Blimps... In... Space... 511
LandGator writes "MSNBC reports a California company with an alternate launch site in Texas, JP Aerospace, is on their third test of a blimp system specifically designed to fly to space. Blimps. To Space. At payload costs around a dollar a ton to LEO. Their concept, first unveiled at the Space Access '04 conference in Phoenix last month (with a blog report here, include the Ascender, a ground-to-near-space blimp, which docks to a helium-inflated two-mile-long station at the edge of space, over 20 miles up. Another ship, also a blimp but specifically designed to reach orbit, takes the payload from there to LEO, using well-proven electric propulsion (AKA 'ion drive'). That trip to LEO would take up to nine days, but that's a good thing; for, what goes up fast, must come down fast, and speed is energy which must be bled off by either massive amounts of expensive and explosive rocket fuel, or through ablative heat transfer which has its own problems (as we have seen before). JP Aerospace has flown many PongSats -- micropayloads the size of a ping-pong ball -- for balloon or rocket-launch. Over 1,500 PongSats have flown to date, which demonstrates a track record in near-space few of the X-Prize contenders can approach. Oh, yes, the Air Force is interested."
Cost to orbit (Score:3, Interesting)
Re:Cost to orbit / quote (Score:2, Informative)
Still.
Re:Cost to orbit (Score:3, Insightful)
Re:Cost to orbit (Score:4, Informative)
Yea, good and explosive. While it may not be particularly dangerous to people, losing payloads to accidents involving hydrogen explosions in the atmosphere would jack the potential cost up.
Re:Cost to orbit (Score:3, Insightful)
Re:Cost to orbit (Score:3, Informative)
Which brings up the interesting question of what there is in the upper atmosphere... is there enough oxygen for hydrogen to burn?
--
Evan "Not a meteorologist"
Re:Cost to orbit (Score:3, Informative)
Of course, one of the other great benefits of helium over hydrogen is that helium is MUCH more containable - He stays inside Mylar envelopes a lot longer than H, which has been known to burrow its way out of multi-layer met
Re:Cost to orbit (Score:5, Insightful)
So, once we use the helium we have, we aren't getting any more. One source says this may happen by 2030.
Found some googled info here [anl.gov] and here [omsi.edu] and here [gopbi.com].
Re:Cost to orbit (Score:4, Informative)
So, yeah, you're right it's leaving, but it's also being replaced by natural radioactivity so that even after all the hydrocarbons are used up, natural gas wells will still be producing helium for millions of years.
According to Praxair, fifty percent of current natural gas consists of helium. So, it's not all that rare which helps to explain why it's not all that expensive.
Re:Cost to orbit (Score:5, Insightful)
No, the only safety concern that I have with Hydrogen is that it tends to escape from a confined space much more quickly than does Helium.
Re:Cost to orbit (Score:3, Interesting)
It also burns with an invisible (ultraviolet) flame - and a leak is essentially ALWAYS lit. (NASA used to find them by having a worker walk slowly forward holding a big piece of cardboard edge-on in front of him, stopping when it caught fire. B-) )
Re:Cost to orbit (Score:3, Interesting)
Maybe this will make it affordable to launch garbage collection in space, though.
Blimps do not necesarily crash due to leaks (Score:4, Informative)
It all comes down to the pressure difference between the insides and the outsides of the blimp.
Reading their promotional literature, they do not maintain much of a pressure difference between the insides of the blimp and the outsides. Thus, a hole will not really result in the helium being replaced with the heavier atmospheric gases.
Most blimps can manage a safe emergency landing if even significantly damaged.
Last but not least, I suspect that their choice of helium was more due to the dramatic reduction in safety precautions they have to take with the stuff on the ground. There are real advantages to using diatomic gases over monotomic gases (for example, they leak much more slowly through micro-pores). But the advantages do not make up for the disadvantage of the risk of explosion on the ground or at low altitudes.
