I'll bet the Eaglepanzees can take far higher g-loads than human
astronauts, and are more likely to perform outrageous hijinks and
hilarious monkeyshines while on-orbit also.
Wally Schirra simply put the lens cover on the TV camera when he became
angry on Apollo 7...an Eaglepanzee would have hurled feces straight at
that camera, and that would have been just for starters.
I want an all-mutant monkey crew to be my contribution to what is
evolving here.
I can think of few things more heartwarming than watching a beaked
Chimp-like creature hatch from an egg. ;-)


Pat

A troll is when you post something you don't believe in just to start
an argument or to be controversial. I think you've seen enough of my
posts to know that's not something I'm into. It's possible of course
that it's wrong. All that means, of course, is that the idea is just
wrong. All this rending of clothes and gnashing of teeth is really
over the top.

If you did use wet wings for tankage, that would add greatly to the
weight of the wings. You would need extra support added of wing spars
and ribs, as well as extra support members connecting the wings to the
fuselage. But I certainly don't think it would cost say in the range
of $100 million, which is how much more the Virgin Galactic
development cost is over the purchase price of $42 million for the
orbiters. $100 million is approaching the price of entire jet
airliners, including their engines, that do have such wing
strengthening.
(It might cost that much if the government gave one of the aerospace
companies a cost-plus contract to do it. But a commercial company
would have better sense than to do it that way.)
The orbiter would be launched vertically. You probably would not want
the entire weight of the vehicle to be resting on just the engine
nozzles. You could have support pillars that lead up to connect onto
the airframe. Remember with the current shuttle after the SRB's
jettison that 1,000,000 lbs thrust from the engines is being
transmitted up through the airframe.
I'm not a fan of solid rockets for manned missions. The shuttle SRB's
are also expensive also. It had been thought that reusing the casings
would cut costs, but it turned out, retrieving them, cleaning them,
and refilling them costs nearly as much as using new solid motors on
each flight.
The problem with the ET is that it is disposable. I want a fully
reusable vehicle to cut costs. If I recall the cost of the ET is $100
million per flight, another quite expensive item.
In regards to its feasibility, keep in mind that the orbiter is a
rocket after all. And it does have it's own engines. After ET
separation it is essentially operating in the fashion I'm suggesting
with it's own on board fuel supply, albeit with much weaker engines.
And with the ET still attached, after SRB sep, it is operating as a
rocket with much higher thrust than what I'm suggesting and the
aerodynamic stresses and structural loads are even worse than in my
scenario since the ET would carry even more fuel and it is in a non-
axial position. What I'm suggesting is actually *easier* than the
current propulsion method of the shuttle system after SRB separation.


Bob Clark

For the space tourism use or hypersonic transport use, note that
Virgin Galactic is charging $200,000 just for space tourism and they
believe they can make a profit based on a $150 million development
cost, while carrying only 6 passengers per flight.
Carrying 100 passengers in my scenario would allow you to reduce the
price significantly which would actually increase revenues at this
high number of passengers with additionally, as I'm arguing, a lower
development cost. Note also this would allow a hypersonic transport
role for a large number of passengers in the airliner capacity range
which actually would probably be a larger market. Imagine trips to
Asia instead of taking a whole day only take 90 minutes. Note too this
large number of passengers, at this short transport time anywhere in
the world raises the possibility of military applications.

For the first stage booster use, it's very important to remember the
Air Force believes using such reusable first stage boosters can cut
launch costs by 50%. Now notice the similarity of the Lockheed first
stage booster proposal to the space shuttle orbiter:

Plans for future re--usable space launch X-plane hatched.
Posted by Guy Norris at 3/31/2009 3:41 PM CDT
http://www.aviationweek.com/aw/blogs/space/index.jsp?plckController=Blog&plckBlogPage=BlogViewPost&newspaperUserId=04ce340e-4b63-4d23-9695-d49ab661f385&plckPostId=Blog%3a04ce340e-4b63-4d23-9695-d49ab661f385Post%3a515cca66-2055-4902-bce3-400832bdc2a4&plckScript=blogScript&plckElementId=blogDest

