price spikes and provide grid support services. In other countries, up to 15 per cent of peak demand is met with demand response.

Canto: So what exactly does it have to do with renewables?

Jacinta: Well get ready for a long story. It’s called demand response because it focuses on the play of demand rather than supply. It’s also called demand management, a better name I think. It’s partly about educating people about energy not being a finite commodity available at all times in equal measure…

Canto: Sounds like it’s more about energy conservation than about the type of energy being consumed.

Jacinta: That’s true. So on extreme temperature days, hot or cold – but mostly hot days in Australia – electricity demand can jump by 50% or so. To cope with these occasional demand surges we’ve traditionally built expensive gas-based generators that lie idle for most of the year. For reasons I’m not quite able to fathom, at such extreme demand times the ‘spot price’ for wholesale electricity goes through the roof – or more accurately it hits the ceiling, set by the National Energy Market at $14,000 per MWh. That’s just a bit more than the usual wholesale price, about $100/MWh. Demand management is an attempt to have agreements with large commercial/industrial users to reduce usage at certain times, or the agreements could be with energy retailers who then do deals with customers. Of course, bonuses could be handed out to compliant customers. The details of how this offsets peak demand usage and pricing are still a bit of a mystery to me, however.

Written by stewart henderson

December 9, 2017 at 9:07 pm

an assortment of new technology palaver

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I like the inset pic – very useful for the Chinese

Western Australia lithium mining boom

I’m hearing, better late than never, that lithium carbonate from Western Australia is in big demand. The state already provides most of the world’s lithium for all those batteries used to run smart devices, electric vehicles, and large-scale storage batteries such as South Australia’s Tesla-Neoen thingy at Jamestown (now 80% complete, apparently). Emissions legislation around the world will only add to the demand, with the French and British governments planning to ban the sale of petrol and diesel vehicles by 2040, following similar plans by India and Norway, and the major investments in EVs in China. Australia’s government, of course, is at the other end of the spectrum re EVs, but I’ve no doubt we’ll get there eventually (we’ll have to!). Tesla, Volvo, Nissan, Renault, Volkswagen and Mercedes are all pushing more EVs into the marketplace. So now’s the time, according to Money Boffins Inc, to buy shares in lithium and other battery minerals (I’ve never bought a share in my life). This lithium mining boom has been quite sudden and surprising to many pundits. In January of this year, only one WA mine was producing lithium, but by mid-2018 there will be eight, according to this article. The battery explosion, so to speak, is bringing increased demand for other minerals too, including cobalt, nickel, vanadium and graphite. Australia’s well-positioned to take advantage. Having said that, the amount of lithium we’re talking about is a tiny fraction of what WA exports in iron ore annually, but it’s already proving to be a big boost to the WA economy, and a big provider of jobs.

battery recycling

Of course all of this also poses a problem, as mentioned in my last post, and it’s a problem that the renewable energy sector should be at least ideologically driven to deal with: waste and recycling. Considering the increasing importance of battery technology in our world, and considering the many toxic components of modern batteries, such as nickel, lead acid, cadmium and mercury, it’s yet another disappointment that there’s no national recycling scheme for non-rechargeable batteries. Currently only lead acid batteries can be recycled, and the rest usually end up in landfill or are sent to be recycled overseas. So it’s been left to the industry to develop an Australian Battery Recycling Initiative (ABRI), which has an interesting website where you can learn about global recycling and many other things batterial – including, of course, how to recycle your batteries. Also, an organisation called Clean Up Australia has a useful battery recycling factsheet, which, for my own educational purposes I’m going to recycle here, at least partly. Battery types can be divided into primary, or single-use, and secondary, or rechargeable. The primary batteries generally use zinc and manganese in converting chemical to electrical energy. Rechargeable batteries use a variety of materials, including nickel cadmium, nickel metal hydride and of course lithium ion chemistry. Batteries in general are the most hazardous of waste materials, but there are also environmental impacts from battery production (mining mostly) and distribution (transport and packaging). As mentioned, Australian batteries are sent overseas for recycling – ABRI and other groups are trying to set up local recycling facilities. Currently a whopping 97% of these totally recyclable battery units end up in landfill, and – another depressing factoid – Australia’s e-waste is growing at 3 times the rate of general household waste. So the public is advised to use rechargeable batteries wherever possible, and to take their spent batteries to a proper recycling service (a list is given on the fact sheet). The ABRI website provides a more comprehensive list of drop-of services.

