Breaking the model

I was just reading a blog post about the world solar energy market over at Go Green Solar.  Good short post about which countries have the most solar PV and why.  Here’s the summary image of the article:

Installed PV by Country - 2007

Keep in mind that this doesn’t include Solar Thermal, which would change the US and Spanish shares of this chart somewhat.  The fact remains that right now, economics rule solar.  Expensive electricity + Incentives = Booming Solar Industry.

But there’s nothing set in stone about this model.  Electricity prices are going up, the cost of solar is coming down, and the old energy sources are becoming more volatile.  So the current electrical generation model, and the “energy crisis” that politicians love to talk about is very real in the sense that changes are coming, and big ones.  The current subsidies all flow to oil and coal right now, with nuclear and hydro-electric dams getting a meaningful chunk of cash too.

What makes solar and other renewables is that they have the power to break the current model, and soon enough, can break it with or without the subsidies that it’s so clearly dependent on.  That’s what makes our current project at Morgan Solar so exciting – we want to be one of the first companies (but by no means the only one) that crosses that subsidy barrier.

We want to be making solar power systems that cost less than the electricity they produce, and we think we can do it in the next year or two.  Breaking the model entirely, and shaking up the system.  How cool is that?

Also, for those people in Toronto, Tuesday is the first of the OCETA Breakfast Sessions.  I’m going, and I have hopes for these, I know the people that set them up, and I’m expecting the quality to be excellent.

Back from hiatus

Hi everyone, sorry for the posting hiatus, but things have been insane around here.  For the next couple of weeks there will be semi-regular posts here, but for now it’s just a brief note hello and a couple of updates.

Updates

The Earth Rangers Centre Demo Site

Everything is on track for this, and right now it looks like the first panels will be installed in the third week of September, with the remainder of the panels in place by second or third week of October.  We’ve already received the tracker and had it delivered to the site, and we’re waiting on the delivery of the first batch of prototype optics from our provider and we’re all set for the assembly process.  The installed has been booked and we’ll be mounting the tracker in a few weeks.  Exciting stuff for us.  We’ll be putting pictures here as soon as they’re available.

Solar Power International 2008

We’ve finalized our booth plan and we’re going be to showing a prototype of our Sun Block solar wall system (more details on that later) and a small version of the Sun Simba HCPV.  Should be pretty cool.

Sun Simba HCPV Details

We’re waiting on the go ahead from the lawyers regarding our patents, but in a week or two we’ll be publishing details on the Sun Simba HCPV system.  We’ve shown it to a couple of people in confidence, and people are pretty impressed.

That’s it for now.

Five More Solar Power Myths

Ok, so here are the other five promised solar energy myths.  See my previous post for the first five.

6 – Solar power can only exist with subsidies/tax breaks

Right now this is actually true in most places for most solar power technologies. There are probably some thin film installations and a few concentrated solar thermal installations that approach cost effectiveness, but in general without some sort of subsidy, solar can’t compete.

Yet.

The reason it can’t compete, yet, is partly because every other form of energy is heavily subsidized as well and partly because true, industry-wide economies of scale haven’t truly kicked in yet. Coal, oil, natural gas, hydro electric, nuclear… all of those industries get money from the government and lots of it. Solar companies would love a level playing field, either remove the subsidies from the competitors (not realistic), or give us a taste. Solar really only needs a little, and the ideal model is based on a feed-in tariff so the subsidies are power output driven.  Traditional energy also has decades, in some cases, centuries of industry establishment, solar is catching up, but it’ll take another few years.

That said, with the price of electricity in many parts of the US expected to double in the next five years, and the price definitely rising rapidly everywhere, combined with the falling price of different solar technologies, solar power won’t even need a level playing field soon enough. In as little as five years, unsubsidized solar will be a cost effective way to generate electricity in many places.

7 – Solar power needs extremely intense sun to work (solar isn’t for Canada, New York, the UK etc)

For now, the real cost considerations for solar are the regulatory environment and the price of electricity. I know this slightly contradicts what I said in myth 6, but note the clever inclusion of the words “for now“.  Barry Cinnamon, the CEO and founder of Akeena Solar, outlined this better than I ever could in this podcast (definitely worth a listen).