Re:Blimps do not necesarily crash due to leaks (Score:4, Informative)
My understanding of blimps is that they use equivalent pressure - hence the airsacs that allow pressure changes as they rise - and rely on the buoyancy of lower weight at the same pressure.
I'm just thinking of a blimp on the edge of space suddenly getting hit with a small projectile traveling 1000+ miles per hour. That could do some serious damage. Aside from making a hole, the force of impact might well deform the ballon, rapidly forcing gas from it. This is unlike most damage that occurs with conventional blimps. And, the additional height exacerbates the issues with blimps, giving them more time to slowly leak as they descend and more time to accelerate.
helium != diatomic (Score:3, Informative)
I see your point, though. Helium has a nucleus that is four times as heavy (two protons and two neutrons versus a lone proton for most hydrogen), and has another electron in its orbitals. These factors greatly reduce the diffusion rate. Diatomic gasses would have some added advantages of greater size per unit weight but would have some disad
Re:Blimps do not necesarily crash due to leaks (Score:3, Interesting)
Re:Cost to orbit (Score:3, Interesting)
When the blimp is staying up via buoyancy, it's still in atmosphere by definition. If there is atmosphere of any sort, it's rather unlikely you will find high velocity paint chips or other things.. they would quickly slow down, burn up, etc.
When the blimp is OUT of the atmosphere, at orbital velocity, it is no longer staying up there via buoyancy, and puncturing it's gasbags would not really be an issue as far as staying up there goes.
Re:Cost to orbit (Score:3, Informative)
Re:Cost to orbit (Score:5, Informative)
Re:Cost to orbit (Score:5, Informative)
Re:Cost to orbit (Score:3, Informative)
Re:Cost to orbit (Score:5, Informative)
Re:Cost to orbit (Score:5, Insightful)
I bet people just keep thinking of the Hindenberg.
Re:Cost to orbit (Score:2)
Helium vs. Hydrogen (Score:4, Interesting)
-Mark
Re:Cost to orbit (Score:5, Interesting)
Firstly, helium gas goes round as a single atom, He, because it's a noble gas. Hydrogen goes as pairs, H2. This means that in a given volume at fixed pressure, you would have twice as many hydrogen atoms as you would heliums, so that brings the difference in weight down to 1/2.
Secondly and more importantly, it's not actually the weight that counts. (Please if I've got this wrong, correct me, this is just from me thinking about it) The important thing is the difference in weight between e.g. a liter of air and a liter of helium/hydrogen.
Air is mostly nitrogen which has mass no. 14. This means that 1 mole of N2 molecules weighs 28g. A mole of any gas occupies 24 liters at STP so air weighs about 1.17 g per liter. Running the numbers for He and H2 gives 0.16 and 0.08 respectively.
Now, looking at the difference in weight, which is what determines buoyancy, helium gives about 1.01 g per liter while hydrogen gives 1.09 g per liter. Not such a big difference after all! I think that the advantage of non-flammability probably outweighs this minor difference in buoyancy. On the other hand, it may very well be easier and cheaper to produce hydrogen in bulk than helium.
Re:Cost to orbit (Score:5, Informative)
In all likelihood, it was the flammable nature of the skin that led to the ignition. Sure, having all that hydrogen there didn't help once the fire started, but there were a lot of successful hydrogen-filled blimps and dirigibles up to that point (the survival ratio was at least as good, if not better, than that of hydrazine or solid-propellant rockets).
Re:Cost to orbit (Score:3, Informative)
It's much worse than that. In order to make it look better, they covered the skin with a mixture of iron oxide and aluminum powder. That's right, boys and girls, they covered it with thermite! No wonder it burned so fast!
What's that hissing sound? (Score:3, Interesting)
Pop, pop. Hiss, hiss, oh what a release it is.
Sorry, I can never resist a dumb joke
Not a dollar a ton... (Score:3, Interesting)
Re:Cost to orbit (Score:5, Insightful)
They're almost certainly dynamically stable in position and tension.
