Reaction Engines To Fly Reusable Spaceplane

RobGoldsmith writes "Reaction Engines have designed a 'reusable spaceplane' to provide inexpensive and reliable access to space. The Star Wars-looking 'Skylon' reusable spaceplane has already been designed and the team are well into engine testing. They have taken some time out from building spaceships to talk about their background, their goals, and their recent engine tests. This article shows new images of their STERN Engine, an experimental rocket motor which explores the flow in Expansion Deflection (ED) nozzles. They also discuss their Sabre air-breathing engine technology. View the Skylon Spaceplane concept, the STERN Engine and much more in this in-depth interview with the team."

Dollars per kg?

[rift321]

Can anyone find a cost per kg (or lb) of cargo estimate on that website? Not trying to detract from its value, just wanted it for comparative purposes.

Re:Dollars per kg?

[denzacar]

From http://www.reactionengines.co.uk/skylon_dev.html [reactionengines.co.uk] :

The total development program will cost about $10 billion.

Also... http://www.reactionengines.co.uk/skylon_vehicle.html [reactionengines.co.uk]

Skylon Statistics

Length: 82m
Fuselage Diameter: 6.25m
Wingspan: 25m
Unladen Mass: 41,000kg
Fuel Mass: 220,000kg
Maximum Payload Mass: 12,000kg

At the start of the take-off roll the vehicle weighs 275 tonnes, whilst maximum landing weight is 55 tonnes.
At take-off the vehicle carries approximately 66 tonnes of liquid hydrogen and approximately 150 tonnes of liquid oxygen for the ascent.
.
.
.
Payload Capabilities

The Sklyon payload bay is 4.6m diameter and 12.3m long. It has been designed to be compatible with expendable launcher payloads but in addition to accept standard aero transport containers which are 8 foot square in cross section and 10, 20, 30 or 40 feet long.
It is anticipated that cargo containerisation will be an important step forward in space transport operations, enabling the "clean" payload bay to be dispensed with.

The vehicle can deliver 12 tonnes to a 300km equatorial orbit, 10.5 tonnes to a 460km equatorial spacestation or 9.5 tonnes to a 460km x 28.5 deg spacestation when operating from an equatorial site.

You do the per flight math.

Re:

[khallow]

Problem here is that they don't (like virtually everyone in the business world) throw out costs for the launches themselves. Still a development budget of $10 billion indicates to me that they're expecting operating profit to be somewhere around $1-2 billion a year. Suppose they make a profit of $10 million average per flight (that's $1000 profit per kg or so). That means 100-200 flights per year. If the profit is only a tenth that, then they have to make 1000-2000 flights a year.

Re:

[Rakishi]

You also need to add in maintenance, staff (someone has to manage and test this thing), facilities (you're housing and launching it where?), fuel, insurance and other such costs.

Also there are only something like 20 commercial satellite launches a year and I think that includes geosynchronous orbit ones. Maybe you could double that if you add in government satellites but it's still not much.

Re:

[khallow]

Yes, lot of stuff needs to be added. At a glance, it looks like they can use a convention runway (though it might need to be reinforced, apparently a loaded vehicle generates a lot of impact on landing). Insurance isn't much of a cost for the launch provider. Insurance against third party harm is rather low since US launch providers need to demonstrate a ridiculously low risk of harm before they can launch anyway. Insurance for the payload should be pretty good for an RLV with the kind of launch frequency t

Re:

[CrimsonAvenger]

it looks like they can use a convention runway (though it might need to be reinforced, apparently a loaded vehicle generates a lot of impact on landing).

Even fully loaded, this vehicle is better than 150 tons lighter than a 747. Much less at its designed landing weight (about 1/8th the takeoff weight of a 747). So I doubt the runway will need reinforcement.

Re:

[khallow]

Problem is the narrowness of the vehicle. Up to 273 tons concentrated in a narrow band. They even mention it on the website (which is why I brought it up, wouldn't have thought about it on my own). And an abort and return to airport shortly after takeoff would result in a fully loaded landing. That has to be part of the design as well.

Re:

[CrimsonAvenger]

Problem is the narrowness of the vehicle. Up to 273 tons concentrated in a narrow band.

Width of the undercarriage might be an issue, but probably not. The entire vehicle puts a load on a narrow strip of runway only slightly higher than the load that either side of a 747's undercarriage put on a runway (273 tons versus 220 tons per side). While reinforcement might be desirable, doesn't look to be mandatory.

