Reported here is a concept for a two-stage to orbit (TSTO)
vehicle, capable of sending two
astronauts to low Earth orbit (LEO) in a minimal transfer and return
capsule. Modern ablative heat shield
items are assumed to reduce the capsule weight.
The capsule has a “service module” containing on-orbit propulsion and
folding solar panels for electric power.
These astronauts arrive in LEO with a significant on-orbit
maneuvering propellant budget, and can
conduct short term (one week or less) missions unaided. Longer missions would require docking with
something that had some living space and life support supplies. The on-orbit propellants are nitrogen
tetroxide-monomethyl hydrazine (NTO-MMH),
which are very storable for very long periods in space. Total on-orbit delta-vee was simply assumed
to be 1 km/s.
These roughed-out designs are the results of bounding
calculations, not trajectory
simulations. I went through four
iterations to reach a rough size-out that I trust. The second stage was analyzed with a
loss-corrected approximation of the rocket equation. The first stage was analyzed with rocket-impulse
and ramjet-energy approximation analyses.
Everything was checked with thrust versus drag maps to ensure basic feasibility, a considerable problem reaching high speed in
the thin air where staging takes place.
For the results of a true horizontal takeoff study utilizing ramjet assist, see "HTO/HL Launch with Ramjet Assist", dated 11-6-13.
For the results of a true horizontal takeoff study utilizing ramjet assist, see "HTO/HL Launch with Ramjet Assist", dated 11-6-13.
First Stage
The first stage takes the form of two integral rocket-ramjet
(IRR) booster pods, based on a
solid-propellant rocket booster, and a liquid-fueled
ramjet sustainer, right out of missile
technology based on ASALM-PTV, about
1980. The same technology is in the
“Sunburn” and “Yakhonts” missiles built by the Russians today. The booster is packaged within the ramjet
combustor, requiring some sort of inlet
port cover, and some sort of ejectable
booster nozzle nested within the ramjet nozzle,
just as in ASALM and the Russian missiles. 10-30-13: also the US ALVRJ (1970's), AAAM (1990's), and VDR (1980's-1990's) efforts used the same basic IRR technologies (I actually worked on ASALM, AAAM, and VFDR). As did the 1960's Soviet SA-6 "Gainful" (that I also got to exploit ca. 1970's).
I have previously posted some of the ramjet thrust performance
data for such a pod (see references list),
based on RJ-5 fuel, which is a
synthetic similar to kerosene, but
slightly denser than water. This work was based on a fixed ramjet nozzle
geometry, but a variable inlet geometry
to maintain shock-on-lip throughout the range of ramjet flight speeds. This amounts to a very simple translating
compression spike, similar to those used
on the SR-71 “Black Bird”, except
operated for ramjet instead of turbine.
(The two engines are quite different,
even though the inlet components are the same.)
The IRR booster in each pod is a state-of-the-art AP-HTPB
composite propellant of 20% aluminum and 87% solids. It is similar to shuttle SRB propellant, except for the really-large thixotropic
effective-viscosity that is inherent with the really-high solids content that
confers high Isp (some 254 demonstrated seconds). Not many companies had the expertise to
reliably cast such a propellant, but the
one I worked for decades ago did. This
is also essentially the same as the AIM-120 AMRAAM propellant we used
successfully at the McGregor, Texas
plant, before corporate politics closed
it.
Second Stage
The second stage is essentially Centaur technology, revised to a slender form factor. This is stainless steel balloon-tank
technology, with one engine similar to
an RL-10. It is a LOX-LH2 system. I assumed only about 450 seconds of Isp, in order to do a conservative performance
estimate. (Centaur actually does better
than this.) I assumed no need for wings
during pull-up from staging, relying
entirely on body lift at Mach 6.
Partial Reusability
I made the first stage booster pods reusable as flyback
remote-control (R/C) aircraft, fitted
for a runway landing on land. I didn’t
get enough reserve fuel out of this bounding analysis to support flying back
all the way to the launch site. There
are two of these pods, one on each
side, which confers plenty of body
lift, even at only Mach 1.7, the ramjet takeover point that I used. The ramjet design works all the way down to
Mach 1.5, but I set takeover at Mach 1.7
to get some reliability “margin”. After
all, this is supposed to be a manned
system.
