From what I've read the DC-X did achieve its performance goals:
LESSONS LEARNED
DC-X OPERATIONS.
A.J. Polizzi
p. 8
http://www.ispcs.com/files/ww/files/presentations/nino.pdf
DC-X experimental lander set up Boeing for future NASA work.
by Ed Memi
"The DC-X was designed for reliability,
maintainability, supportability and operability.
Given the uncertainties of the design, the
plan was to produce a deliberately simple test
vehicle and to “fly a little, break a little” to
gain experience with a fully reusable quickturnaround
spacecraft. Demonstration objectives
included a 7-day turnaround between
flights with a 3-day goal and use of 50 or
fewer on-vehicle maintenance personnel.
The program achieved a 26-hour turnaround
with 10 maintenance personnel."
http://www.boeing.com/news/frontiers/archive/2008/aug/i_history.pdf
The new FFSC (full-flow staged-combustion) engine being investigated
though is interesting in being able to cut down the maintenance costs
while extending the engine life to the range of 200 missions:
New liquid rocket engine cycle fares well in test.
http://www.sae.org/aeromag/techfocus/10-2006/2-26-9-27.pdf
Rethinking engines.
March 8, 2007
Stephen J. Mraz
Rocket engines and the internal-combustion cycle get a remake, thanks to engineering ingenuity.
http://machinedesign.com/article/rethinking-engines-0308
Bob Clark
---------- Post added at 01:42 AM ---------- Previous post was at 01:20 AM ----------
Just saw this:
The SpaceX
Falcon Heavy Booster: Why Is It Important?
by John K. Strickland, Jr.
September, 2011
"What amazes people is that SpaceX has broken the long-sought 1,000
dollars a pound to orbit price barrier with a rocket which is still
expendable. 'How can he (SpaceX CEO Elon Musk) possibly do this?' they
ask. The Chinese have said flatly that there is no way they can
compete with such a low price. It is important to remember that this
was not done in a single step. The Falcon 9 already has a large price
advantage over other boosters, even though it does not have the
payload capacity of some of the largest ones. The 'Heavy' will even
this score and then some. At last count, SpaceX had a launch manifest
of over 40 payloads, far exceeding any current government contracts,
with more being added every month. These are divided between the
Falcon 9 and the Falcon Heavy."
http://www.nss.org/articles/falconheavy.html
I think the most important accomplishment of SpaceX might turn out
to be that they showed in stark terms that privately financed spacecraft,
both launchers and crew capsules, can be accomplished at 1/10th the
developmental cost of government financed ones. Imagine a manned,
reusable orbital launcher, for example, instead of costing, say, $3 billion,
only costing $300 million to develop.
As I argue, the key variable that made this reduction possible is that
the launcher was privately financed. That is, it was the launch
company's own money that was financing its development. In that case
it makes sense the company would be more fiscally responsible in
developing it.
Then the first step in reducing the price to orbit is making the
vehicles be privately financed. But if the launch companies are going
to spend their own money, they have to be convinced they can make a
profit on them. This will come if there is a significant market.
My view is that there would be a significant market for small,
privately owned, SSTO's. When you consider that with orbital refueling
such craft can also make lunar missions, the market becomes even more
apparent.
An additional finance stream of such vehicles that would make them
marketable I argue could be salvage of satellites in LEO or GEO:
Space junk at 'tipping point', now getting worse on its own.
More collisions generate more debris, so more collisions.
By Gavin Clarke
Posted in Space, 2nd September 2011 11:18 GMT
http://www.theregister.co.uk/2011/09/02/space_junk_danger/
Article:
World's First Space Gas Station for Satellites to Launch in 2015.
by Clara Moskowitz, SPACE.com Senior Writer
Date: 15 March 2011 Time: 06:03 PM ET
"Until now, satellites orbiting around Earth have been limited by how
much fuel they carry onboard. Once those tanks run dry, the satellites
die, sometimes languishing in space as uncontrollable debris that then
poses the risk of colliding with other spacecraft.
"The new plan offers the potential not just to extend the lives of
working satellites, but to help combat the growing space junk problem.
The satellite, called the Space Infrastructure Servicing (SIS)
vehicle, is designed not just to transfer more fuel into existing
satellites, but to inspect, tow, reposition and make minor repairs to
them.
"In addition to its tank of fuel, the refueling satellite will carry a
robotic arm that can be used to grab onto satellites and tug at stuck
solar array panels, for example, or attempt other minor fixes to
broken parts.
'This is a first-time-ever, huge, huge, huge event,' said Andrew
Palowitch, director of the Space Protection Program, a joint project
of U.S. Air Force Space Command and the National Reconnaissance
Office, speaking at a National Research Council workshop on orbital
debrislast week.
"Palowitch stressed that the ability to tow or refuel dead satellites
in order to steer them out of the way would have a big impact on the
growing problem of dangerous space debris clogging the crowded
corridors of Earth orbit. [Worst Space Debris Events of All Time]
'In the context of debris removal, this is the absolute best and
absolute most fantastic new venture for the entire space community,'
he said.
"The refueling satellite will be able to move dead spacecraft to
what's called the 'graveyard orbit,' where they are high enough that
they should not pose a risk to working satellites, or maneuver them
low enough that they break apart in Earth's atmosphere."
http://www.space.com/11135-satellite-refueling-mission-space-debris.html
Remember the TV show
Salvage 1?
Bob Clark