If you go to solar conferences, especially conferences in the US South West and California, they’ll show you these beautiful NREL Direct Normal Irradiance (DNI) maps.

NREL Direct Normal Irradiance US Map, original image URL: http://www.nrel.gov/gis/images/us_csp_annual_may2004.jpg

They’ll talk about land speculation in the Mojave desert and write off solar development in the rest of the US.  Here’s Germany’s DNI map:

Germany DNI Map

Germany is the currently biggest solar energy market in the world.  If intense direct sunlight was an absolute requirement for a viable solar market, then that would be impossible.  Spain and Japan also have large and growing solar energy markets, and neither has sunlight like the Mojave. Spain averages between 6.0 to 8.5 kWh/m2/day depending on the region.) In every case it’s not the amount of sun, but a positive regulatory environment, and expensive electricity.

Having lots of intense sun is great, but Ontario up here in Canada is going to out pace many US states for solar (including Southern states), mark my words.

8 – The only viable solar power technology is…

I’ve heard enough versions of this many times, people who latch onto thin film or Concentrated solar thermal and treat all other solar technologies like they’re trivial sideshows or over hyped non-starters. Some people have this weird tendency to latch onto a single metric and then just over simplify the market and dismiss amazing or at least viable technologies.

Thin film is cheap and getting cheaper, but it’s not very efficient and needs lots of space to generate power. Concentrated Solar Thermal can store heat for use later, but needs perfect site conditions or the price goes up. No solar power technology is a one size fits all solution; all of them have their strengths and weaknesses. Basically, I’m not even going to waste my time on this one, if you really think there’s only one “real” solar power technology, then you’re wrong.

9 – Solar is a bad investment compared to other alternative energy sources

This one I’ve heard often, and it’s not as crazy as myth number 8. Solar is still the most expensive, although the degree to which that’s true is less every day.

Most solar technologies are on the high end of the price scale, but solar technology prices are falling fast so the graph below will be out of date very soon (it is already actually).

Costs of Different Renewable Energies in California

ALL renewable energy sources need to be explored, and all of them, including solar, have their strengths and weaknesses. Per watt, wind is cheaper than solar, but wind tends to produce more power in the evenings and at night than in day which doesn’t fit a demand curve as well as wind proponents would like. Geothermal is an excellent source of energy that we should explore more of, but it’s not appropriate for all locations. The beauty of solar, wind, geothermal and other renewable power sources is that once you’ve built the systems, the fuel is free.

As a society, we need all the energy we can get. Look at Google – right now they’re building data centres where the power is, not necessarily where the users are. Power availability is the key driver for them when choosing a data centre location. We need all the power we can get, and renewable energy absolutely has to be part of our power portfolio.

And finally…

10 – Solar power will save us from global warming

If only that wasn’t a myth.

But the truth is that no amount of renewable energy adoption and investment is realistically going to stop global warming. The US and the rest of the West have designed their entire economies around the idea that oil and coal are cheap and unlimited, and that burning them is a good idea. Emerging economies like China and India are working hard to copy the same model.

The fact that neither coal nor oil are unlimited, and that there’s nothing written in stone about them being or staying cheap means that we’ve built everything on a set of false premises. That we’re discovering now that there are long term environmental consequences really just means we need to examine a broken system sooner, and that the system was more broken than we expected.

Solar power and other forms of renewable energy, and the inevitable hydrogen economy that will follow in post oil days will do many things, but only a serious, wide scale and major commitment at a society and individual level will stop global warming (if it isn’t already too late). Renewable energy will help certainly, and solar power has a role to play in the solution.

Global warming is a cultural problem, and technology by itself won’t solve it.

Five Common Misconceptions about Solar Power

Solar Power

I was originally going to make this a top ten list, but when I started adding details it was too long, so I shorted it to five, and I’ll post the other five later this week.  Some of these are going to turn into full blog posts later, as I’ve left out details that matter.

Basically, there are many misconceptions about solar power floating around, and lately I’ve been hearing them repeated even in main stream media.  Solar is still a new industry, so that’s understandable, but these misconceptions will never go away unless people start addressing them.