The second stage is assumed expendable, just as Centaur is today. Its price ought to look about like that of
Centaur. The service module is also
assumed expendable. The capsule could be
re-flown many times, given about 2-to-3
inches (50-to-75 mm) thickness of PICA-X for its heat shield.
First Stage Trajectory
This thing launches ballistically at a “high” gee level still
tolerable by a human crew: around 5
gees. That’s fast enough to achieve
flight speed “without time to swap ends”.
It comes off a slanted rail launcher (angle not determined here, that’s for “real” trajectory code
analysis), and reaches ramjet takeover
(Mach 1.7) at the relatively low altitude of about 5000 ft (1.5 km) above mean
sea level (MSL). Control during this
phase would be by relatively-small attitude thrusters. See Figure 1.
Once the solid integral boosters burn out, the ramjets “light up”. Transition in ASALM was 100
milliseconds, this should be comparable
to that. Each pod has a frangible-glass
port cover protected with bonded rubber insulation, and equipped with a destruct charge set off
as booster chamber pressure tails off.
Each pod has an ejectable booster nozzle (I computed roughly a 10 inch
diameter throat, a 38 inch diameter
exit, and a 52 inch exit bell length at
15-degree half angle). All of this is
based on ASALM technology.
I guessed these ejectable nozzle assemblies at 200 lb per
pod, scaled up from 15 lb for ASALM, more or less on diameter squared, not cubed,
which may or may not be as realistic as it should be. These nozzles are held in place by a circular
snap ring in a groove near the exit,
just like ASALM. That snap ring
is underlain with very-high-quality detonation cord, also set off by the tailoff of booster
pressure, just like ASALM. Then the fast-declining residual boost
pressures “shove” the ejectable nozzle clear.
The boost pressure tailoff also sets off a magnesium flare to light the
fuel-air reaction, same as ASALM. (From about Mach 3 on up, the fuel-air reaction is essentially
hypergolic.)
The ramjets have very significant thrust margin over
drag, although vehicle accelerations in
ramjet are far less (factor 10) than in IRR rocket boost. The trajectory assumes a constant-altitude
acceleration to Mach 2 at 5000 feet,
where thrust margin is pretty much optimum. The vehicle then pulls up on body lift for a
Mach 2 climb to 60,000 feet altitude (18.3 km).
I did a spreadsheet thrust-and-drag point-performance-estimate series, to ensure this would be feasible. These estimates used the same thrust and
overall-efficiency results reported for the pod, just correlated versus Mach number and
altitude.
Once the vehicle reaches 60,000 feet at Mach 2, it pulls-over horizontal and uses its thrust
margin to accelerate to Mach 6 for staging.
The crucial controlling factor for acceleration to this speed is
vehicle drag. It sets the diameter ratio
of the second stage to each of the two IRR booster pods. That is where the 7 foot to 5.22 foot diameter
ratio comes from. The ramjet cycle
analysis that I used is beginning to break down from ionization/recombination
effects, from about Mach 5 on up. It begins diverging sharply from reality above
about Mach 6. That and the ASALM speed
record, are where the staging speed used
here came from. Overall energy
conversion efficiencies fall in the 22-23% class.
This relative diameter result is a function of the number of
pods. That determines how much drag must
be overcome by the ramjet thrust available in the “thin air” at altitude. I got
5.22 ft diameter for each of two pods,
carrying a minimum-credible 7 ft diameter payload. My drag data came from that for clean
projectiles in the old Hoerner “drag bible”.
(If you don’t know what that reference is and how to use it, you have no business playing with this
concept.)
The pods have to be nose inlet configuration, in order to limit pod drag to skin friction
and a little cowl lip pressure drag (that is the minimum achievable). Side inlet configurations will be
“draggier”, and will have far more
difficulty reaching Mach 6 at 60,000 feet (or any other altitude). The single nose inlet selection here is
therefore the “optimum” configuration choice.
It features a cowl area about 50% of the pod cross section area, an inlet duct about 40%, a ramjet throat about 65%, and a ramjet nozzle exit pretty close to 100%
of the pod cross section.
Higher staging altitudes reduce frontal ramjet thrust, reducing vehicle acceleration, extending the acceleration range, and increasing the first stage fuel and
article weights. This is based
on earlier trade studies I did with similar bounding calculations. It’s a judgment call, but 60,000 ft seems to be a pretty good “rule
of thumb”.