A more detailed discussion:

USAF Seeks Reusable Booster Ideas.
May 14, 2009
By Graham Warwick
"The plan is to conduct an integrated demonstration of technologies
and processes culminating in a subscale X-plane vehicle that would fly
by 2017-18 and take the concept to a technology readiness level of 6,
ready to enter full-scale development.
"AFRL has several ground-based experiments already under way involving
structures, controls and systems for an operationally responsive
launch vehicle. The work is focused on a reference concept for an
unmanned vertical takeoff and horizontal landing reusable booster
capable of turnaround in 24-48 hours and launch within 4-8 hours of a
request."
http://www.aviationweek.com/aw/generic/story_channel.jsp?channel=space&id=news/Reuse051409.xml

This is speaking of only of a subscale demonstrator by 2017-2018. I'm
arguing that by using already produced airframes such as the shuttle
orbiter or Buran you could have *full scale* demonstrators at a
markedly reduced price in a shorter time frame. Note too the sort
turnaround time and quite short preparation time to a launch would be
quite important for a hypersonic commercial transport or military
transport role.

A detailed report on the Air Force's "Reusable Booster System"
program is given here:

Spacelift Development Plan.
http://www.acq.osd.mil/nsso/conference/briefs/HampstenSDP%20Public%20Release.ppt

Notice the similarity of the first stage boosters to the shuttle
orbiter in the diagram on page 8.


Bob Clark

Nice video lecture here by Derek Webber of Spaceport Associates on
the market possibilities of suborbital space tourism and hypersonic
point-to-point transport:

05 August 2009
Updated FastForward Study Group overview presentation, Derek Webber
video presentation on suborbital/point-to-point transportation.
http://www.sei.aero/com/news/newsindex.php?id=14

He discusses a market study he took part in by Futron/Zogby from 2002
on suborbital space tourism at a price point of $100,000. Virgin
Galactic will charge $200,000 but Webber concludes the market in the
U.S. alone might be $1 billion - $2 billion. It looks like at an
initial investment of $150 million, Sir Richard Branson might have
known what he was doing.
The market study is available here:

Space Tourism Market Study.
http://www.futron.com/pdf/resource_center/white_papers/SpaceTourismMarketStudy.pdf


Bob Clark

There are two separate considerations in this topic: 1.)is it
technically feasible, and 2.)is it financially better than just a new
system.

For the first question, I don't think anyone thinks it is literally
impossible based on the fact that the shuttle orbiter itself already
acts as an independent rocket with quite a huge fuel tank after the
SRB's jettison.
See the video of shuttle orbiters engines firing with the ET attached
after SRB sep here:

NASA posts Solid Rocket Booster Video.
Published on 10 Jul 2006 at 3:54 am. 4 Comments.
Filed under In the News, Video.
http://www.dirtyskies.com/index.php/2006/07/10/nasa-posts-solid-rocket-booster-video/

Other images:

Loading Image...

Loading Image...

The ET tank is larger than the shuttle orbiter. My proposal would be
to fit a much smaller tank, both in dimensions and mass, inside the
payload bay. The strengthening to the airframe would be less than what
is already on the shuttle for securing the ET under full engine power.
The SSME's also put out much greater thrust than the engines I'm
suggesting replacing them with. Then the SSME's already subject the
orbiter to much greater loads than what I'm suggesting.
In regards to the second question, you could conceivably purchase the
entire airframe including avionics, wiring etc. for under $6 million
if you purchased a Buran. Undoubtedly starting from scratch to build
an entire spacecraft of this size would cost in the hundreds of
millions of dollars.
It is also unlikely merely strengthening the payload bay would cost in
the range of hundreds of millions of dollars, since jet airliners have
such strengthening of the wing fuel tanks with the total cost of the
entire airliner including engines in the $150 million to $250 million
dollar range.

