This is only meant as a funny. The caption is something like "first discovery of water on Mars".
Thursday, March 23, 2017
Saturday, March 18, 2017
Bounding Analysis for Lunar Lander Designs
I did this as a "clean sheet" bounding analysis. Friends I correspond with have asked repeatedly how a lunar base might be established, and with what. I know the most about Spacex rockets and capsules, but actually fleshing out these designs could use anybody's existing equipment, in whole or in part. The challenge I now throw out to them is to design something within these limits.
All the calculations and equations are basically the same as
before. I simply used the same
spreadsheet with different numbers. The
results are given in Figure 2. Deliverable
“payload” is 2235 kg, which would be
suited crew plus a few of days of life support,
plus any samples sent back to Earth.
If we stay under 13 thrown metric tons, the Falcon-Heavy should have enough delta-vee
capability to put that 13 tons into lunar orbit, same as the lander designs just bounded
above. The problem is then leaving lunar
orbit with enough propellant reserve to cover attitude control and a powered
landing on land back on Earth (Spacex’s preferred mode). Attitude control consumption should be
modest, but we might need around 0.5
km/s capability to land safely on Earth,
where capsule terminal fall velocities are only around half a Mach
number. 0.8 + 0.5 + small change is
close to 1.35-1.4 km/s delta vee capability demanded of the Super Dracos on
crew Dragon. It simply does not have
that much capability without extra propellant added in the trunk, and connected to the system in the
capsule.
The only remaining question is for how long a crew Dragon
can be parked in lunar orbit before the crew that needs it must come back to it
and fly it home. There are limits to
lifetime allowable parked in space.
Perhaps this can be made into some number of months to a year, given some experience flying the capsule
design in Earth orbit. If a year, then the lander plan given above is quite
feasible just as it is laid out. If
not, we’ll have to switch out crews on
the moon at 6 months, perhaps.
Bounding Analysis for
Lunar Lander Designs
GWJ 3-18-17 completed 3-18-17
The scenario here is a lander delivered “neat” to lunar
orbit as an unmanned item. A crew will
arrive separately to rendezvous with it in lunar orbit. The plane of that orbit is presumed to be
very close to the ecliptic. Orbital
direction is retrograde, in accordance
with the figure-eight patched-conic trajectory used during Apollo. The delta-vee to land one-way is 1.68
km/s. For design purposes, a few percent higher is used to provide a
little margin: 1.75 km/s.
The lander is delivered “neat” to lunar orbit, meaning the rocket that takes it to the moon
must do the “burn” to put it into lunar orbit.
The total rocket design delta-vee from the surface of the Earth to do
that is at most 12.4 km/s, when the
first 8 km/s to Earth orbit is factored for drag and gravity losses by
1.05. This is very close to the surface
launch for a more-or-less worst-case slow trajectory to Mars, which is about 12.1 km/s, factored the same way. That way, the tonnage sendable onto a Mars transfer
trajectory is almost the same as what can be delivered into lunar orbit, for our purposes here.
Descent Design
Requirements
Spacex lists on its website that its Falcon-Heavy can send
13.6 metric tons to Mars, flown
fully-expendably, for about $90 M launch
price. This heavy-lift booster hasn’t
yet flown, but it should fly this year
(2017). Reducing that payload slightly
for the slightly-higher delta-vee to lunar orbit, call that a max payload to lunar orbit of an
even 13 metric tons.
For the descent stage,
ready to fire in lunar orbit, we
are looking at an ignition mass of 13,000 kg maximum, and a required design delta-vee of 1.75
km/s. Propellants should be
storable, since days to weeks, even months,
in space (or on the moon) are contemplated. With nozzles designed for vacuum, and assuming NTO-MMH propellants, a delivered Isp = 335 sec is quite realistic. Engine thrust/weight ratio of 100
Newtons-of-thrust per Newton of engine Earth weight seems feasible.
Thrust to ignition Earth weight ratio should
just barely exceed lunar gravity’s pull,
so that plenty of thrust margin is available at burnout weight: 0.2 seems “reasonable”. We’d like the vehicle acceleration at burnout
to be less than 1 gee, preferably under
0.5 gee, to keep the ride from being too
rough, and to limit throttleability
requirements to feasible values.