2015 registrations: Australia’s bar would be barely visible on this chart

EVs in Australia – a very long way to go

I recently gave a very brief overview of the depressing electric vehicle situation in Australia. Thinking of buying one? Good luck with that. However, almost all motorists are much richer than I am, so there’s hope for them. They’re Australia’s early adopters of course, so they need all the encouragement we can give them. Journalist Timna Jacks has written an article for the Sydney Morning Herald recently, trying to explain why electric vehicles have hit a dead end in Australia. High import duties, a luxury car tax and a lack of subsidies and infrastructure for electric vehicles aren’t exactly helping the situation. The world’s most popular electric car, the Nissan Leaf, is much more expensive here than in Europe or the US. And so on. So it’s hardly surprising that only 0.1% of all cars sold in Australia in 2015 were electric cars (compared with 23% and rising in EV heaven, aka Norway, 1.4% in France and 0.7% in the US). Of course Australia’s landscape’s more or less the opposite of compact, dense and highly urbanised Europe, and range anxiety might be a perennial excuse here. We have such a long way to go. I expect we’ll have to wait until shame at being the world’s laughing-stock is enough of a motivation.

Adelaide’s Tindo

I’ve been vaguely aware of Adelaide’s ‘green bus’ for some years but, mea culpa, haven’t informed myself in any depth up until now. The bus is called Tindo, which is a Kaurna aboriginal word meaning the sun. Apparently it’s the world’s first and only completely solar powered electric bus, which is quite amazing. The bus has no solar panels itself, but is charged from the solar panels at the Franklin Street bus station in the city centre. It’s been running for over four years now and I’m planning to take a trip on it in the very near future. I was going to say that it’ll be the first time I’ve been on a completely electric vehicle with no internal combustion engine but I was forgetting that I take tram trips almost every day. Silly me. Still, to take a trip on a bus with no noisy engine and no exhaust fumes will be a bit of a thrill for me. Presumably there will be no gear system either, and of course it’ll have regenerative braking – I’m still getting my head around this stuff – so the ride will be much less jerky than usual.

So here are some of the ‘specs’ I’ve learned about Tindo. It has a range of over 200 kilometres (and presumably this is assisted by the fact that its route is fixed and totally urban, so the regen braking system will be charging it up regularly). It uses 11 Swiss-made Zebra battery modules which are based on sodium nickel chloride, a type of molten salt technology. They have higher energy density, they’re lightweight and virtually maintenance free. According to the City of Adelaide website the solar PV system on the roof of the bus station is (or was – the website is annoyingly undated) ‘Adelaide’s largest grid-connected system, generating almost 70,000 kWh of electricity a year’. No connection to the ‘carbon-intensive South Australian electricity grid’ is another plus, though to be fair our grid is far less carbon intensive than Victoria’s which is almost all brown coal. South Australia’s grid runs on around half gas and half renewables, mostly wind. The regen braking, I must remind myself, means that when decelerating the bus uses no energy at all, and the motor electronically converts into an electrical generator, which generates electricity with the continued forward motion of the bus. There are many more specs and other bits of info on this Tindo factsheet.

battery technology and the cobalt problem

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The battery in my iPhone 6+ is described as a lithium polymer, or Li-ion polymer battery. I’m trying to find out if it contains cobalt. Why? Because cobalt is a problem.

According to this Techcrunch article, most of the world’s cobalt is currently sourced from Africa, especially the Congo, one of the world’s poorest countries. Child labour is regularly used in the mines there, under pain of beatings and other forms of coercion. The battery industry uses about 42% of global cobalt production, and the rest is used in a range of essential military-industrial applications.

Incidentally, this article from teardown.com blog goes deep inside the iPhone 6+ battery, showing that it uses lithium cobalt oxide (LiCoO2) for the cathode.