Bob Clark

Robert Zubrin in his book "Entering Space: Creating a Spacefaring
Civilization" makes some interesting observations about the space
shuttle:

"The shuttle is a fiscal disaster not because it is reusable, but
because both its technical and programmatic bases are incorrect. The
shuttle is a partially reusable launch vehicle: Its lower stages are
expendable or semi-salvageable while the upper stage (the orbiter ) is
reusable. As aesthetically pleasing as this configuration may appear
to some, from an engineering point of view this is precisely the
opposite of the correct way to design a partially reusable launch
system. Instead, the lower stages should be reusable and the upper
stage expendable. Why? Becasue the lower stages of a multi-staged
booster are far more massive than the upper stage: so if only one or
the other is to be reusable, you save much more money by reusing the
lower stage. Furthermore, it is much easier to make the lower stage
reusable, since it does not fly as high or as fast, and thus takes
much less of a beating during reentry. Finally the negative payload
impact of adding those systems required for reusability is much less
if they are put on the lower stage than the upper. In a typical two-
stage to orbit system for example every kilogram of extra dry mass
added to the lower stage reduces the payload delivered to orbit by
about 0.1 kilograms, whereas a kilogram of extra dry mass on the upper
stage causes a full kilogram of payload loss. The Shuttle is actually
a 100-tonne to orbit booster, but because the upper stage is a
reusable orbiter vehicle with a dry mass of 80 tonnes, only 20 tonnes
of payload is actually delivered to orbit. From the amount of smake,
fire, and thrust the Shuttle produces on the launch pad, it should
deliver five times the payload to orbit of a Titan IV, but because it
must launch the orbiter to space as well as the payload, its net
delivery capability only equals that of the Titan. There is no need
for 60-odd tonnes of wings, landing gear and thermal protection
systems in Earth orbit, but the shuttle drags them up there (at a cost
of $10 million per tonne) anyway each time it flies. In short the
Space Shuttle is so inefficient because *it is built upside down*.
{emphasis in the original.}
"Entering Space", p. 29.

This provides support for the view of the Air Force that reusable
first stage boosters can cut the costs to space by 50%:

Spacelift Development Plan.
http://www.acq.osd.mil/nsso/conference/briefs/HampstenSDP%20Public%20Release.ppt

The shuttle is quite large for an upper stage. But it is the right
size for a first stage. It's my intention to turn the Space Shuttle
System right-side up by making the orbiter into a reusable first
stage.


Bob Clark

I mentioned before converting the space shuttle orbiter into a first
stage use would actually be quite important. I discuss this below.

I.)Weight savings by removing unneeded components.
II.)Replacement of the Ares I first stage by the reconfigured shuttle.
III.)Costs saving by private commercial financing rather than "cost-
plus" contracts.

I.) I wanted to get some shuttle component weights to estimate the
weight savings we could make by removing systems that would not be
needed for a suborbital or first stage use. The Astronautix page on
the Shuttle Atlantis gives its "Heat Shield Mass" as 12,100 kg (26,600
lb).
However, Astronautix is sometimes inaccurate. So I found this report
after a web search:

Thermal Protection System Sizing and Selection for RLVs Using the
Sentry Code.
http://www.sei.aero/eng/papers/uploads/archive/AIAA-2006-4605.pdf

It gives on page p. 11 a weight of 17,910 lbs for the thermal
protection tiles and panels but notes other hardware for the TPS
amounts to 4,600 lbs. for a total of 22,510 lbs., 10,232 kg. I'll use
this value for the shuttle TPS.
I've been informed by someone who did a study for the Air Force's
"Reusable Booster System" program that for first stage use at low
hypersonic speeds an aluminum frame would require minimal thermal
protection. See the slides from pages 5 and 7 of this report on the
Air Force's RBS program:

Spacelift Development Plan.
http://www.acq.osd.mil/nsso/conference/briefs/HampstenSDP%20Public%20Release.ppt

So I'll subtract off the 10,232 kg TPS weight from the 75,266 kg dry
weight I got for a reconfigured orbiter, to get a 65,034 kg dry
weight.
This NASA page says a saved weight of 450 lbs off the OMS system
amounted to 10% of its weight:

OMS/RCS PODS.
http://science.ksc.nasa.gov/shuttle/technology/sts-newsref/sts_coord.html#sts_oms_pods