And an abort and return to airport shortly after takeoff would result in a fully loaded landing. Tha

Re:

[AJWM]

The 747 is a heavy beast indeed. In the early days of autoland systems (heavily used at airports that tend to be foggy, like Heathrow), the accuracy of the autoland system was so good that the 747s kept touching down on the same spot on the runway, overstressing that one spot. They fixed it by adding some slight dither to the autoland to spread the impacts out.

The landing gear for a 747 uses more wheels than Skylon which reduces the 747 point loads (in terms of PSI).

Re:

[AJWM]

I think the DC-X, an unmanned prototype (for SSTO eventually) had composite tanks. There were serious problems with thermal flexing and penetration by cryogenic fluids that weakened the tanks.

No, DC-X had metal tanks (I forget whether straight Al or Al-Li). You're thinking of the X-33 (VentureStar prototype), that not only had composite tanks but the hydrogen tank was V shaped, putting extreme stresses on the joint (and leading to the flex/leakage problems). Reinforcing that joint overwhelmed the weight

Re:

[cheesybagel]

DC-XA had an Al-Li Oxygen tank and a composite LH2 tank. The think that fscked up X-33 was indeed the shape of the tank in combination with the composite material picked. It was heavier than using Al-Li in the first place.

Re:

[WindBourne]

THe hard part is that we did this already; The shuttle had the same issue.

Re:

[khallow]

THe hard part is that we did this already; The shuttle had the same issue.

The Shuttle had serious issues aside from lack of demand (it would take the entire US launch market to achieve the design launch rate of 50 launches per year for the Shuttle). Particularly, the 1-2% failure rate and the monstrous overhead. These guys are hoping that they can get the operating costs down to a very cheap level, achieve a high reliability rate, *and* that the launch market will improve significantly to the point that by the time the vehicle flies, they can find enough demand for the vehicle.

Re:

[trenien]

It may be naïve of me, but wouldn't there be a huge difference between development cost and construction cost?

What's keeping them from buildng more than one unit?

Re:

[khallow]

I completely ignored construction cost. It gets a lot more difficult once you take that into account. The point is, if you spend $10 billion on something risky, you are expecting considerable return. A constant rate of 20% per year in the not so distant future isn't unreasonable and may be low given the circumstances. Or maybe some sort of high growth effect (low or negative rate in the near future with huge growth rate years later), say if they built an large number of these for market a number of years af

Re:

[CarpetShark]

The vehicle can deliver 12 tonnes to a 300km equatorial orbit, 10.5 tonnes to a 460km equatorial spacestation or 9.5 tonnes to a 460km x 28.5 deg spacestation when operating from an equatorial site.

You do the per flight math.

I'm more worried about the fact that it can only go in two directions: to the equator, to to 28.5deg.

Holy shit, it's a proto-Firefly!

[Dr. Spork]

I never thought that the Firefly form factor would ever actually fly, but look at the picture of the Skylon and tell me you don't see the resemblance!

SR-710?

[Mateorabi]

Actually I see more of an SR-71 Blackbird with a fat tail. Can really see it here [reactionengines.co.uk] from above.

Re:

[S-100]

Looks to me more like the ship in George Pal's "When Worlds Collide": http://www.imdb.com/media/rm3091372032/tt0044207 [imdb.com]

Re:

[hcdejong]

Actually, it looks more like the Avro 730 concept for a high-speed reconnaisance aircraft. Including the four engines at each wingtip.
image [bisbos.com]

Re:

[Timesprout]

I dont see the resemblance. Anything else I can help you with?

Re:

[EdIII]

I wish I could see any picture of it. Those sites have been Slashdotted :)

Re:

[Wandering Wombat]

Uhm... they made this 15 years ago. It was called the Venturestar. They had all the bugs worked out. It was cheap.

Re:

[AJWM]

VentureStar was never anywhere near having all the bugs worked out. It was way over budget.

In addition to the above-mentioned problems with the V-shaped composite tank, the launch/landing profile (vertical takeoff, horizontal landing) meant that the structure was designed for perpendicular load paths, and there was no way to land after a launch abort until it had reached sufficient altitude/airspeed to turn around and return, and it had burned off/dumped enough fuel to be light enough for the landing gear

Oh, not bad! Not bad, huh? A Nubian, huh?

[slyborg]

Watto like!

http://starwars.wikia.com/wiki/J-type_327_Nubian_royal_starship [wikia.com]

Did anyone else misread the title?

[Amazing Quantum Man]

Reaction Engines is the name of the company. It's using conventional LOX/LH2 engines.

And for those who are calling this Shuttle 2.0, it's unmanned.