The propellant tanks will need a sun-reflective surface and
some insulation, plus electric in-tank
heaters, on a single-hull tank. That means the descent stage propellant
tankage will not be quite as lightweight as that of an expendable booster. Just considering the tankage alone, a 95-5 split of propellant to tank masses
seems reasonable to assume (Wp/Wt = 95/5 = 19).
The rest of the stage structure must bear the thrusted
flight maneuvering loads carrying as large a payload as possible, plus incorporate a set of broad-span landing
legs, and some means of unloading large
items (ramps, crane, etc.).
An inert structural fraction for the stage near 15% should cover all of
this. That fraction does not include
tank inerts or engine hardware. Those
get figured separately, and then added
to determine an overall stage inert mass fraction.
The objective here is to determine max payload mass within
that ignition mass limitation. That
payload can be either (1) cargo delivered one-way, or (2) an ascent vehicle carrying minimum
crew and cargo weight. They mass the
same, though.
Sizing a “Clean-Sheet”
Bound on the Descent Stage
Exhaust velocity is rather accurately estimated as Vex, km/s
= 9.8067*(Isp, sec)/1000. That and the
design delta-vee value combine to determine stage mass ratio MR =
exp(dV/Vex). The required propellant
fraction (of ignition mass) is Wp/Wig = 1 – 1/MR. The corresponding fraction for tankage inerts
is Wt/Wig = (Wp/Wig)/(Wp/Wt). The
corresponding engine inert fraction of ignition mass is We/Wig = (T/Wig)/(T/We). The rest of the stage structural and
equipment inerts is represented by the 15% figure. These total together for the overall stage
inert fraction.
Payload fraction of ignition mass is just 1 minus the
propellant fraction and minus the sum total inert fraction. Once you specify an absolute payload
mass, that determines ignition
mass, from which all the component
masses are determined by their fractions.
That finalizes the weight statement.
For this bounding exercise based on Falcon-Heavy delivery, those results are in Figure 1.
Figure 1 – Limits for Descent Stage, One-Way,
Falcon-Heavy Delivery to Lunar Orbit
Payload is 5.372 metric tons. This could be all cargo, or it could represent a crewed ascent
stage. If cargo, that’s $90M/5.372 metric tons = $16.8M per
metric ton delivered to the surface of the moon. Actually,
you design to a slightly-smaller payload mass, because of all the uncertainties. There is always the unexpected outcome, when sizing vehicles like this “from
scratch”. The weight margins don’t have
to be all that large, because I already
put that into the design delta-vee figures.
Ascent Design
Requirements
The same propellant and tankage choices are presumed. The same engine T/We is assumed. A slightly-higher T/Wig = 0.3 is assumed, to accelerate “smartly upward” against lunar
gravity. Stage inert fractions can be lower
since no unload equipment or landing legs are needed. However,
these inerts are likely higher than a typical booster rocket (5%) because
of the protective cabin surrounding the crew,
the docking hatch, and the instruments
and controls they must use. I simply assumed
10%.
This ascent stage must ascend to lunar orbit (requiring 1.68
km/s), and also maneuver to rendezvous
with the crew return craft left in lunar orbit.
It therefore needs more design delta-vee than the descent stage. Call it 2.0 km/s, for a kitty of 0.3 km/s to cover maneuvering
and the unexpected.
Its maximum ignition mass cannot exceed the descent stage
payload capability of 5372 kg. Prudence
dictates very slightly less. Call it
5360 kg for design-bounding purposes.
Sizing a Clean-Sheet
Ascent Design to Fit the Descent Stage
Figure 2 – Limits for Ascent Stage, One-Way,
To Fit Descent Stage That Falcon-Heavy Can Deliver
For the sake of argument,
use 80 kg per person body weight,
and 120 kg for a surface EVA-capable pressure suit. That’s 200 kg per person. Set food,
water, and breathing oxygen
supplies to 100 kg to cover an unexpectedly-long rendezvous interval of several
days. That’s 300 kg allotted per
person. There’s “room” for 7 such masses
in the payload.