I can think of three possible ways out of this problem. 1. Stop sourcing cobalt from the Congo, or anywhere else that has exploitative labour practices. 2. Reform those labour practices, to improve the lives of the workers and provide them with a fairer share of the tech revolution profits. 3. Find an alternative to cobalt for batteries and other applications.

I didn’t say there were easy solutions haha. Anyway, let’s examine them.

An online Fortune article from March this year, which by the way confirms that cobalt is indeed used in iPhone and iPad batteries, reported that Apple has responded to investigative articles by Washington Post and Sky News by no longer buying cobalt from companies that employ child labour. Of course, even if we take Apple at its word – and considering that the Congo provides 60% of the world’s cobalt, and other African sources may have similar problems, how else will Apple be able to source cobalt cheaply? – the problem of Congolese child labour remains. The Washington Post report focused on a Chinese company, Zhejiang Huayou Cobalt Company, which purchases a large percentage of Congolese cobalt. It seems highly unlikely that such a company will be as affected by public or media pressure as Apple. However, there are some positive signs. A report in the Financial Times from a year ago, entitled ‘China moves to quell child labour claims in Congo cobalt mines’, says that China has launched a ‘Responsible Cobalt Initiative’ to improve supply chain governance and transparency. Whether this means applying solution 1 or solution 2 to the problem is unclear, but presumably it’s solution 2, and it really is a serious initiative, put forward by the Chinese Chamber of Commerce for Metals, Minerals and Chemicals Importers and Exporters, backed by the OECD and involving a number of international tech companies. Of course we’ll have to wait for reports on how this initiative is faring, and on whether these companies are concerned to improve the lives of cobalt miners or simply to ban the under-age ones while still paying very little to the remainder. Continued scrutiny is obviously necessary.

Of course, solution 3 would be of most interest to tech-heads (though presumably the effect on the Congolese economy would be terrible). According to this marketing article, there isn’t too much cobalt available, and the demand for it is increasing sharply. One problem is that cobalt isn’t generally mined on its own as ‘primary cobalt’ but as a byproduct of copper or nickel, and both of these metals are experiencing a worldwide price plunge, with many mines suspending activities. Also the current supply chain for cobalt is being dominated by Chinese companies. This could have a stifling effect especially on the EV revolution. Governments in advanced countries around the world – though not in Australia – are mandating the adoption of electric vehicles and the phasing out of fossil-fuel-based road transport. The batteries for these vehicles all contain cobalt.

In the TechCrunch article mentioned above, journalist Sebastien Gandon examines the Tesla situation. The company has a target of 500,000 vehicles a year by 2018, with cobalt sourced exclusively from North America. On the face of it, this seems unrealistic. Canada and the US together produce about 4% of the world’s cobalt supply, and  acccording to Gandon the maths just doesn’t add up, to say the least. For a start, the mining companies Tesla is looking to rely on are not even operational as yet.

However, there are a few more promising signs. The Tesla model S has been using high energy density nickel-cobalt-aluminium-based (NCA) battery cells, which have a lower cobalt content than the nickel-manganese-cobalt (NMC) batteries of most other companies. There is also the possibility of adopting lithium-iron-phosphate (LFP) chemistry, or lithium-manganese-oxide (LMO), neither of which use cobalt, though their lower energy density is a problem. In any case, battery technology is going through a highly intensive phase at present, as I’ve already reported, and a move away from cobalt has become a distinct possibility. Nickel is currently being looked at, but results so far have been disappointing. There are certainly other options in the offing, and cobalt itself, which unlike oil is completely recyclable, could still be viable with greater focus. It isn’t so much that it is scarce, it’s more that, in the past, it hasn’t been a primary focus, but mining it as a primary source will require substantial upfront costs, and substantial time delays.

So, all in all, it’s a problematic future, at least in the short term, for vehicles and technologies using cobalt-based battery systems. We can only wait and see what comes out of it.

Written by stewart henderson

October 28, 2017 at 12:55 pm

the tides – a massive potential resource?