Re:

[rift321]

They allude to the ability to _shuttle_ persons into space later down the road using the craft, and specifically state that they aim to bring the cost of such an endeavor to the sub-$100k range.

Re:

[SoupIsGoodFood_42]

From what I've read, they aren't conventional rocket engines. But if you know better, then please explain.

Re:

[Hal_Porter]

They are anything but conventional. They run as an precooled jet engine [wikipedia.org] upto Mach 5.5 breathing air from the atmosphere and then close an inlet and run as a rocket using onboard liquid oxygen as an oxidizer.

http://en.wikipedia.org/wiki/Reaction_Engines_SABRE [wikipedia.org]

Re:

[Hal_Porter]

Reaction engines do have a design for a manned hypersonic airliner

http://en.wikipedia.org/wiki/Reaction_Engines_A2 [wikipedia.org]

The A2 is designed to leave Brussels International Airport, fly quietly and subsonically out into the north Atlantic at Mach 0.9 before reaching Mach 5 across the North Pole and heading over the Pacific to Australia. ...

The developers say it would be able fly from Brussels to Sydney in about 4.6 hours.

enough propellant?

[khallow]

It doesn't seem to have enough propellant mass for the task. To get to LEO, it needs something like 7.5 km/s or more in delta v (ignoring very substantial gravity and air resistance losses). If it were purely a rocket, that would be roughly 7.2 km/s (rocket equation is delta v = -4420 m/s*log(53 tons/273 tons), where 4420 m/s is perfect exhaust velocity in vacuum for LOX/LH2 burning rockets). Even if we assume we can get to Mach 5 for free (which is 1.5 km/s roughly), that leaves no more than 1.2 km/s margin. A regular rocket picks up 1.5-2 km/s or so in gravity and air resistance losses. While gravity losses might be somewhat lower (due to lift), air resistance is definitely going to be higher than the 100-200 m/s a rocket of similar size would have. So we have gravity and air resistance losses. We also have probably an inefficient nozzle design with a tradeoff between greater bell size (and efficiency in vacuum) and lower air drag. Something like drop tanks would help a little, but there doesn't seem to be the space for a lot of extra mass there. Another possibility is to use denser fuel in place of LH2 for the early parts of the flight, but that weakens the isp a little.

Re:enough propellant?

[evanbd]

You can get slightly better Isp than that, actually. For example, I get 4664 m/s vacuum Isp for O:F of 6:1 and 3000 psi expanded to 1 psi. I don't know what pressure they run at, but for a wide altitude range I would imagine it's high. Furthermore, I believe they plan to still be using some outside air even at Mach 5 -- and at that altitude, they've also got some delta-v in the altitude itself, not just the velocity. Small effects, but they help... Anyway, I don't know the details of their flight plan, but I do know that the engineers behind it are decidedly competent, and do have a detailed trajectory plan that includes good estimates of air drag and such. If you can find trajectory details, though, I'd love to see them...

(Oh, to pick a few nits about your dv budget... 7.2 km/s is orbital velocity; don't forget nearly 500 m/s of Earth rotational velocity. So if you ignore air and gravity drag, it's actually slightly under 7 km/s total delta-v, though air and gravity drag will usually add more than 2 km/s to that.)

Re:

[khallow]

(Oh, to pick a few nits about your dv budget... 7.2 km/s is orbital velocity; don't forget nearly 500 m/s of Earth rotational velocity. So if you ignore air and gravity drag, it's actually slightly under 7 km/s total delta-v, though air and gravity drag will usually add more than 2 km/s to that.)

7.5 km/s is orbital roughly. Still leaves up to 1.7 km/s which is pretty tight. OTOH, the payload could be a second stage, which gets you neatly around the problem.

Re:

[MichaelSmith]

(Oh, to pick a few nits about your dv budget... 7.2 km/s is orbital velocity; don't forget nearly 500 m/s of Earth rotational velocity. So if you ignore air and gravity drag, it's actually slightly under 7 km/s total delta-v, though air and gravity drag will usually add more than 2 km/s to that.)

7.5 km/s is orbital roughly. Still leaves up to 1.7 km/s which is pretty tight. OTOH, the payload could be a second stage, which gets you neatly around the problem.

Yeah I think a spaceplane should never go into orbit. Instead it should make suborbital hops. Non-aerodynamic payloads could be exchanged during the ballistic part of the flight.