So, without further ado, and in no particular order – five common misconceptions about solar power.

1. Solar power needs some new additional technology to be viable
   
   I talked about this somewhat in my last post about the MIT scientists and their hydrogen battery technology.  Solar power is basically a mature technology now – this is a multi-billion dollar industry with hundreds of millions in new investments pouring in every week.  The majority of that new investment is to ramp up production of existing technology, not in new research.That said, we’re developing new technology, and we’re going to have a profound impact on the CPV solar farm market as well as the BIPV market.  There’s a big space for new technology in solar, but if discoveries and new technologies stopped happening today, the solar energy market would still be thriving 50 years from now.
2. Solar power needs storage
   
   Solar power benefits from cheap, efficient storage sure, and on an industrial scale being able to control exactly when you get power is really valuable, the truth is for most users, solar power is producing peak electricity when people need it the most.  Storage would be great for all that cheap morning power that could be stored for use for a couple of hours after sunset, but the peak demand is 2 or 3PM to 7 or 8PM.  I covered this in detail in my last post and I can leave it alone for now.
3. Solar power is too expensive to be viable
   
   Right now, if you compare the average price of electricity today, to the average price of a solar power installation today, it takes between 9 and 16 years for the system to pay for itself.  As an investment it’s lousy if everything stays as it is today.  However:
   • IF the price of electricity ever goes up (it’s expected to double in the next five years) and,
   • IF the price of oil doesn’t go down and stay down, and
   • IF the electricity market’s insulation from the higher price of oil doesn’t last forever, and
   • IF any of the cost overruns on the current nuclear power projects being built continue (here in Ontario we’ve got a project that’s only a billion over budget, and compared to some of the other projects out there, we’re doing good), and
   • IF more proposed coal fired plants get blocked by locals concerned about the mercury, other toxins and of course the carbon, and finally
   • IF we ever put any kind of price, tax or disincentive on carbon emissions.

   So, in a perfect world, it’s true, solar is just too expensive. If we don’t live in a perfect world, solar’s not such a bad bet.  Of course, the fact that solar is rapidly declining in price doesn’t hurt either.

4. Grid parity is too far away, or grid parity is some specific number
   
   Grid parity is the point where generating electricity through solar power costs as much or less than the average price of generating electricity.I’ve seen people refer to grid parity like it’s some fixed number, ignoring the fact that people living next door to each other in California aren’t necessarily paying the same for their electricity.  Never mind the price difference in electricity between Seattle and San Diego or San Francisco and Cleveland.The price of electricity is variable throughout the day (highest between 2PM and 7PM) and variable depending on where you are.  So grid parity is a moving target, and since the price of electricity is going up, it’s a fun target to shoot for if you’re a solar power company.
   
   Also, remember that when solar power is producing electricity, the price is at it’s highest.  If you look at total output to average price, solar is a few years away still.  If you look at daytime output to compared to daytime electricity prices, some solar installations are at grid parity now.
5. Coal power is cheaper than Solar power
   
   Coal production in the US is so heavily subsidized in so many ways it’s frightening.  I won’t go into it here, but spend a couple of minutes at Coal-is-Dirty.com, or even just do a google image search for “Mountain top removal mining“
   
   Really, if you believe that this:

Mountain Top Removal Mine near Blair, West Virginia, original image found at: http://www.flickr.com/photos/nationalmemorialforthemountains/230179038/

and this:

A Coal Power Plant, original image from Greenpeace Public Images: http://www.greenpeace.org/raw/image_full/international/photosvideos/photos/pollutioncoalplantthailand.jpg

are cheaper than this:

Solar Panels, image licenced from Dreamstime Images.

You’re a sucker.

Ok, that’s it for now, I’ll follow up with another five later this week.

Peace.

First Sun Simba HCPV Demo Site

Projects

So, it’s official, we’re announcing the installation of our first Sun Simba HCPV demonstration facility at the Earth Rangers Centre just outside of Toronto in Woodbridge, Ontario.  This is exciting for a couple of reasons.