Second Stage
Trajectory
Since the staging point is Mach 6 at 60,000 ft, there is plenty of body lift available to
pull up to about 40-degree path angle.
“Store separation” hypersonically is even more problematical than at
supersonic speeds, something the
military avoids at all costs. That is
because the aerodynamic forces are so much larger than the weight forces, even in the thin air. That means stage separation will require
small solid motors strategically placed,
on both stages. Those
details are beyond scope here, although
the solid motors would resemble scaled-up versions of the ullage motors seen in
many launch vehicles.
The second stage pulls up to a steep path angle on body
lift, then flies a simple ballistic
gravity-drag turn to orbit. See Figure 2. I simply assumed a 10% gravity-drag combined
loss, imposed on the velocity
requirement for simple rocket equation mass ratio analysis. Mass ratio sets the propellant mass
fraction. That and the inert fraction
set the payload fraction.
If the mass of the payload is fixed (as it is here), that sets the weight statement, for any given propellant combination. The combination here is liquid oxygen-liquid
hydrogen (LOX-LH2), similar to that in
the Centaur upper stage in use today. As
in Centaur, I assumed steel balloon
tankage construction, just of a slim
form factor. Inerts are 10% of stage
ignition weight, as in Centaur.
The Ultimate Payload
What is delivered to LEO is a manned capsule with a “service
module” that supplies solar electric power plus significant on-orbit maneuver
capability. I assumed (1) very storable
propellants, and (2) 1 km/s maneuver
capability. The propellants are
NTO-MMH. I assumed a conservative Isp of
300 s for the maneuver engine. See Figure 3.
The capsule is a minimum-credible two-man re-entry vehicle
of an assumed 2000 lb, assuming
low-density ablative heat shielding that can be re-flown a few times. That would be PICA-X for the main heat
shield, and Avcoat on the afterbody
external surfaces. The minimum credible
diameter for a cramped two-person capsule would be near 7 feet.
This capsule would contain nothing more than two
persons, their spacesuits, and many hours of life support. The idea would be adequate support for a few
days of independent operation, or a
“lifetime” of many weeks to several months if docked to an independent habitat
such as the International Space Station.
There are an entire plethora of useful missions that such a crew
transport capability could support, a
subject not explored here.
Second Stage
The second stage is a simple rocket vehicle using LOX-LH2
propulsion, with a gimballed
engine. I used a simplified analysis and
a conservative Isp to estimate the stage properties shown in Figure 4. The payload is the two-man capsule and
service module already described as the “ultimate payload”. This second stage is not assumed to be
recovered and reused, although there is
always that possibility, given the
higher inert fraction required to cover the heat shield and parachute
equipment, and perhaps some additional
deorbit/deceleration propellants. Making
that stage recoverable and reusable is far out of scope here.
First Stage IRR Pods
The first stage IRR pods are shown in Figure 5. This pod concept is basically identical to
that described in the earlier postings regarding ramjet pod performance. The booster is AP-HTPB composite propellant
under web fraction and volumetric-loading conditions easy to meet, with a burn rate already well-demonstrated
without resort to ultra-fine AP grinds.
The ramjet uses the dense synthetic kerosene-like fuel RJ-5, sometimes known as Shelldyne-H.
This is the nose-inlet analog to the chin-inlet ASALM-PTV
missile configuration. The only
difference between these results and the earlier postings of ramjet pod performance
is in the pod drag: fins that fold into
a wake zone, instead of fixed fins. Those fins are needed for stability and
control, after staging, for recovery purposes. They have significant drag, left in the slipstream.
Recovery is by runway landing, on a steerable nosewheel and fixed skids on
the ventral fins. Two pivoting wings are
extended subsonically, to form a biplane
configuration capable of landing at a bit over 150 knots equivalent air speed
(KEAS), without resort to flaps and
leading-edge devices. These pods are not
manned; recovery is by remote radio
control.
They cruise back as far as fuel allows, at Mach 2 60,000 ft conditions, fins extended, but wings stowed. Once the engine is “off”, the pod quickly decelerates subsonic, at which point the wings pivot to extend for
subsonic glide to a dead-stick landing on the runway.
These pods are modular: an inlet
section, a tank section, and a combustor section. Refurbishment of the pod requires separation
of the combustor IRR section, and its
replacement by another already loaded with propellant and transition gear out
of inventory.