I wish ignorant people would stop saying that, too.
It's going to be a thin ribbon of probably carbon nanotube fibers. How much ribbon do you need to drop on someone to hurt them?
Common retort: Oh, but it's falling from orbit
What is the terminal velocity of a strand of ribbon? Do you have a one story building's roof available to demonstrate this to yourself?
Most of it, falling down, will burn up in the upper atmosphere. That which does not, will fall so slowly by the time it reaches ground level as to pose no threat to anyone on the ground, unless you tangle yourself up in it after it lands or it happens to catch an airplane on the way down.
Screaming terror scenarios of huge swaths of land ruined by explosive impact are bad science fiction not fact. No competent professional has ever said such a thing. It just plain will not happen.
Re:Cost to orbit (Score:5, Interesting)
While I tend to agree with your overall claim, this particular comparison doesn't seem all that straightforward. That's the terminal velocity of an infinitesimal fragment of the overall tether.
Small pieces tend to flutter in the breeze. Would a mile's length of tether also flutter? Much less so, at least in the middle, since any given small length of the tether would need to pull on the parts above and below it to move out of position. I'd be interesting to see a computer simulation of this.
Re:Weight, profile and wind (Score:4, Insightful)
Yes, it does. And it did to the people who looked at the space elevator as well. The Tacoma Narrows bridge fell because the period of its resonant frequency happened to be close to a naturally occurring oscillation.
In order for resonance to be a serious problem, the induced oscillation has to occur over the entire object, and it has to be close in period to the natural frequency of the object.
The fundamental period of the space elevator is 7 hours. There's nothing which occurs on the full scale of the elevator (hundreds of thousands of kilometers) which is near to 7 hours.
So induced oscillations aren't a worry.
(Wind oscillations are a non issue if they don't rip the ribbon. The ribbon is huge. The atmosphere is just a tiny sliver compared to its full length.)
Re:Weight, profile and wind (Score:3, Interesting)
The wind at the bottom will act more like a violin bow, and the harmonics of the primary mode of vibration (i.e., all the multiples of f=1/(7*3600) cycles/second) will be induced into the cable in the stable state.
These vibrations won't be simply transverse, but helical as
Re:Cost to orbit (Score:3, Funny)
African or European ribbon?
Only since 2002? (Score:5, Interesting)
x-prize (Score:5, Interesting)
Re:x-prize (Score:2)
That was exactly my response. Amazing. Why hadn't anyone thought of this before!
Oh the humanity (Score:4, Funny)
"Now, the object of this expedition is to see if we can find any traces of last year's expedition."
Re:Oh the humanity (Score:5, Funny)
Re:Oh the humanity (Score:3, Informative)
NOT a dollar/ton (Score:5, Informative)
Incase there are actually people not reading the linked article, the interesting part is quoted here:
Re:NOT a dollar/ton (Score:5, Insightful)
Re:NOT a dollar/ton (Score:4, Funny)
Re:NOT a dollar/ton (Score:2)
Re:NOT a dollar/ton (Score:2, Informative)
Re:NOT a dollar/ton (Score:3, Informative)
The U.S. definition is 50 miles high (80 km). The FAI uses 100 km (62 miles).
Mercury 3 (Freedom 7) reached 186.2 km (115.7 miles) at its greatest distance from Earth, while Vostok I perigeed at 169 km (105 miles) and apogeed at 315 km (196 miles) in its orbit.
The exosphere goes out to 10,000 km (6213 miles); the only humans to ever go beyond it were in Apollo mission 8 and 10-17.
Re:NOT a dollar/ton (Score:5, Informative)
Too good to be true. (Score:2)
Sorry but that just stinks of "too good to be true". What about the cost of the blimp, gas, maintenence, workforce, insurance, and everything else.
$100/ton/mile sounds like something real but this, I don't know.