Our strategy has been to make it to the demonstration prototype stage prior to seeking external funding – demonstrate our technology before we start talking to investors.  (What we can do is pretty amazing, so a little proof to quell people’s healthy scepticism is a good thing.)  We’ve been developing the Sun Simba HCPV for a while, and we’re going to be releasing details on how it works in the next few weeks.

It’s one thing to say that we’ve built a low-cost, high-efficiency CPV system with a long list of advantages over other systems, we’re looking forward to showing people.

The other reason this is exciting is that Earth Rangers will be hosting the demo.  Earth Rangers, if you haven’t heard of them, are a non-profit organization dedicated to children’s environmental education and action, and to demonstrating cutting-edge environmental technologies. In the words of one of their engineers, they believe in implementing smart environmental technologies now, and they believe in walking their talk.

The Earth Rangers Centre is a certified LEED Gold building that is an amazing model of environmental technology in action.  After discussions and a tour of the facility, we’re most likely going to be installing our demo system just south of a building on the site that already features a rooftop PV installation. Our demo will be tied into the existing system.  In addition to hosting the demo system and providing us with a beautiful location, they’re going to be providing us with monitoring support as well as access to their facilities.  Their enthusiasm to support cutting-edge solar energy technology research translates into a perfect setting for us to showcase the Simba.

It’s a beautiful spot too.  We’ll be installing the demonstration system in mid to late September and releasing more details soon.

Cool, eh?

Better Uses for MIT Solar Storage Breakthrough

Energy Ideas

A news story has been making the rounds for the last week or so, heralding a revolutionary breakthrough for solar power.  The short version, they’ve come up with an amazing new way to separate water into hydrogen and oxygen, using an innovative new catalyst that works at room temperature, low pressures and yields efficient conversion.  Great so far.  They’re touting it as a breakthrough for home solar installations.  This is a brilliant technology, and if it’s as cheap as they claim it will play a huge role in solar.  But not the way they’re saying.  This does not belong in the home.

Here are some articles.

• MIT Researchers Develop Efficient Solar Energy Storage System
• MIT develops way to bank solar energy at home
• ‘Major Discovery’ Primed To Unleash Solar Revolution: Scientists Mimic Essence Of Plants’ Energy Storage System
• MIT Breakthrough Means Solar Power All Day Long

Screen caps from Daniel Nocera’s MIT video.

I really had to spend some time reading on this before I started this post. When I first saw this article starting to pop up in blogs and Google Alerts, I didn’t think much of it. “10 years away” too often means “never”, so basically I lost interest. But the article kept popping up and it seems that they’ve got something useful that really works, and it will probably lead to commercial applications.  So in this case, “10 years away” might actually mean 10 years away.  Cool!

Check out Daniel Nocera’s MIT video for a decent overview of the technology.

I want to be totally clear, I think this is an absolutely amazing technology, and hell, I’ll go one further and say that when it comes out, I’ll invest.  But it’s a bad fit for residential solar and an amazing fit for utility scale solar.  After some thought, I want to address a few points made in discussing this technology.

Point 1: No solar energy at night is what’s holding solar back.

In the video Daniel Nocera says the following:

“It really opens the door for the large scale deployment of solar, because we have an easy way … to store that energy.”

This is just wrong. On the most basic level, we don’t need more electricity at night. We need more in the afternoons during peak demand. If you look at the daily electrical consumption (examples below) you’ll see that the night time price of electricity is a  fraction of what it is during the day.

Typical Daily Demand Curve

LMP is Location Marginal Pricing, a standardized method of describing electricity pricing.  PJM Interconnect is a regional transmission organization in the North East.  Source: NREL – Understanding the Economic Value of Electricity Storage: Some Key Drivers.

Hourly Price of Electricity

Source: Healthandenergy.com: Demand Side Management

Solar energy, especially solar energy with tracking capability, or concentrated solar thermal systems with built in thermal storage, produce energy when we need it the most – during peak demand.  Utility scale electrical storage would let solar facilities store the cheap morning electricity generated prior to peak demand, and output more electricity during peak demand.  (Solar thermal already does this by storing heat, but it can only be stored for 6 hours.)