The inlet section merely requires minimal servicing of the
hydraulics for the nosewheel and translating inlet compression spike. The tank section merely needs fuel control
checkout, and tank refueling. All three sections need the external cork
layer residues power-washed off, and
replaced with fresh cork insulation.
This was a technique used very successfully on the Phoenix missile for
hypersonic aeroheat protection.
The combustor section needs the internal insulation residues
power-washed clean. Then it needs a new
DC 93-104 insulator cast in place on retaining ribbons, and primed for an etched Teflon separator
sheet. That sheeted insulator then needs
another primer before casting the booster propellant. This system was quite successful in ASALM, in spite of the otherwise-incompatible
chemistries of propellant and insulator.
The booster is envisioned as a simple internal-burning
cylinder with both ends unrestricted,
which would be slightly progressive,
more-or-less matching the drag increase with speed. The propellant resembles shuttle SRB
propellant, except for the higher solids
content that makes it very thixotropic.
This material has to be pressure-cast into vacuum in the case, which is fitted with cast tooling. The pressure-casting pressure level is very
significant, or else voids will cause
fatal troubles. This was a processing
technique well-proven at the old McGregor, Texas weapons plant. Few others could do this.
The unique concept here is “circumferential
folding” of the fins, something
fairly compatible with the limited-volume of the ramjet nozzle recess, by means of circumferentially-rotating rings
to which the fins are fixed. During
rocket boost and ramjet sustain, the
three fins of each pod are stowed in the wake of the second stage, for no perceptible drag increment. That is how power-on pod drag can be limited
to skin friction plus a bit of cowl lip pressure drag. (Power-off,
one must include the base drag,
too, which differs between rocket
and ramjet, due to the differing exit
area sizes.)
Upon staging, the
fins are quickly moved to their proper positions. This can be done hypersonically, because each fin is essentially streamline to
the flow, and thus is not subjected to
catastrophic forces. The pod flies supersonically
on body lift until fuel is exhausted.
Deceleration to subsonic is then quite rapid, after which the pivoting wings are
extended. Two wings are used, in a biplane configuration, to reduce the wing loading under 100
lb/sq.ft, which gets the sea
level stall speed down near 150 knots equivalent air speed. That is a very practical value, without any flaps or leading-edge devices. Each wing is about 35 foot span, and constant 2 ft chord. A flat-bottomed subsonic airfoil is the
proper choice.
Cluster Vehicle
The vehicle comprises the second stage rocket plus two IRR
pods strapped-on, as shown in Figure 6. The strap-ons are positioned on either side
for maximum body lift capability. They
are staggered axially to provide the room at the rear in which to stow the fins
in the wake of the second stage. The
wings are stowed top and bottom by pivoting into axial alignment with the pod
airframe.
This is necessarily a cluster vehicle. The axial stagger ensures that the second
stage bow shockwave does not impinge upon the strap-on IRR pods. However,
the spike shocks of the pod inlets do impinge upon the second stage. Depending upon material selections, the enhanced shock-impingement heating can be
quite catastrophic above about Mach 2-to-3.
Even with heavy Inconel-X skins,
shock-impingement heating became quite catastrophic on the X-15 flight
that carried a scramjet test device in place of its ventral fin.
For this vehicle,
small sacrificial panels of the tough ablative silica phenolic could be
located in the impingement zones on the second stage. Although expensive and a bit heavy, such panels would provide a
reasonably-certain “fix” for the otherwise-fatal shock-impingement heating
problem.
Concluding Remarks
I did not even try to estimate costs. But,
consider this: this vehicle can
send a crew of 2 to LEO, yet grosses
near only 120,000 lb at launch. That is
a lot smaller than current commercial satellite launch vehicles, and more in line with the size of the
historic Titans that launched Gemini in the 1960’s.
The second stage rocket is a form-factor variant of the
venerable Centaur upper stage, and thus
should be priced similarly.
The small capsule and service module should resemble the
historic Gemini of the 1960’s except that this one is partially reusable. The price should be similar to Gemini
corrected for inflation, but significantly
reduced for experience gained since then, and for reusability of the return capsule
itself.
The first stage pods resemble nothing so much as large
tactical missiles, and should have
similarly-small manufacturing and logistical support “tails”. The prices for these should resemble the
prices for large tactical missiles,
quite a bit cheaper than is “customary”,
even with commercial launchers.
There is absolutely nothing here that requires new technology
development. There is only the
application of well-established missile technology in a launch venue not
accustomed to using it since about 1960.