Re:

[MarkRose]

You can get slightly better Isp than that, actually. For example, I get 4664 m/s vacuum Isp

DUDE!!! You must have a ton of warez!! Where can I sign up for Vacuum Isp?? My ISP suck0rs!! Im lucky if I get 3 Mb/s, but ur getting 4664!! NO FAIR!!!!1!

Re:

[khallow]

My ISP suck0rs!!

Be careful what you ask for. No matter how bad your ISP is, it can't suck0rs as much as *vacuum* ISP.

Re:

[dkf]

Be careful what you ask for. No matter how bad your ISP is, it can't suck0rs as much as *vacuum* ISP.

Don't forget black-hole ISPs. They suck nearly as much as... hmm, what a choice...

Re:enough propellant?

[StevePole]

A friend of mine works on the heat exchange system for the SABRE engines that will power Skylon. The SABRE engines are air breathing i.e. they use air they pick up on the way as fuel, hence they need less fuel at launch.

From their website: "The Sabre engine is essentially a closed cycle rocket engine with an additional precooled turbo-compressor to provide a high pressure air supply to the combustion chamber. This allows operation from zero forward speed on the runway and up to Mach 5.5 in air breathing mode during ascent. As the air density falls with altitude the engine eventually switches to a pure rocket propelling Skylon to orbital velocity (around Mach 25)."

More info here: http://www.reactionengines.co.uk/sabre.html [reactionengines.co.uk]

The engine saves weight by using the same combustion chamber during both modes of operation and in air breathing mode it only cools the oxygen to it's vapour point (as opposed to full liquidization) which greatly simplifies the engine design.

At least that's my understanding, IANARS.

Re:

[khallow]

Yes, that's pretty much what I gathered from looking at the design, especially the odd-shaped, untapered outlets for the Sabre engines and the fact no other nozzles appear anywhere on the ship.

The engine saves weight by using the same combustion chamber during both modes of operation and in air breathing mode it only cools the oxygen to it's vapour point (as opposed to full liquidization) which greatly simplifies the engine design.

This sounds like quite an effort. Would like to see if it works out. Recently, I was discussing a scramjet design [nasaspaceflight.com] with the internet:

tnphysics: The key to a gas-and-go SSTO RLV IMO is airbreathing engines-somewhat like the Forerunner V business jet proposed somewhere on the forum (afterburning ultra-high-bypass turbofan to Mach 8, then LNG scramjet to Mach 15, then switch to LH2 to Mach 20), with a small rocket added for EOI. A metallic TPS should be used.

At the time, I recommended reducing the complexity of the vehicle by eliminating the air-breathing turbofan at the start and using the rocket instead to get the vehicle up to scramjet spe

Re:

[RocketGeek]

We also have probably an inefficient nozzle design with a tradeoff between greater bell size (and efficiency in vacuum) and lower air drag.

That's why we are developing the ED nozzle :-)

The ED nozzle is a very efficient nozzle design and provides altitude compensation across the thrust operation range. Part of the engine development at the moment is concerned with development of the ED nozzle for this purpose.

Re:

[khallow]

Hmmm, the problem I was thinking of was in pure vacuum. Does the pintle (adjustable central obstruction in the nozzle) improve performance in vacuum? Seems to me that if you wanted almost perfect ISP, you still need a high expansion bell on your nozzle.

Re:

[Plekto]

It doesn't necessarily have to make it to orbit, though. If its goal is to merely drop a payload into space and then come back down, there's a small window for it to unload the object before it starts to drop back down. The question is whether we're talking about an hour or so or minutes.

I suspect that they plan to have the payload have its own small engine to do the final positioning and get up to orbital speeds. 5% change it actually works. It looks fancy, but seems to me to be yet another company th

Re:

[khallow]

Quite true about the RLV. It should also be good for suborbital flights.

Loads of good intentions but little likelihood that it will actually work. (see SpaceX for a perfect example)

SpaceX is perfect example of what? 1) They don't troll for rich investors, 2) they actually work (I know, 1 out of 4 sucks, but it's a lot better than 0 out of 0), 3) they're getting some serious contracts.

Sky-Lon?

[pcgabe]

Sounds like a Skynet-Cylon joint venture. Please don't be sinister-looking....

*Opens link*

Ah, crap.

"Star Wars-looking"

[GPS Pilot]

The resemblance to Queen Amidala's "Naboo Cruiser" is remarkable.

http://www.galacticempiredatabank.com/NabooCruiser1.jpg [galacticem...tabank.com]

Coincidence?

does this add up ?