So I'll remove the OMS system to save 4500 lbs, 2,000 kg, bringing
the dry weight now to 63,035 kg.
This page gives the left payload bay door weight as 2,375 lbs. and
the right as 2,535 lbs., and both doors containing radiator systems at
an additional weight of 833 lbs each:

PAYLOAD BAY DOORS.
http://science.ksc.nasa.gov/shuttle/technology/sts-newsref/stsref-toc.html#payload_bay_doors

These won't be needed so removing these would save 6,576 lbs, 2,990
kg, bringing the dry weight to 60,000 kg.
The Buran showed it's possible for the shuttle to have a completely
automated ascent and descent, so I'll remove the life support
components from the mass to use the orbiter as an unmanned first
stage. For lack of any other reference on the mass of these components
I'll subtract off the numbers given on the Astronautix Atlantis page
of "Crew Seats and Provisions" as 750 kg and "Environmental Control
System" as 2,500 kg, for a total saving of 3,250 kg, bringing the dry
weight to 56,750 kg.
Probably the fuel cells and the tanks to hold the on board LOX and
LH2 for the fuel cells could be removed, since as a first stage its
flight would only last minutes rather than the days of a manned
orbiter flight. For such short flights, lightweight batteries or
electrical generators powered by the engines would suffice. This page
gives the fuel cell's oxygen tank weight as 201 lbs. and the hydrogen
tank weight as 216, and says there are a maximum of 5 pairs of tanks:

POWER REACTANT STORAGE AND DISTRIBUTION.
http://science.ksc.nasa.gov/shuttle/technology/sts-newsref/sts-eps.html#sts-eps-prsd

I'll take the total fuel cell's tank weight as 2,085 lbs, 948 kg.
There are three fuel cells each weighing about 120 kg, for a total of
360 kg. So I'll subtract off 1,308 kg from the dry weight to bring it
to 55,442 kg.

II.) The manned space program is in a quandary now because of the
ballooning costs overruns on the Ares I system that was supposed to
act as the next manned transportation system. The primary difficulty
was the Ares I first stage boosters. Originally the development cost
was set at $1.8 billion dollars, though fixes to for example the
excessive vibration generated undoubtedly has increased that cost:

Aug. 10, 2007
NASA Awards First Stage Contract for Ares Rockets.
"WASHINGTON - NASA has signed a $1.8 billion contract with Alliant
Techsystems, known as ATK, located near Brigham City, Utah, for the
design, development, testing, and evaluation of the first stage of
the
Ares I and Ares V launch vehicles."
http://www.nasa.gov/home/hqnews/2007/aug/HQ_C07036_Ares_first_stage.html

Moreover, weight growth and a short fall in the delta-V delivered by
this first stage drove costly adjustments of the upper stage as well.
My point is adapting the shuttle or the Buran for first stage use
would vastly reduce the cost for a first stage. You would have then
several options for manned flight all of which would be cheaper than
using the Ares I first stage solid motors and all of which would allow
a return to space at a faster time scale than the original Ares I
plan.
I'll give a calculation that you could still carry the planned upper
stage and payload of the Ares I with the reconfigured shuttle as first
stage. This page gives the specifications of the Ares I:

