I'm sorry but I don't believe them that it can run for 300km in between refuels. Compressed air is just not a very dense fuel. Enough fuel to power a car for that long would be a tank about 1/3 the size of the car.
(My calculation: gasoline stores about 3000 times as much energy as compressed air per volume. But a gasoline engine is also only 10% efficient, an air engine would be much more efficient. Assuming 100% efficient, then gasoline stores 300 times as much. I can go about 300km using 11 or so gallons of gas. Lets assume a lighter car, so 5 gallons per 300km * 300 = 1500 gallons of air, which is about 5.5 cubic meters. So you'd need a box 1.75 meters on each side. Which is about 1/3 of a car.)
Obviously if they can store the air at a higher density then the box can be smaller, but if they did that it would also have to be stronger and thus heavier. (Edit: they are running at about 1/3 more pressure than my numbers assumed.)
And now comes the bigger problem: you waste a tremendous amount of energy by heating the air when you compress it.
And then you let the air cool, and lose again, because as it expands it gets _really_ cold, and won't expand as much. On the plus side running the A/C will be free. But forget about heat in the winter.
Using higher compression makes this much worse.
All in all, I simply don't think this will work for that distance. Maybe as a 30km car it would work fine (and there's a large market for that), but not 300km.
And the heating/cooling losses are really going to hurt efficiency.
And as an aside using vegetable oil is a bad idea. Unless you can seal it away from air (doubtful) it will oxidize and won't be oil anymore.
Now please tell me if I made any mistakes in my calculations.
In the winter you compress the air at home and use the heat to keep your house nice and toasty.
Your calculations are off: energy density of gasoline ~35 MJ/L, compressed air at 300 bar ~ .15, so per volume is ~230 times, so w 10x efficiency, it's down to 23X volume required: tank to be used is 340 L : divide by 23 ~= 15 L ~= 4 gal. Much closer to their claim, no?
The compression stations will have heat exchangers, so be able to use at least some of the wasted energy...
You've made a few small mistakes, but they're non-obvious.
One big thing is that your current vehicle doesn't push the technical mileage limits as far as the Air Car does.
You've assumed the car is the same weight. Cars can be made much lighter than those currently on the market today. You can get well below 1000 pounds. For example, one design prototype is the Volkswagen 1-liter car, which gets 282 mpg. (http://en.wikipedia.org/wiki/Volkswagen_1-litre_car). This design uses a variety of techniques to get the mileage up, and does so quite wonderfully.
With an Air Car it's even easier: you can even do it in a production, mass market system. You need not have a transmission, or an electrical system, or an air conditioning system, so you can get a very good car, a production car, for under 1000 pounds.
Also, unlike gasoline engines, it's a comparatively simple matter to have breaks which recover power. Power recovering breaks become simply a system for compressing and releasing a piston: a fairly mature technology actually. So breaking is not as much of an issue, and the energy you'd lose for it can be recovered at about the 70% efficiency level.
Also, compressed air, at 300 bar (4500 psi) stores approximately 16 kwh per 300 liters, (via wikipedia http://en.wikipedia.org/wiki/Air_vehicle#Storage_Tanks), giving an energy density of 0.0056 of gas (in liters). In other words, gasoline takes 176 times less space, not 3000 times, as you guessed. And given modern tanks, the air is lighter than it is large (compared to gas), though weight is a property of the tank, and does not scale linearly. I haven't factored the efficiency of gas versus air engines into this calculation, as both technologies are varied and evolving.
When these factors combine, you can get a much, much more efficient vehicle than ordinary. Getting around 80 km is a no-brainer, and 300 km is well within the realm of possibility. You might go up to 1000km before you start to hit fundamental limits.
To address some of your other concerns.
The temperature regulation of the compressed air tank is not as much of an issue as you think. There are two temperature regulation problems. The first is heating the tank as you compress it. This is not a fundamental problem, but it's actually a technical detail that I think I've solved, and I want to develop it for my startup. You'll just have to trust me that there's a way to heat this cost effectively. The second direction is when the air is expanding. While the expanding air leaving the tank is quite cold, the tank itself doesn't expand very fast, and air simply doesn't have much heat capacity. Oil and water have a far greater heat capacity, and so running a radiator in a gasoline car is actually a much more significant problem.
Additionally, there are wonderful, wonderful ways in which to improve the energy economy of these vehicles as compared to gasoline (or any other comparable vehicle, including electric). Email me, if you might be interested, since I am working on them, and actually looking for more mechanical engineering and organizational talent, or funding, or mentorship.
As I replied to someone else, you are right, I was off by 10 in my calculations (a typo in my calculator, sigh). But I did take efficiency, and light weight vehicle into account.
But I still maintain that the heating/cooling losses from compressing the air are going to hurt efficiency a lot. It's really hard to do anything with waste heat, especially since this car probably won't be sold in cold climates, so the waste heat can't be used for heating.
But, since an air engine is so much more efficient than internal combustion, it might work out.
But if it works so well, I wonder why no one did it before now - is the tank the problem?
Does it make sense to use a larger, lower pressure tank?
I'm very interested in these ideas, and I spend a lot of time dreaming up ideas - basically every time I have to fix something in my car I think of a way to design a car without that part. But I don't know if I could actually help you - I'm a computer programmer, I don't have experience with any of the skills you mentioned.
Most of the best engineers were outside of car design and into aerospace since the early 40's. Getting a car that works at this level of efficiency requires three or four conceptual jumps, which weren't made until a market forces induced some thought on the problem.
Additionally, none of the interested parties have figured out the last step: how to cheaply charge the thing (while recycling the waste energy). But I think I might have.