[freddy_dreddy]

from this presentation [space.co.uk]:
- air intake in the order of hundreds of kg per second (400 kg/s to quote) ...
- passes through thousands of small tubes (resistance at that speed ?!?) ...
- in a few milliseconds ...
- cooled from + 1000degreesC to -150degreesC

Forgive me my ignorance, but are these materials physically possible ?

Re:

[freddy_dreddy]

Thanks

George Lucas copyright?

[VincenzoRomano]

Hmmm ... I would suggest GL to sue that company for (R) infringement!
And later (from a galaxy far far away) the Empire will sue GL!

Still going?

[jeroen94704]

Reaction Engines Ltd have been working on this for well over 10 years now (maybe closer to 20) with not a lot of actual hardware to show for it. I first heard about Skylon when I was still in uni, around 1996 or so, and not much has happened since. So while the Skylon design is inordinately cool, with some very nifty and innovative features, I'm afraid it's never going to actually fly.

Sad, really, as it's one of Europe's few contenders in the non-gov space race, and probably the most promising one, in ter

Re:

[Stoutlimb]

It might fly, but will it stand the heat of re-entry? There doesn't seem to be any heat shielding at all. I'm wondering how it's not going to disintegrate?

Re:

[account_deleted]

Comment removed based on user account deletion

a 21st Century DC-3

[alizard]

From what I saw at the company website, it looks like they're building the orbital equivalent of the first commercial airliner, the DC-3.

If they can get the cost to orbit even remotely close to the $200/kg number the Space Power Satellite program proposed by NASA was based on, we could either build a full system or a large proof of concept orbital power array. We're a bit more desperate for power than we were when Bush defunded the SPS project. The launch capability is the hard part of SPS, the rest is just engineering we know how to do.

That could take up enough launches to provide the company a reasonable chance at profit.

Re:

[YourExperiment]

From what I saw at the company website, it looks like they're building the orbital equivalent of the first commercial airliner, the DC-3.

Cool. Now if we can just scale up to build space DC-8s, we can take all the scientologists to another planet and drop them in a volcano.

Re:

[rarel]

From what I saw at the company website, it looks like they're building the orbital equivalent of the first commercial airliner, the DC-3.

Bit of a nitpick here, but that would be the first tremendously successful commercial airliner.

The DC-3 was an evolution of the DC-2, which was designed to compete with Boeing's 247. The 247 itself was preceded by a bunch earlier designs by various constructors, like the Ford Tri-Motor.

HOTOL?

[footnmouth]

Hmm... as I'm getting old I thought I remember this concept as HOTOL, and sure enough: wikipedia [wikipedia.org] Reaction engines was started by one of the HOTOL designers. Still, it's had probably 30 years of intellectual development and it looks believable to me. Go Reaction Engines.

Whilst

[necro81]

Skylon will be able to repay its development costs, meet its servicing and operating costs and make profits for its operators whilst being an order of magnitude cheaper to customers than current space transportation systems.

Can I trust my payload and/or investment dollars to a company that uses "whilst" on their site? [reactionengines.co.uk]

Reaction Engines To Fly Reusable Spaceplane

[John Hasler]

There's another kind? Tell me more!

Re:

[khallow]

Do not want shuttle 2.1. Do want Space Elevator. Now get to work.

Are you personally picking up the tab for this space elevator? Even an RLV doesn't have much of a business case to be made. There simply isn't that much demand. A space elevator needs a lot more demand than has been demonstrated to exist. A reasonable plan is to build up the demand to the point that exotic launch systems make business sense. Not develope the exotic launch system and hope someone will use it.

Re:Space Elevator

[barc0001]

You know, the day Sputnik went up hardly anyone was thinking about a commercial use for space, and now look at us. Space has definitely become a "build it and they will come" scenario. If you make payload lifting even cheaper, there will be more customers because things that didn't make sense before suddenly start to.

Re:

[khallow]

You know, the day Sputnik went up hardly anyone was thinking about a commercial use for space, and now look at us. Space has definitely become a "build it and they will come" scenario. If you make payload lifting even cheaper, there will be more customers because things that didn't make sense before suddenly start to.

There was around an eight year lag between Sputnik 1 and the first commercial satellite. My take is that there wasn't enough business to support a commercial launch provider till sometime in the late 70's or early 80's. So it seems odd to me to build a space elevator and then wait 20 years for the elevator to become economically viable. My take is a superior approach is to increase launch demand and reduce launch costs on current and near future vehicles. That will in turn drive demand for RLVs, space eleva

Re:

[khallow]

Doesn't look like it was a commercial satellite. NASA and publically owned European organizations were involved. Though it did belong to AT&T which was nominally a private company at the time.