Solar Tracking and Co-Firing Demand Durve

Source: Hal LaFlash, PG&E – Utility-Scale Solar Power Generation Presentation.

Night time electricity is incredibly cheap, and if there is lots of nuclear, geothermal, hydro or wind power in your area, it can get close to free. Wind power is most productive in the evening and at night, so if you really need more power at night, throw up a turbine and you eliminate the need to install (in every home mind you) hydrogen and oxygen storage tanks, fuel cells, water tanks, piping, inverters and whatever else you need to run this system.

Basically, if the big advantage of this is that it provides power at night, it’s solving a non-existent problem.  Solar benefits from storage, but not the way they seem to imply.

But the real thing that’s holding back solar energy is that the cost compared to the power output is still higher than just buying power off the grid.  (Something we at Morgan Solar are working to change soon enough.)  Even if this system was 100% efficient (which is impossible) it would still mean more equipment and more costs for the same amount of power. That they’re suggesting you shift power from when it’s most useful to when it’s least useful, which doesn’t really make sense.

Point 2: This is a solar technology.

After looking at this, reading their website, watching their video etc, it’s fairly clear that this system electricity, and the source doesn’t really matter. This catalyst uses electricity to run the system, not photons, heat or anything else particular to sunlight.  Any electrical source would work.

As cool as this is, it’s not really “solar storage”, it’s electrical storage.  In a home installation, this system would provide MUCH better returns if you used the super-cheap and abundant night time electricity from the grid to store hydrogen that you could burn during the day.

Point 3: This would be cheap and useful for providing nighttime power

There is just no way that this system could be cheaper than a few more wind turbines. There is no nighttime energy crisis. Electricity peak demand is from around 4PM to around 7PM. High demand is from noon to 8:30PM or so. No matter how cheap this system is, there is no way you could reasonably justify the costs of hydrogen and oxygen storage tanks and a hydrogen fuel cell to provide power at night.

Point 4: Getting off the grid is a good thing

I hear many people talking about “getting off grid”. It really sounds better than it is.

The electrical grid is one of the most astonishing achievements of modern society. It’s totally democratic, even the poorest of the poor can be and usually are connected, and it improves absolutely everyone’s life.  Access to indoor light, heat and appliance power helps everyone.  We’ve spent the better part of a century building it for a reason, and it’s so effectively built and managed that we forget about it most of the time.  You plug something it, it turns on.  We only pay attention to it during windstorms or the occasional (very seldom) power outage.

But wanting to disconnect sounds like a good idea.

“If I generate all my own power, then I’m not contributing to whatever bad stuff happens when the utility generates electricity. Carbon, pollution, all of that, I’m not involved if I disconnect…”

Technically true, but what about your surplus power? What happens when your power system breaks down? (Which it will occasionally.) What about the people who can’t afford the up front costs of going off grid?  Sure you can go carbon free if you disconnect, but you can go carbon negative if you stay connected and give back.

Basically, it makes much more sense for us all to contribute to the grid.  So using this to “liberate” yourself from the grid is a non-starter.

Increase our local home production as much as we can, while decreasing our consumption, so we’re giving back more than we’re taking. In this model, a couple of things happen. First, it provides more of a financial incentive for upgrades to the grid that would benefit everyone, and second, it contributes to a more stable, productive and low cost power grid for everyone.  Staying connected and giving back makes more sense than disconnecting.

This hydrogen fuel cell doesn’t generate power, it stores it, and doesn’t do anything to lower household consumption. It’s great if you need a battery back up, or if connecting to the grid isn’t an option, but all it does is store power.

Practical Uses for Cheap Efficient Electrical Storage

Now, to be clear, I think cheap, efficient and reliable energy storage is an amazing thing, and something that we need. But not for storing solar power at home. Here are some smart scenarios for using this breakthrough:

• Hook an industrial scale version of this thing up to a nuclear power plant, run it at it’s optimal power output 24/7, store power when the grid doesn’t need it and dump the power onto the grid when demand goes up.
• Hook these up to wind turbines, which are intermittent and unpredictable, so you get a more steady baseline power output.
• Hook one up at home, charge it up all night, and use it during the day to lower your power consumption during peak demand.