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A floating tidal turbine, Orkney islands, as seen on Fully Charged

A recent episode of Fully Charged, the Brit video series on the sources and harnessing of clean energy, took us again to the very windy Orkney Isles at the top of Scotland to have a look at some experimental work being done on generating energy from tidal forces. When you think of it, it seems a no-brainer to harness the energy of the tides. They’re regular, predictable, unceasing, and in some places surely very powerful. Yet I’ve never heard of them being used on an industrial scale.

Of course, I’m still new to this business, so the learning curve continues steep. Tide mills have been used historically here and there, possibly even since Roman times, and tidal barrages have been operating since the sixties, the first and for a long time the largest being the La Rance plant, off the coast of Brittany, generating 240 MW. A slightly bigger one has recently been built in Korea (254 MW).

But tidal barrages – not what they’re testing in the Orkneys – come with serious environmental impact issues. They’re about building a barrage across a bay or estuary with a decent tidal flow. The barrage acts as a kind of adjustable dam, with sluice gates that open and close, and additional pumping when necessary. Turbines generate energy from pressure and height differentials, as in a hydro-electric dam. Research on the environmental impact of these constructions, which can often be major civil engineering projects, has revealed mixed results. Short-term impacts are often devastating, but over time one type of diversity has been replaced by another.

Anyway, what’s happening in the Orkneys is something entirely different. The islanders, the Scottish government and the EU are collaborating through an organisation called EMEC, the European Marine Energy Centre, to test tidal power in the region. They appear to be inviting innovators and technicians to test their projects there. A company called ScotRenewables, for example, has developed low-maintenance floating tidal turbines with retractable legs, one of which is currently being tested in the offshore waters. They’re designed to turn with the ebb and flood tides to maximise their power generation. It’s a 2 MW system, which of course could be duplicated many times over in the fashion of wind turbines, to generate hundreds if not thousands of megawatts. The beauty of the system is its reliability – as the tidal flow can be reliably predicted at least eighteen years into the future, according to the ScotRenewables CEO. This should provide a sense of stability and confidence to downstream suppliers. Also, floating turbines could easily be removed if they’re causing damage, or if they require maintenance. Clearly, the effect on the tidal system would be minimal compared to an estuarine barrage, though there are obvious dangers to marine life getting too close to turbines. The testing of these turbines is coming to an end and they’ve been highly successful so far, though they already have an improved turbine design in the wings, which can be maintained either in situ or in dock. The design can also be scaled down, or up, to suit various sites and conditions.

rotors are on retractable legs, to protect from storms, etc

Other quite different turbine types are being tested in the region, with a lot of government and public support, but I got the slight impression that commercial support for this kind of technology is somewhat lacking. In the Fully Charged video on this subject (to which I owe most of this info), Robert Llewelyn asked the EMEC marketing manager whether she thought tidal or wave energy had the greatest future potential (she opted for wave). My ears pricked up, as wave energy is another newie for me. Duh. Another post, I suppose.

As mentioned though in this video, a lot of the developments in this tidal technology have come from shipbuilding technology, from offshore oil and gas technology, and from maritime technology more generally, as well as modern wind turbine technology, further impressing on me that skills are transferable and that the cheap clean energy revolution won’t be the economic/employment disaster that the fossil fuel dinosaurs predict. It’s a great time for innovation, insight and foresight, and I can only hope that more government and business people in Australia, where I seem to be stuck, can get on board.

fixed underwater tidal turbine being tested off the Orkney Islands

Written by stewart henderson

October 11, 2017 at 6:27 am

stand-alone solar: an off-grid solution for Australia’s remote regions (plus a bit of a rant)

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According to this article, Australia is leading the world in per capita uptake of rooftop solar, though currently South Australia is lagging behind, in spite of a lot of clean energy action from our government. The Clean Energy Regulator has recently released figures showing that 23% of Australians have installed rooftop solar in the last ten years, and this take-up is set to continue in spite of the notable lack of encouragement from the feds. South Australia is still making plenty of waves re clean energy, though, as it is continually lowering its record for minimum grid demand, through the use of solar PV. The record set a couple of days ago, interestingly on Sunday afternoon rather than in the middle of the night, was 587MW, almost 200MW less than the previous record set only a week or so before. Clearly this trend is set to continue.