Re:NOT a dollar/ton (Score:5, Funny)
Can I have a Giraffe? (Score:5, Funny)
Re:Can I have a Giraffe? (Score:2)
Ads in space? (Score:2)
It... is... BALLOON! (Score:3, Insightful)
Crossing fingers that this won't lead to another.. (Score:3, Informative)
Fortunately this time we should have the sense not to paint the blimps with highly flammable doping.
Couple of things... (Score:5, Interesting)
Second, LEO isn't just *up*, it's also speed that keeps you falling back to earth. That kills the up-fast-down-fast idea. Are these space blimps (inflatible tech! Dr. Schlock would be proud) going to manage to accelerate a load from a relative standstill to LEO speeds using an ion engine (which has very weak acceleration) in just a few days? Unless I'm missing something, that doesn't seem very likely.
That aside: Cool idea. This sort of infrastructure wouldn't be as awesome as a space elevator would be, but it sure seems a hell of a lot more likely (cheaper, safer, possible without huge leaps in materials, etc). Once you're moving tons of material to orbit for a very small price (costs more to ship something across the ocean!), it seems like space exploration is ready to take off (no pun inte... oh, who am I kidding?) in a very real way.
Re:Couple of things... (Score:5, Informative)
Re:Couple of things... (Score:2)
a few days... a few weeks... does it really matter? It still gets you to LEO for peanuts.
Re:Couple of things... (Score:3, Funny)
Congratulations on working a Sluggy Freelance [sluggy.com] reference into your post!
I'm also bitter because I was too late to do it first.
Fear the rabbit!
Blimp Cruises (Score:5, Interesting)
Imagine the view...
Seriously, this is a good stepping stone to space tourism.
Re:Blimp Cruises (Score:2)
9 days might be a bit long though -- 18 day round-trip? That, and when you get to LEO
Probably not X Prize contenders. (Score:3, Insightful)
Hopefully this solution will be developed and used commonly when fats times to orbit aren't a must.
Re:Probably not X Prize contenders. (Score:5, Funny)
Great... (Score:5, Funny)
WTF? (Score:5, Interesting)
Can you really accelerate a big inflated condom to escape velocity with an ion drive? I mean, it can only get so high on He, and I'm assuming that at its apogee there will still be an appreciable amount of atmosphere. Would an ion drive be able to overcome the drag force? Anyone willing to do the math?
Re:WTF? (Score:5, Informative)
First, escape velocity is about getting you permantly out of earths gravity well. Not something you want if your destination is a stable orbit around the earth.
Second, escape velicity is a ballistic value, ie. the speed required to kick your butt off the planet from ground level going straight up.
Third, pushing "a big inflated condom" around in the upper atmosphere is not really a problem since there isn't much air to create drag.
Further, the higher you go, the less drag you feel, hence the "launch" of the orbiter from a platform already 20 miles up.
This one isnt going to be easy (Score:2)
I wish them well, but I'm not holding my breath.
I'm a bit confused by this statement: (Score:5, Interesting)
That trip to LEO would take up to nine days, but that's a good thing; for, what goes up fast, must come down fast
What goes up fast must come down fast? Unless I'm missing something, low earth orbit still means going several thousand miles an hour. The rate you ascend at has nothing to do with how quickly you'd come down at.
Up-fast-down-fast? (Score:5, Insightful)
Advanced Materials (Score:3, Interesting)
Recall in the very beginning where the Vickis are riding in a blimp where the bag is full of vaccum instead of any gas? It seems to be that this would be an elegant one-stage-to-orbit vehicle, since you don't have to worry about things like gas expansion.
Anybody care to take a guess as to what sort of advanced materials would be needed for this sort of structure?
Re:Advanced Materials (Score:4, Interesting)
This is different than a gasbag put into a vacuum. Stephenson's blimps were under compression, and the proposed blimp-in-space is under tension.