The real value of this in the solar market will be for what’s called Load Shifting.

• Hook up an industrial scale version of these to a solar farm, so that that the power generated in the morning (which isn’t worth much) can be stored and dumped onto the grid in the afternoon and early evening when it’s at peak demand.  At home, this makes no sense, on a utility scale, it’s brilliant.

Another amazing application would be local demand management.  They spend millions of dollars topping up local power dips and trying to get the power from the big utility stations to the widespread grid.

• Put neighbourhood versions of these in trouble spots, store hydrogen when there’s lots of power and then top up the grid when you start facing brownouts or rolling blackouts.

In all these cases, you’re taking power when it’s cheap and not in demand, storing it, and then using it when (or where) it’s actually needed.  But power at night? Don’t need it, don’t want it, it’s nearly free already, so why use daytime energy to make it?

This is huge, this is a major breakthrough, if this works and people can use this technology to make utility scale systems that stock-pile energy and deliver it when needed, they’re going to make billions.  But installing these in the home, tied into residential solar – pass.

For a rediculously detailed economic analysis of storage for renewable energy, check out this report from the NREL.

Quick Updates

Solar Updates

Great long weekend, and we’re going to be having an interesting week.  More on that later, I assure you.

The announcement I mentioned on Friday is still on track, but I want to have everything sorted before saying anything, so it’ll be a little later this week, Thursday probably.  It’s pretty cool though.  For now I wanted to comment on a couple of goings on in the solar industry:

• Solar Power Conf & Expo 2008 changes name to Solar Power International 2008.  It’s still the same conference, we’re still going to be exhibitors there, and we’re still sponsoring the event, it’s just changed names.  On that note, our exhibit will be the first completely public look at our panels, and we’ll have live data from the demonstration facility available via the web.
• Partisan politics (the GOP really) are still blocking the Renewable Energy Tax Credit renewal, and it’s looking worse and worse.  (The Renewable Energy Tax Credit is usually referred to as the ITC, and I’ve blogged about it’s importance to the US Solar Energy Market.)  It looks like the ITC is getting dragged into the off-shore oil drilling debate in the presidential election.  Sigh.  Also, it looks like a 4 year renewal, not the 8 years the industry really needs.  Stupid stupid stupid.
• A great analysis of Obama’s speech on Energy over at Earth2Tech (video embedded at the bottom of this post).  My favourite quote from the speech:

We simply cannot pretend, as Senator McCain does, that we can drill our way out of this problem. We need a much bolder and much bigger set of solutions. We have to make a serious, nationwide commitment to developing new sources of energy and we have to do it right away.

Sadly, he also says:

Now, increased domestic oil exploration certainly has its place as we make our economy more fuel-efficient and transition to other, renewable, American-made sources of energy.

At least he pledges to extend the ITC.

• On another note entirely, Cyrium Technologies here in Ontario just announced $15 Million in funding.  We know these guys and are very interested in the triple junction cells they’re designing, so good for them.
• Finally, on a lighter note, since I just got an iPhone, I thought I would point people to this Solar Powered iPhone Case.  I want one (and the reviews are surprisingly positive).

Obama On Energy

Sun Simba HCPV Early Details

Projects

We’re pretty close to releasing the full specifications and images for the Sun Simba HCPV system, and will be uploading images here and on the website fairly soon.  We’re putting together the final details of the spec sheet right now, and are looking forward to having the working demonstration system available in September.

The Sun Simba HCPV is based on the best implementation of the Light-guide Solar Optic (LSO), which is described in high-level detail the technology section of our website.  It’s a pretty amazing system.