It's exciting that they're announcing this. I had actually started specifically working on supporting technologies for this (off-grid sustainable refueling strategies) about a month ago.
The difference between burning seawater, water catalysts, cold fusion, and this, is that this is based on science and technologies that have basically been known for more than a hundred years, and many of the technologies used have already been quite solidly demonstrated. They simply hadn't been put together.
I don't quite buy this argument. Gas is far less volatile than people think. In the event of an accident, I would much rather face a tank of gasoline, which most likely wouldn't explode at all, than a tank of compressed air.
In the middle of the fire, however, I'm not so sure.
Yes industries like welding have been using high-pressure tanks for decades, but that's not high pressure tanks that are traveling at 70 miles an hour in a tight corridor surrounded by hundreds of other cars that likewise are traveling at 70 mph. Can you say chain reaction?
Compressed air is far more dangerous than gasoline. Gasoline is not a guaranteed explosion more likely its a fire.
I would like to see that in action, because it seems to me that allowing gas to expand that fast is going to drop the temperature of the gas so low it'll probably freeze CO2 out of the air.
And that process will probably rob a lot of the explosive force.
Can you compress gas so much that if it exploded it would liquefy? With a quick google I couldn't find an equation relating pressure drop to temperature in real air (not ideal gas).
I think its worth mentioning that explosion is not the danger we should be thinking about when it comes to gasoline.
Gas is a low viscosity, oily (duh) substance held in flimsy metal or plastic containers that ignites easily and is hard to put out. We are comparing the danger of being injured by the compressed air explosion with the danger of being burned severely by sprayed or leaked fuel.
Sign me up for the shrapnel because burns suck huge.
I was just thinking about these. Yes, they're used for years, but they are incredibly dangerous and treated as such. I remember that not any compressor can load them: if it leaks the tiniest amount of oil in the air it'll create an explosive mix.
I wonder if you are thinking of diving tanks, where not any compressor can load them. If it leaks the tiniest amount of oil in(to) the air it'll poison the diver.
We intentionally put vast amounts of far more flammable compounds into gas tanks, welding, cutting etc.
It's totally different, the compression there is just for more effective storage, the power still comes from the gas itself.
In compressed air however it's the compression that contains the power to move the car. Drive an accident and the same power that moves your car will release its power with quite an unpleasant speed.
the air tanks in the garage aren't in danger of being suddenly ruptured by a car that rear ends you at 40 mph.
And don't tell me that doesn't happen, since I had that happen to me two times already, strangely enough the accidents were less than 2 weeks apart, and both times they were big SUVs(Navigator and an X5). Actually the same thing happened to a friend(in his case it was a Grand Cherokee). So accidents like this probably happen quiet often.
And yes before someone asks in all 3 cases, it was a soccer mom on a cell phone.
A pretty cool idea. I wonder how the compressed air is generated. I know that there are some < $100 compressed air generators that run off many other types of power(electricity, petrol etc). I wonder how energy efficient it is in terms of power. I mean, the energy use has just moved from the car to the compressed air generation plants.
It seems they have optimized the car for use in urban areas by making it as lightweight as possible. I wonder if it would pass safety tests in other countries -- with the car being held together with glue, and relying on wireless technology (zigbee maybe)?
Great ideas... it seems to have used a whole bunch of new technologies.
Sorry, its a stupid paintball reference. It probably is meaningless. What its supposed to mean is that as a chemical pressurized (to the point of liquification) boils and creates the pressure in the tank, this pressure remains relatively stable as long as there is some liquid left to boil.
So most paintball markers use CO2 because you need a simple regulator to get an even pressure for most of the tank. Some markers use plain air pressure, they require more complicated regulators because the pressure changes dramatically during the entire use of the tank.
So the dumb jocks say that the CO2 tanks are "pressure stable", I suppose because pressure in the tank is constant around 850psi so long as there is any liquid CO2 in the tank.[1]
I made this comment because this to me seems like a desirable property for a fuel gas in a compressed gas vehicle to possess. I will attempt to be more succinct in the future.
[1] And since we are nitpicking, I am in fact aware that that this figure of 850 is variable based on the temperature of the tank.
The only trouble with using a gas like co2 that liquefies easily is that once you reach that point (850psi) you pretty much can't go any farther. And they are running this thing at a much higher pressure than that - about 4500.
I'm sure there are gases that would liquefy at this pressure, but none that you would want to release into the atmosphere.
(My calculation: gasoline stores about 3000 times as much energy as compressed air per volume. But a gasoline engine is also only 10% efficient, an air engine would be much more efficient. Assuming 100% efficient, then gasoline stores 300 times as much. I can go about 300km using 11 or so gallons of gas. Lets assume a lighter car, so 5 gallons per 300km * 300 = 1500 gallons of air, which is about 5.5 cubic meters. So you'd need a box 1.75 meters on each side. Which is about 1/3 of a car.)
Obviously if they can store the air at a higher density then the box can be smaller, but if they did that it would also have to be stronger and thus heavier. (Edit: they are running at about 1/3 more pressure than my numbers assumed.)
And now comes the bigger problem: you waste a tremendous amount of energy by heating the air when you compress it.
And then you let the air cool, and lose again, because as it expands it gets _really_ cold, and won't expand as much. On the plus side running the A/C will be free. But forget about heat in the winter.
Using higher compression makes this much worse.
All in all, I simply don't think this will work for that distance. Maybe as a 30km car it would work fine (and there's a large market for that), but not 300km.
And the heating/cooling losses are really going to hurt efficiency.
And as an aside using vegetable oil is a bad idea. Unless you can seal it away from air (doubtful) it will oxidize and won't be oil anymore.
Now please tell me if I made any mistakes in my calculations.