Compression's a bitch. Holding a 500-foot-dia sphere in enough equalized compression to avoid buckling and collapse is insanely difficult, which is why nanotech was the narrative used to justify it. But tension? Ha, tension's a walk in the park particularly for materials formed into skins.
Just eyeballing it, we have more than enough common materials like mylar that can produce a gasbag of sufficient size (i.e. common Goodyear blimp). If the tension proves too much for mylar, then some strenghtening can be done like sail makers do all the time, with carbon-fiber thread wrappings, etc. But my rule-of-thumb gets hazy for things that are kilometers in size under the gas pressures they must contain, since tension rises appreciably with the radius of curvature.
Pong Stats (Score:3, Funny)
Balls: Sent = 2002, Received = 1001, Lost = 1001 (50% loss)
Striving to be common [blogspot.com]
9 days to LEO (Score:3, Interesting)
Odd economics... (Score:3, Funny)
Might be a stupid celestial mecannic question but: (Score:3, Interesting)
In other word you would only need to lift a far smaller rocket up there , orient it correctly, and have it put payload easily in space. Thus far less cost in needed boost overall. Am I missing something ? Is it a naive thinking ?
Re:Might be a stupid celestial mecannic question b (Score:3, Informative)
It's naive thinking. (The same kind of naive thinking leads to proposals for air breathing first stages.)
No matter how far *vertically* you lift something, you still need significant *horizontal* velocity in order to reach, and stay, in orbit. Blimps get you high, but not fast.
RTFM... (Score:4, Informative)
Here are the details:
Atmospheric airship with crew of three takes payload to 140,000 ft. Airship uses lift and buoyancy, and driven by propellers designed to operate in near vacuum.
Dark Sky Station (DSS) at 140,000 ft. Permanent, crewed facility.
Airship that flies from DSS to orbit. Over a mile long. Uses buoyancy to climb to 200,000 ft. From there uses solar/electric propulsion to reach orbital velocity over several days.
Continuing to use solar/electic propulsion, it can keep on going to anywhere in the solar system.
Several "DSS" platforms have been flown. All equipment has been flown at 100,000 ft. and tested in the environment. Ion engine tests of the orbital airship at 120,000 ft. will occur in the next five months.
Every segment of the plan has funding. DoD is funding the atmospheric airship for reconnaissance. Telecom companies are funding DSS.
NOBODY'S SEEN THE IMPLICATIONS? (Score:5, Interesting)
If enough money is put into the project, we can start space industrialization in a year or three, we don't have to wait until we find out if the space elevator is actually possible, we don't have to build giant rail guns for cheap space launches if the Elevator is unworkable.
It's time to start work on actually building Space Power Satellites at the "proof of concept" level. For more info, click here [ecis.com]
Re:NOBODY'S SEEN THE IMPLICATIONS? (Score:3)
This suggests that it's time for NASA to get out of most of the space transportation business and fund this instead.
Given that money spent on a transportation and platform system that is almost a slam-dunk (a big-D sort of R&D project), NASA should then refocus its priorities onto getting the "proof of concept" demo for the Space Power Satellite system together and the lunar industrial facilities which will
As someone else noted... (Score:3, Funny)
Been done. (Score:3, Funny)
Space cruise? (Score:4, Interesting)
Figure a fully outfitted luxury passenger module, including oxygen and other facilities, is ten tons per passenger.
That's $200 per passenger to get to the "edge of space", or $9000 per passenger for low earth orbit.
Space cruises for civilians now become feasible.
Pretty exciting.
No way. Unfortunately. Way too much drag (Score:4, Informative)
If the ship was, say, 50 ft wide and had a rediculously low drag coefficient of
where
rho is density (about 1.7x10^-5 slugs/ft^3)
Cd is
V^2 is velocity squared. At 5000 fps, that's 2.5x10^7
A is area, 50 ft
This yeilds a drag of a little more than 100 lbf.
The most powerful ion engine is Nasa's new HiPEP [nasa.gov] that has a thrust of about 1/10th of a pound.