Some of the key advantages of the Sun Simba HCPV:

• Low cost – We’ll definitely be able to sell our panels at a significantly lower cost than most other CPV systems on the market.  Reasons:
  • We use very few materials compared to other systems – less material equals lower weight and less cost.
  • Our manufacturing processes are extremely simple and can be 100% automated.
• Low profile – The LSO allows us to build a panel that is only 3cm (<1 inches) thick.
• Low Wind Load – We have a simple innovation that allows for lower wind loading on the panel, even when in full wind facing position.
  • Combined with the low weight and low profile of the system, this leads to additional savings in the tracker.
• No Overheating – We don’t have any overheating issues, not that we’ve found ways to deal with overheating, our system doesn’t overheat.
• No Thermal Expansion Problems – We don’t have any thermal expansion issues, our system expands evenly, with no thermal misalignments.
• High Concentration – Our concentrator technology very easily scales up to 1400 suns concentration in the current implementation, and with modifications can achieve up to 5000 suns concentration (which we’re considering for solar chemistry and other super high temperature industrial applications).
• High Efficiency – There is an absolute minimum of sun exposed surface that isn’t capturing light, and very few losses in the optics, so the system functions at near the theoretical limits of efficiency for CPV systems.
• Unique - We don’t use lenses or reflectors – our system is unique so our advantages can’t easily be replicated in other systems.

We’re a couple of weeks away from being able to go into more details, and are arranging renderings right now so expect to hear more about this soon.

Sun Simba HCPV Project Update

Projects

This week, a couple of people have asked why there’s not much on the website about our actual products. There will be, and soon too. But there are a couple of reasons we’re being vague.

First off, the reason we’re not formally announcing anything concrete or specific yet is that we’re sorting out some final patent details that inform the best implementations of our technology and we don’t want to get too specific until we have it completely sorted. We expect to be able to publicly talk in detail about what we’re doing in a month or two, possibly sooner. We’re preparing press releases as well as spec sheets and other materials in the meantime.

Second, we’ve ordered the optics, but these things take time and we expect to have working demonstration systems in place by some time in September or October. Having these working demonstration systems has always been part of our strategy – we’re going to make some very bold claims and having the evidence to back them up is part of our approach. We have proof of concept prototypes of course, but these demonstration systems will actually be installed and generating power, which is a key difference.

So, we’re going to have all the intellectual property stuff sorted soon, and definitely before the demos go live, and then, when we’re a little closer to having the demo systems installed, we’ll really start promoting our innovations

Intersolar North America 2008 Summary – Part 2

Solar Industry

Here’s part two of my wrap up of Intersolar North America 2008.  Obviously, this doesn’t even scratch the surface of what was covered at the conference, but these were some of the things that stuck out in my mind.  Also, I haven’t added anything about the exhibition – I spend quite a bit of time checking out the various exhibits and talking to people, but they were enforcing their “no photography” policy the day I was walking the floor, and frankly, there’s not much I could say here that isn’t on the exhibitor’s websites.

• Concentrated Solar Thermal (CST) - CST still enjoys cost advantages over PV, but these are shrinking rapidly.  As the price of concrete and steel continue to climb, this advantage will erode, and will quite likely disappear and then reverse in the next 5 to 10 years:
  • Solar Thermal systems can store their heat, they can produce more power output as needed and during peak demand, which makes this more attractive for utility scale solar.
  • As PV costs start to significantly fall, combined PV – Wind systems might start to look more attractive, see next point.
• Meeting Peak Electrical Demand – Photovoltaic and Wind Power output compliments well.  As prices fall, proposals for blended systems might become more common.  See slide:

Wind and PV Power Output

• High Quality Development Land – Land use is becoming a bigger issue as flat, high solar irradiance land near transmission lines gets bought up.  The US Federal Bureau of Land Management tried to put a 2 year moratorium on new solar projects, and concerns about endangered species habitats and even flash flooding have put the breaks on some projects.
  • This hurts land inefficient applications like thin film, tracking PV and Tower Solar Thermal the most.

And finally, here are a couple more blog posts and articles covering the event.

Greentech Media has another slide show of the conference itself, and a short article on some of the other conference news items.  (If you look carefully in slide 3, I’m the green shoulder and hair visible behind the woman in the first row.)

In the San Francisco Examiner, a short summary article about the conference.  Short version of the article, it was an excellent conference, attendance was huge and if you’re at all interested in solar and can make it next year, go.

So, that’s basically it for now.  I will definitely go into more detail on some of these points in the future and am likely to cover other points raised that I didn’t mention here.