It’s hard for me to get my head around what’s happening re disruptive technologies, microgrids, stand-alone solar, EVs, battery research and the like, not to mention the horribly complex economics around these developments, but the sense of excitement brought about by comprehensive change makes me ever-willing to try. Only this morning I heard a story of six farming households described as being ‘on the fringe of Western Australia’s power network’ who’ve successfully trialled stand-alone solar panels (powered by lithium-ion batteries) on their properties, after years of outages and ‘voltage spikes’*. The panels – and this is the fascinating part – were offered free by Western Power (WA’s government-owned energy utility), who were looking for a cheaper alternative to the cost of replacing ageing infrastructure. The high costs of connecting remote farms to the grid make off-grid power systems a viable alternative, which raises issues about that viability elsewhere given the decreasing costs of solar PV, which can maintain electricity during power outages, as one Ravensthorpe family, part of the trial, discovered in January this year. The region, 500 kilometres south of Perth, experienced heavy rain and flooding which caused power failures, but the solar systems were unaffected. All in all, the trial has ‘exceeded expectations’, according to this ABC report.

All this has exciting implications for the future, but there are immediate problems. Though Western Power would like to sign off on the trial as an overwhelming success, and to apply this solution to other communities in the area (3,000 potential sites have been pinpointed), current regulation prevents this, as it only allows Western Power to distribute energy, not to generate it, as its solar installations are judged as doing. Another instance of regulations not keeping up with changing circumstances and solutions. Western Power has no alternative but to extend the trial period until the legislation catches up (assuming it does). But it would surely be a mistake not to change the law asap:

“You’d be talking about a saving of about $300 million in terms of current cost of investment and cost of ongoing maintenance of distribution line against the cost of the stand-alone power system,” Mr Chalkley [Western Power CEO] said.

Just as a side issue, it’s interesting that our PM Malcolm Turnbull, whose government seems on the whole to be avoiding any mention of clean energy these days, has had solar panels on his harbourside mansion in Point Piper, Sydney, for years. He now has an upgraded 14 kW rooftop solar array and a 14kWh battery storage system installed there, and, according to a recent interview he did on radio 3AW, he doesn’t draw any electricity from the grid, in spite of using a lot of electricity for security as Prime Minister. Solar PV plus battery, I’m learning, equals a distributed solar system. The chief of AEMO (the Australian Energy Market Operator), Audrey Zibelman, recently stated that distributed rooftop solar is on its way to making up 30 to 40% of our energy generation mix, and that it could be used as a resource to replace baseload, as currently provided by coal and gas stations (I shall write about baseload power issues, for my own instruction, in the near future).

Of course Turnbull isn’t exactly spruiking the benefits of renewable energy, having struck a Faustian bargain with his conservative colleagues in order to maintain his prestigious position as PM. We can only hope for a change of government to have any hope of a national approach to the inevitable energy transition, and even then it’ll be a hard road to hoe. Meanwhile, Tony Abbott, Turnbull’s arch-conservative bête noir, continues to represent the dark side. How did this imbecilic creature ever get to be our Prime Minister? Has he ever shown any signs of scientific literacy? Again I would urge extreme vetting of all candidates for political office, here and elsewhere, based on a stringent scientific literacy test. Imagine the political shite that would be flushed down the drain with that one. Abbott, you’ll notice, always talks of climate change and renewable energy in religious terms, as a modern religion. That’s because religion is his principal obsession. He can’t talk about it in scientific terms, because he doesn’t know any. Unfortunately, these politicians are rarely challenged by journalists, and are often free to choose friendly journalists who never challenge their laughable remarks. It’s a bit of a fucked-up system.

Meanwhile the ‘green religionists’, such as the Chinese and Indian governments, and the German and Scandinavian governments, and Elon Musk and those who invest in his companies, and the researchers and scientists who continue to improve solar PV, wind turbine and battery technology, including flow batteries, supercapacitors and so much more, are improving their developments and disrupting traditional ways of providing energy, and will continue to do so, in spite of name-calling from the fringes (to whom they’re largely deaf, due to the huge level of support from their supporters). It really is an exciting time not to be a dinosaur.

 

Written by stewart henderson

September 20, 2017 at 9:32 pm