Now, I'm a big fan of JP Aerospace, and wish them all the luck in the world. Their program of launching sounding rockets from high-altitude balloon platforms was quite exciting. Hypersonic blimps, though, are just not going to happen.
Thad
Re:No way. Unfortunately. Way too much drag (Score:4, Funny)
Re:No way. Unfortunately. Way too much drag (Score:3, Informative)
Yes, I know you won't get aerodynamic lift without air, so there will be some drag, but your back-of-envelope calculation doesn't tell enough of the story to know if it's a showstopper.
My question i
Re:No way. Unfortunately. Way too much drag (Score:3, Informative)
Gravity in the blimp space station (Score:5, Interesting)
Furthermore, it's not like poeple haven't flown up to 100,000 feet up in balloons; what becomes technically interesting is building a permanent or semi-permanent station as a balloon at that altitude.
The best part is that the worlds record for the highest skydive is above that altitude. So theoretically in the case of a catestrophic emergency, people could simply get into their skydiving space suits, and jump.
Re:LEO? (Score:3, Informative)
Definition... (Score:2)
Re:LEO? (Score:4, Funny)
Re:LEO? (Score:3, Interesting)
Re:Potential for a disaster (Score:5, Informative)
Re:Potential for a disaster (Score:5, Insightful)
Man, I'd hate to be in the blimp industry. Give a dog a bad name, or what? One big accident almost seventy years ago and every time somebody suggests a blimp as a solution to anything, everybody assumes it's a fiery disaster waiting to happen. It's as if we'd all given up on ships after the Titanic.
Re:Potential for a disaster (Score:3, Informative)
Hindenburg, anyone?
No oxygen to burn?
Helium, not hydrogen?
In the Hindenburg it was the blimp material and not the hydrogen that caused the flames?
Ignorant Comment Of The Week, anyone?
Re:Altitude != orbit -- The beginning of the end (Score:5, Informative)
Re:Crap? (Score:3, Interesting)
Re:Crap? (Score:5, Informative)
First, they're talking about 20 miles up for this two-mile 'lily-pad'. At 20 miles, we still have atmosphere, so we still have buoyant(sp) forces acting. Since there's a buyoant(sp) force at work, orbital mechanics can be damned. Your airship doesn't fall back to Earth because it's lighter than air.
Are you with me, then? You have a lovely two-mile long launch platform. From here, you launch another, smaller balloon with even less density and a few ion engines. This smaller balloon floats up as high as the remaining atmosphere allows. At this point, we'll say that the balloon is 'floating' on the very top of the Earth's atmosphere. It won't go down (buyoant[sp] force) and it won't go up (gravity). At this point, as long as the ion engines can beat the force of gravity, you have acceleration.
Acceleration, even small amounts of it, mean a lot in a vaccum. Give it a couple weeks and you'll find yourself speeding along at 8 km/s. Let go of the object you want in orbit and use the same ion engines to slow down. Physics being what they are, you should wind up back where you started with the same amount of velocity as when you left. At which point, you'll be 'floating' on the top of the Earth's atmosphere and you can manipulate your airship to get back down to the 20-mile-high 'lily-pad'.
Re:Crap? (Score:3, Informative)
At this point, we'll say that the balloon is 'floating' on the very top of the Earth's atmosphere. It won't go down (buyoant[sp] force) and it won't go up (gravity). At this point, as long as the ion engines can beat the force of gravity, you have acceleration.
Wrong! As long as the ion engines can beat drag, you h
Re:Crap rockets? (Score:3, Informative)
The problem with getting to orbit isn't altitude, it's velocity. From your handy-dandy high-school physics book: E_altitude = mgh (mass times gravity times altitude) = 1 kg * 9.8 m/s2 * 100 km = 9.8*10^5 J. Whereas kinetic energy is E_kinetic = 0.5*m*v^2 = 0.5 * 1kg *(
Re:Helium non-renewable (Score:4, Informative)