This is blogspammed PR that gets it wrong. This is a research project that is nowhere near production with many "ifs". Vertical surfaces don't make a lot of sense for solar since they get limited exposure. They'd have to be incredibly cheap to make financial sense.
Research like this comes out every day. 90% of the time it's not possible to make it practical.
A large fraction of the cost of solar is installation — the panels are actually a minor expense in most rooftop installations. So using windows, which are being installed anyway, isn’t all that crazy. It will work best on a South-facing window at a high Northern latitude or vice versa.
> the panels are actually a minor expense in most rooftop installations
I have had the questionable delight of seeing a specification made for a rooftop installation recently, so I know this is not universally true (even if you use an older type of solar panel, which is cheaper).
Totally agree. Took an HVAC course during my grad years and there's specific standard and regulations windows adhere to for houses to prevent over heating or cooling which means the view factor to the sun is usually way below optimal. I'm willing to bet the net energy required to cool a house during the summer is negative if you try to place the windows that is more solar optimal. But I can see this working for cities with tall buildings. But there will be new technology required to wire all these together properly for a building scale.
Office towers seem like a natural fit for this and have a huge surface area to collect solar energy from! Hope this makes it out of the lab and into commercial buildings in quick fashion.
My house has 4 walls and a roof to cover solar panels in before it makes sense to make my windows solar panels. Unless it is one of those skyscrapers where the entire exterior is glass.
Just from a physics point of view, I have a hard time believing this. Isn't a large portion of the energy coming from the sun photons in the visible wavelengths? If the solar panel is transparent, it's allowing those photos through and not collecting energy.
Or am I wrong, and most of the energy is in the non-visible range?
most of it is in the blue i think, but from the surface of the earth this range is scattered so the next peak is in the green-yellow. I'm sure there's UV we could capture with windows
1. Mainframes are cheaper then distributed computing. We call them 'the cloud' these days.
If pointless things like solar windows become cheaper then utility solar, then utilities will just build farms of solar windows. You know what's easier then installing a solar window in a house wall? Installing one at ground level, without worrying about walls.
Instead of having a handyman drive for 50 minutes, and then spend two hours tearing apart my house to install 6 windows in it, they could have him install an array of 90 of them in one day at a utility site. Hell, he won't even need to make sure that they don't leak.
This was the argument against PCs too. And in the late 70s I was already using cloud computing (MIT lispms and PARC systems like grapevine) that were not using mainframes. The economics seemed clear, but a variety of path dependence and economy of scale issues meant the mainframe survived quite a while (and is still going strong, but isn't dominant). But we are doing more edge computing than ever before with supercomputers in every pocket, game consoles and the like.
I have also worked in distributed solar. That's why I understand that the existing utility model still has a long way to run. Where I disagree is that there might be an inherent advantage.
> The biggest limiting factor on renewable adoption is cost.
Often the biggest cost for a solar project is the installation. If they somehow make these windows roughly as easy to install as a regular window, this could actually be a very economical approach.
And look at what happened to SolarCity, and similar firms. That space is unable to operate profitably, despite large federal subsidies. It also has no shortage of scammy ownership/loans-for-your-solar-install model, is a bad investment for most homeowners, and doesn't even answer the hundred-thousand-dollar-per-home question of peak energy storage. (Or how it can operate in a world where you are on an even playing field for selling power to the grid as the utility.)
The home solar industry makes most power utilities look both efficient and competent.
Also, look at the hilariously high cost of electricity in PG&E territory. If you can deal with storage and peak loads, on-site generation is competing with 20-40 cents / kWh charged by PG&E, not the vastly lower prices that PG&E pays for generation.
This lacks data. We'd need to know the efficiency, life expectancy and energy production cost of the cells in order to know if this is really interesting.
If you need more energy to produce the cells than the amount they'll provide throughout their lifetime, it's not worth it.
Sure, it looks cool, but it's too soon to publicize.
Many negative comments. While this might not yield the desired results right now it’s still good that different approaches are being explored and evaluated.
Also, as for many things (think gorilla glass) the right application might not be the one for which this technology has been developed originally.
Research like this comes out every day. 90% of the time it's not possible to make it practical.