Belonging to AT&T, the original Telstar was part of a multi-national agreement between AT&T, Bell Telephone Laboratories, NASA, the British General Post Office, and the French National PTT (Post, Telegraph & Telecom Office) to develop experimental satellite communications over the Atlantic Ocean. Bell Labs also built the Andover Earth Station in Andover, Maine, and it held a contract with NASA, reimbursing the agency three million dollars for each of the two launches, independent of success.

Looks like COMSAT wasn't really commercial either. It was owned by Intelsat which didn't privatize till 2001 according to wikipedia [wikipedia.org].

The Internet

[mcrbids]

How many "2.0" Internet businesses exist only because of the unexpected consequences of humanity building the largest peer based computer network in existence?

Slashdot itself, and other newcomers like Netflix "on demand" only exist because of the Internet. Did we build the Internet so that we could stream "Superman" in real time, or argue politics with people from around the world?

No. but they all happened because we built the Internet!

So build it! Society will profit in ways we can't today imagine today any more than Bob Metcalfe imagined Slashdot when he co-invented Ethernet!

Re:

[khallow]

OTOH, we (or rather DARPA) built the Internet because there was at the begining a a demand for the internet. Namely a test stand for protocols and equipment that would maintain communications in time of nuclear war. Shortly thereafter, one of the most important applications to ever grace the internet was introduced, email [livinginternet.com]. If we threw up a space elevator today, what would we use it for? How would we pay the upkeep and operations for the elevator? What is the equivalent of "email", of the "web", etc and how

Re:

[hitmark]

another thing is that given how we humans are basically running this planet dry, there is only one way to go for future resources.

also, if we are able to spread out over the solar system, there is less of a likelihood that a single big rock will take us out...

Re:

[StrawberryFrog]

Space has definitely become a "build it and they will come" scenario.

Except with the space shuttle, which hasn't lived up to expectations.
And the ISS, which is behind schedule.
And the way that no-one has sent a manned mission to the moon in decades.

Re:

[Cowmonaut]

And what pray tell does that have to do exactly with what the OP said, of "if you build it they will come"? No one said this stuff had to come immediately. The space shuttle is the first re-usable spacecraft the US created. Many of the first escort fighters (Allison-engined P-51 mustangs [wikipedia.org] didn't live up to expectations either, nor did the first assault rifle for the US (M-16 before they lined the barrel and chamber with chrome [wikipedia.org]).

First and early attempts rarely tend to their tasks as well as people hope or

Re:What to do in orbit?

[Migraineman]

Honestly, I'm not being pedantic here, but exactly what are the "new" commercial applications that'll magically appear in LEO? Earth imaging? Yep, we do that already. Communications relays? Yep, from both LEO and GEO. Tourism? That implies a destination that doesn't exist yet, and obviates the "cargo" bias of the launcher. Note: "scientific research" isn't a commercial application nor is it a business model. It may be a necessary component, but the research phase is usually an expensive precursor to

Re:

[timeOday]

You know, the day Sputnik went up hardly anyone was thinking about a commercial use for space, and now look at us. Space has definitely become a "build it and they will come" scenario.

On the other hand, when we went to the moon it was emotionally a "giant leap for mankind," but it really didn't lead to anything or change anything in practice. Neither has the ISS paid off. Motorolla's Irridium communications constellation seemed incredibly awesome and well-timed, and promptly went out of business. How d

Re:

[Fulcrum of Evil]

Sure, nobody wants to lift cargo at the current price point. Try cutting it by 90% and see what happens.

Re:

[khallow]

Sure, but guess what? I bet even current launch vehicles can do a lot better in cost per kg than they currently do. I figure the limit of expendable launch vehicles are somewhere around $500 per kg in very high launch volume (thousands of launches a year). RLV would drive that to somewhere around $100 per kg. At that point, you have the business to justify that next step to exotic technologies like space elevators, rail launch, etc. This is the point that I think is being missed. There's little reason to fu

Re:

[Fulcrum of Evil]

Hey, if you think you can get those numbers, go ahead. I haven't seen anything other than a skyhook that does $100/kg. Also, once you have 2 skyhooks, you can build 20 while lifting cargo.

Re:

[khallow]

Hey, if you think you can get those numbers, go ahead. I haven't seen anything other than a skyhook that does $100/kg.