Just as a wild guess,
call it $25M per launch, for 3300
lb delivered to LEO. That’s about
$7500/lb or $16,700/kg, which is higher
than commercial, but still less than the
trend of government-operated vehicles.
The amazing schedule flexibility of a missile-like launcher is preserved
in this design, a unique advantage
indeed.
My point is that simplicity,
flexibility, and smaller launched
size, can all be had for a price not all
that out-of-line with modern commercial launch.
References
Sighard F. Hoerner,
“Fluid Dynamic Drag”,
self-published by the author and then his widow Liselotte, 1965.
Pratt and Whitney,
“Aeronautical Vest Pocket Handbook”,
12th edition, December
1969 (propellant and performance data for liquid rockets).
G. W. Johnson, “Inlet
Data for Ramjet Strap-On Pod”, posted to
http://exrocketman.blogspot.com, 2-20-2010.
G. W. Johnson,
“Ramjet Strap-On Pod Concept”,
posted to http://exrocketman.blogspot.com, 2-20-2010.
G. W. Johnson,
“Ramjet Strap-On Pod Point Performance Mapping”, posted to http://exrocketman.blogspot.com, 2-20-2010.
G. W. Johnson,
“Preliminary Acceleration Margins for Baseline Pod”, posted to http://exrocketman.blogspot.com, 2-28-2010.
G. W. Johnson, “More
Ramjet Performance Numbers for the Strap-On Pod”, posted to http://exrocketman.blogspot.com, 7-11-2010.
G. W. Johnson, “More
Strap-On Pod Ramjet Engine Data”, posted
to http://exrocketman.blogspot.com, 7-23-2010.
G. W. Johnson, “Two
Ramjet Aircraft Booster Studies”, posted
to http://exrocketman.blogspot.com, 8-22-2010.
If you combine a technology like this article’s crew transport capability, with a permanently-deployed but occasionally-manned repair craft like that described in the 8-2-11 article, then you have recreated the tremendously-successful and valuable on-orbit service and repair capability we had with the space shuttle.
The change, and it is a huge one, is that you no longer incur the gigantic expense of a shuttle launch (or any other giant rocket), every single time you need to use the on-orbit repair capability.
This approach is not the way our government
space program has historically operated.
It is more like what the commercial space companies are trying to
do, but have not really accomplished yet. Maybe there is a lesson for government
space agencies here, since they
still set many of the missions to be done,
and the rules by which to accomplish them.
Use the wrong rules or goals, and you get a bad result; it’s just plain old common sense.
Update 10-30-13:
The technology described here is one
of several possibilities for flexible,
rapid, and modestly-priced launch
of a small work crew to orbit, to do a
specific job and then return. The point
of this article was to show that this goal can be achieved with technologies
we have had for decades. All
that is needed is the will to do it,
not endless gravy-train technology-development programs, nor politically-dictated gigantic rockets.
The technology outlined in “End of
an Era Need Not Be End of a Capability”,
posted 8-2-11, is essentially the
deployment on-orbit, of generalized
repair and maintenance facilities. These
are only occasionally manned, when there
is a job to do. A few of these facilities
would need to be deployed in a few convenient orbits.
You send up propellants and life
support supplies in small payloads when you want to use one of the repair
facilities. The propellants and some of
the supplies might even be launched at high gee with a light gas gun, an even-cheaper-to-use technology. The crew collects these, and brings it all to the repair station, when they go up. That’s why I gave the capsule a service
module with a significant on-orbit maneuver capability.
If you combine a technology like this article’s crew transport capability, with a permanently-deployed but occasionally-manned repair craft like that described in the 8-2-11 article, then you have recreated the tremendously-successful and valuable on-orbit service and repair capability we had with the space shuttle.
The change, and it is a huge one, is that you no longer incur the gigantic expense of a shuttle launch (or any other giant rocket), every single time you need to use the on-orbit repair capability.
Use the wrong rules or goals, and you get a bad result; it’s just plain old common sense.
Figure 1 – First Stage Trajectory Characteristics
Figure 2 – Second Stage Trajectory Characteristics
Figure 3 – The Ultimate Payload (Carried By the Second
Stage)
Figure 4 – Second Stage Characteristics
Figure 5 – IRR Pod Characteristics
Figure 6 – Launched Vehicle (and Recovery) Characteristics