Space Launch Report - Ares I.
http://www.spacelaunchreport.com/ares1.html

The gross weight including payload is given as 912,660 kg and the
gross weight of the first stage as 732,550 kg. So the gross weight of
the Ares I second stage plus payload is 180,110 kg.
Then the gross weight for the 55,442 kg dry weight of the
reconfigured shuttle, plus 300,000 kg propellant load, plus 180,110 kg
second stage and payload is 535,552 kg, 1,178,214 lbs. But the 3 NK-33
engines I was suggesting to use only put out a total of 1,018,518 lbs.
of thrust at sea level. For this purpose you would need a fourth
NK-33. The dry weight is now 56,664, the gross weight is 536,774 kg,
1,180,903 lbs., and the sea level thrust of the 4 engines is 1,358,024
lbs.
Using the average Isp of the NK-33 as the midpoint of the sea level
and vacuum Isp's at 315 s, the achieved delta-V would be 315*9.8*ln
(536,774/(56,664+180,110)) = 2,527 m/s, comparable to the equivalent
delta-V, speed + altitude, provided by the Ares I first stage. The
achieved delta-V is actually higher than this since the rocket spends
most of the time at high altitude, where the Isp is closer to the
vacuum value.
Note that if you want to increase the delta-V, the space occupied by
the crew compartment is now empty. This gives an additional 74 cubic
meters that could be used for propellant, which amounts to 74,000 kg
additional lox/kerosene propellant that could be carried.
Then we could still use the planned upper stage of the Ares I while
having a significantly lower development cost and per launch cost of
the now reusable first stage. Still the time when we could reach
flight status would be dependent on the development of the upper
stage. However, we don't need to use the large Ares I upper stage and
Orion capsule if we just want manned flight. I'll show in a following
post we could get a smaller and reusable manned upper stage at a much
lower cost also than the Ares I upper stage and Orion capsule, that
will also allow a much quicker return to manned flight.

III.) I wish also to argue however that for these methods, for the
reconfigured shuttle/Buran first stage and smaller reusable manned
upper stage, we don't want to use the standard procurement methods
with the "Old Space" aerospace companies. Robert Zubrin has some
insightful observations about the "cost-plus" government contracts
that the large aerospace companies get in his book, [u]Entering Space:
Creating a Spacefaring Civilization[/u].
In the chapter, "The Age of the Dinosaurs" referring to the "Old
Space" companies, he first comments that high launch costs drive the
tendency to make satellites be highly reliable which drives the cost
for the satellite higher. And conversely if your satellite is already
very expensive, say a $1 billion Air Force satellite, then there is
little incentive to reduce launch costs since at that satellite price
a launch cost of $100 million or zero makes little difference.
Then Zubrin says:

"Beyond these considerations stands the government contracting system
known as "cost plus," which has been in place for some time now in the
United States. According to the people who invented this system, it is
essential that corporations be prevented from earning excessive
profits on government contracts. Therefore, rather than negotiate a
fixed price for a piece of hardware and allow the company to make a
large profit or loss on the job depending on what its internal costs
might be, regulators have demanded that the company document its
internal costs in detail and then be allowed to charge a small fixed
percentage fee (generally in the 10 percent range) above those costs
as profit. This system has served to multiply the costs of government
contracting tremendously, so much so that it has produced public
scandals when news leaks out about the military paying $700 for a
hammer or a toilet seat cover."
[u]Entering Space[/u], by Robert Zubrin, p. 24.

Then I'm suggesting that the "New Space" companies rather than going
through the usual "cost-plus" financing from the government could
purchase a shuttle/Buran on their own and develop the manned reusable
upper stage on their own with the idea of making a profit. I'm arguing
the development cost of this reconfigured first stage and the small
upper stage would be so low that this can be profitable both for
satellite launch and for now fully orbital space tourism.


Bob Clark

Deep Discount on Space Shuttles.
By THE ASSOCIATED PRESS
Published: January 16, 2010
"CAPE CANAVERAL, Fla. (AP) — Here is a recession bargain: the space
shuttle. NASA has slashed the price of the 1970s-era spaceships to
$28.8 million apiece from $42 million."
http://www.nytimes.com/2010/01/17/science/space/17nasa.html

What I found really interesting was this passage:

"As for the space shuttle main engines, those are now free. NASA
advertised them in December 2008 for $400,000 to $800,000 each, but no
one expressed interest. So now the engines are available, along with
other shuttle artifacts, for the cost of transportation and handling.
"Assembly will be required, however."

I doubt though you could keep these engines and be profitable as a
suborbital tourism vehicle or first stage booster. The maintenance
costs on these engines are just so high. However, the most maintenance
intensive parts were the turbopumps for the high pressure cryogenic
LOX and liquid hydrogen. If you could switch out these turbopumps to
lower performance dense propellant ones, or find some other method
rather then the original turbopumps for pumping the LOX/LH2 at these
volumes and high pressures it might be doable.


Bob Clark