To be honest, nobody has seen anything that can do $1000 per kg much less $100 per kg. But once you get any launch system to the point where virtually all of the cost is reaction mass and energy, then it's going to be $100 per kg or lower. RLVs, skyhooks, and space elevators can do that. If your launch system only runs mass up to orbit, then RLVs remain rather competitive. The only weakness is that chemical motors have a much lower isp than what you can use in vacuum (where most of the space elevator and sk

Oh I forgot

[khallow]

Space elevators and sky hooks have an additional advantage over RLVs. All three can economically drop mass from orbit, but the tether systems can harvest the energy and momentum of orbital mass going to Earth's surface. This removes the last big restriction to cost to orbit. If there's some large quantity of sufficiently valuable mass in orbit to return to Earth, it might actually yield a negative cost to orbit for material coming from Earth. Eg, if putting a kilogram in space meant a kilogram of gold or ot

Re:

[EdIII]

There simply isn't that much demand.

There isn't a demand because there isn't a supply. That's like the argument, "Which came first, the chicken or the egg?"

I used to live with a little jack terrier dog that would crap all over the place. If there was a space elevator I would have used it.

Re:

[decoy256]

I think what he's saying is that we need to know in what ways we would be using the technology, so it at least has an economically viable proposal. Jack Terrier crap is actually one of those viable proposals that would have to be figured into the whole process... but if all evidence points to very limited use, then we would just be wasting money on a fruitless endeavor. Prove to me that this is economically viable (however you want to do that), and then I'll willing hand over my money. The other way around

Re:

[EdIII]

I think what he's saying is that we need to know in what ways we would be using the technology, so it at least has an economically viable proposal. Jack Terrier crap is actually one of those viable proposals that would have to be figured into the whole process... but if all evidence points to very limited use, then we would just be wasting money on a fruitless endeavor. Prove to me that this is economically viable (however you want to do that), and then I'll willing hand over my money. The other way around

Re:

[khallow]

There isn't a demand because there isn't a supply. That's like the argument, "Which came first, the chicken or the egg?"

There's no paradox if there's neither a chicken nor an egg.

Re:Space Elevator

[evanbd]

I don't much like the idea of a space elevator, at least for short- or medium-term applications. (Long term, is 50 years from now, is different... but also not very relevant.) Why, you ask? Simple. Give me a space-elevator class building material, and I'll make rocket tankage out of it long before it's fully developed to space elevator performance levels. Those tanks will be so vastly superior in weight performance to current materials that I can give you a rocket that is not only single stage to orbit, but does it on *pressure fed* engines. Who needs turbopumps and all their associated machinery when you can just put enough pressure in the tanks (and run at a lower chamber pressure... which is more conducive to high reliability anyway)?

For a given payload rate, my pressure fed SSTO will use somewhere between 3 and 10 times the energy (depending on which kool-aid you drink when it comes to getting the power from the ground to the elevator car). It will have a *vastly* lower capital cost. It will be faster (no radiation worries for cargo that spends days passing through the van Allen belts). Perhaps more importantly, it will scale down better. It starts with a lower investment and lower flight rate to prove out demand, and then grows as more customers appear and more rockets get built.

Oh, reusability? It gets a lot easier when you don't have to jettison a stage a third of the way there -- and when your reentry vehicle is as light and fluffy as these building materials imply, it gets even easier. Engine reusability is pretty trivial when you don't have 60,000 rpm turbines wearing out all the time.

There are plenty of engineering problems to be overcome for a space elevator. They're not impossible, but they're far from trivial. But the real problem is the competition from rockets -- it makes zero sense to compare a space elevator built with magic nanotubes to a lithium-aluminum tankage rocket; it should be compared to a magic nanotube rocket. When you do that, you discover that for any unproven market (ie, where capital costs matter) the spaceship fleet is far, far cheaper.

Re:Space Elevator

[F34nor]

Look into the Space Fountain instead... http://en.wikipedia.org/wiki/Space_fountain [wikipedia.org]

Re:Space Elevator

[evanbd]

Actually, if you want a mega-scale engineering project, my personal preference is for the launch loop [wikipedia.org].

Re:

[jamstar7]

OK, I don't see the numbers working for a launch loop too easily. How do you hang a 2000 km loop 80 km up in the atmosphere to begin with???

I'm more of a fan of the laser launcher [strangehorizons.com] concept myself. Problem is, it takes a lot of energy to make one of these work right, so we're probably looking at a couple geosync power sats feeding microwaves to the site. Talk about bootstrapping. Development costs would be a helluva lot lower than 'magic materials' to build a loop or a fountain, I'd think, and if somethi

Re:

[evanbd]

You don't have to hang it up there; it stays up by itself. The ribbon is moving faster than orbital velocity (14 km/s -- orbital is a bit over 7), so its natural tendency to go in a straight line means that the Earth's surface curves away from it. You then have to apply tension with cables to hold it down and make it follow the curvature of the Earth (from 80 km up, of course). The problems with the launch loop lie in things like the control systems and the quantity of stored energy, not the basic physic

Re:

[khallow]

I like this idea. SSTO hasn't been attainable so far. But getting an SSTO with a pressure fed propulsion system. That's extremely competitive even for a space elevator.

Re:

[evanbd]

Yeah, when you start applying space elevator class building materials to your rocket tankage, the usual assumptions simply don't apply. For example: with 65GPa tensile strength (the low end of the strength range Wikipedia gives for an elevator material) material for tankage, a 1000 psi tank filled with dense propellants (which, depending upon your models, might be better [dunnspace.com]) has a mass ratio of somewhere over 1000. The exact number depends on your assumptions about anisotropic winding strength efficiency, bu

Re:

[daveime]

Unobtainium.

Re:

[drinkypoo]

Rockets suck because they burn fuel. Energy goes into making the fuel one way or another and there is generally a significant environmental cost. The space elevator has a massive initial capital cost, but if you're spinning it down from orbit and making it out of something that's already up there (carbon is easy to come by, anyway) then the environmental cost is low. Once the elevator is built, it requires a fraction of the energy to operate that it takes to launch your rockets, as long as you're sending up

Re:

[LingNoi]

Once one is up it's easier to put others up.

Re:

[evanbd]

Have you actually run the numbers on efficiency? I have. A rocket (built from space elevator class magic nanotubes, of course) is somewhere around 5-8% efficient at converting energy on the ground to energy in the payload; somewhat more if you use hydrogen instead of dense propellants, and somewhat more if you count the rocket bits in orbit as useful rather than dead weight.

How efficient the space elevator is varies depending on your assumptions about beamed power efficiency (or other means of getting pow

Re:

[evanbd]

The rocket is not perfectly efficient; neither is the elevator. As I explained above, plausible estimates put the efficiency difference at about a factor of 5. That number can vary by a factor of at least 3 (in either direction) depending on which kool-aid you prefer. The implication of this is that for the short and medium term, the reduced capital cost of the rockets dominates. For the long term, where energy costs are actually relevant, the elevator wins -- but that problem is properly classed as "a

Re:

[Tubal-Cain]

I think it looks like a cross between a SR-71 Blackbird, and a Naboo Royal Starship (the silver ship from SW episode one).

Re:

[MadnessASAP]

Looks like an aircraft meant for hypersonic flight to me... Dunno why it needs to look like anything else.

Re:

[meringuoid]

I think it looks like a cross between a SR-71 Blackbird, and a Naboo Royal Starship (the silver ship from SW episode one)

Looking at that ship, I'm overcome with a sudden urge to fly it to Pleione to track down Mic Turner.

Re:

[Yvan256]

What the hell is an Aluminum Falcon?

Re:

[deimtee]

It's what the Yanks call an Aluminium Falcon.

Re:Star Wars looking?

[decoy256]

Is that what pretentious Brits call Aluminum?

Re:

[Yvan256]

The Brits and everybody else on the planet. ;)

Re:I see...

[RocketGeek]

Then you may need to work on your reading :-)

The precooler tests were run separate to the thrust tests. The thrust tests were related to the ED nozzle work.

As for the reliability, well when I wrote the test plan for the ED nozzle test engine, I can assure you, that reliability was very much part of the plan.

As for you not seeing any prototype being tested, note the photograph of a rocket shaped object with hot flame coming out of it in the News section?

I'm sorry the photograph isn't any better, but none of us were prepared to step outside the bunker during the hot firings. I'm working on improving the photos taken during test runs.

Mod parent rocket scientist up.

[Civil_Disobedient]

Thanks for replying... I think some people forget just how complicated (and time-consuming) it is to design a vehicle for space travel when you don't have billions of dollars in your budget.

Re:

[rts008]

No, you're not the only one.
I had to read it three times before I could parse it correctly.
I blamed it on not enough coffee yet. :-)

Re:

[turgid]

we'll never let it.

+5, insightful.

Actually, it might be more like the UK's original space rocket [wikipedia.org] programme. Just as they get something built that looks like it might work, some bureaucrat will try to terminate the project. There will be begging and pleading to let it fly just once, which it will, and do so perfectly much to the admiration of the world.

Then it will be canceled properly and everyone will have a nice cuppa tea, a slice of cake and a sit-down.

Still, mustn't grumble.