If this were 6 crew,
there’s room for around 300 kg of samples or return cargo. If the crew is 5, there’s room for about 600 kg of samples or
return cargo, and so forth. But the point is, there’s room for a much larger crew than
Apollo had. That’s partly the difference
in technologically-achievable storable propellant performance, and in structural technologies, since the 1960’s. The rest is landing without unknown obstacles
in your path, which is what happened on
Apollo 11, nearly depleting its
propellant.
How This Can Be Used
The one-way cargo-only variant can be used at $90M a shot to
deliver 5.36 metric tons of cargo to the moon ($16.8 M/delivered metric ton). Several could be sent to the same site. Some of these could be the modules from which
some sort of surface habitat could be assembled. The rest could be the supplies, equipment,
and surface rover vehicles needed to operate that base.
The manned lander conforms to the same 5.36 metric ton
weight limit. If crew were 3, then 1200 kg of surface supplies could go
down with them. If crew were 2, then 1500 kg of cargo could ride down. Reducing the ascent load just increases the
rendezvous maneuver capability upon returning to lunar orbit, a very beneficial safety factor.
Say, we sent 9 of
these to the moon: 6 cargo-only landers
and 3 landers with manned ascent stages,
each with a crew of 2 and 1500 kg of cargo on board. That gives us three ascent vehicles on the
lunar surface ready to use, when the
entire crew really only needs one to return.
Added safety, that is.
That’s a total of 32.16 tons delivered with the cargo
landers, and 4.5 more tons sent down
with the manned landers, for a total crew
of 6. Assume simply for the sake of
argument that the surface habitat requires 20 tons. We need to reserve 0.6 tons of supplies for
the crew to ascend. Assume two rovers, each 1 ton.
Assume one electric backhoe-like device, at 2 tons.
36.66 tons total delivered cargo, less 20 ton habitat, 4 tons for vehicles, and 0.6 tons for ascent supplies, leaves 12.06 tons allocatable for surface stay
supplies and other equipment items. At a
nominally-assumed 10 kg life support per person per day for 3 months, then about half that 12 tons is something
other than life support supplies. Also nominally, 3 months of life support supplies for a crew
of 6 is pretty close to a lander’s deliverable payload at 5400 kg. I tried to overestimate this requirement.
Looks to me like there is very good potential for
establishing a fairly substantial lunar experiment station, temporarily occupied for a considerable time
(at least 3 months). This requires 9
Falcon-Heavy fully-expendable launches for the landers, plus one more to send the crew in a crew
Dragon (with its trunk modified to carry propellant, something not addressed here), for $900 M in launch costs. If launch costs were 20% of the program that
develops these vehicles and the surface equipment, total program cost to put a small base
temporarily on the moon would be in the ballpark of $4.5 B.
Launching another cargo lander every 3 months or thereabouts
brings the supplies to keep that base permanently occupied at crew size 6. Maybe switch out crews yearly, by adding a crewed Dragon to lunar orbit
along with a fresh manned lander to take them down to the surface. That’s a total of 6 Falcon-Heavy launches per
year to maintain a continuous presence at the base. That’s $540M per year to maintain the base
after it is built, plus the costs of keeping
the necessary vehicles and equipment in production. Development is complete, so call launch costs ~50% of continuing
program costs.
About $4.5 B to establish a 3-month-capable, 6-man base on the moon, and about $1B/year to keep it continuously
manned and operating is just not very expensive as space ventures go! This analysis is based on the use of a
commercial heavy lift rocket that is far less expensive to use than NASA’s
SLS, and which will also be far more
available for routine use multiple times per year, than NASA’s SLS ever can.
Blue Origin is also planning to get into this kind of lunar
capability with its New Glenn rocket.
Between them and Spacex, putting
a base on the moon looks to be quite feasible and quite affordable. This could provide the bootstrap start needed
to begin doing something useful, or for
profit, on the moon.
Final Remarks
This kind of experiment station allows evaluation of
low-gravity effects upon health versus the zero-gravity effects that we are
familiar with in Earth orbit. It allows
a place to experiment with increasingly-capable recycling life support
systems. It allows a place to experiment
with meteoroid and radiation protection by regolith cover. It allows a place to experiment with ways and
means to overcome contamination and wear issues with very-fine-but-sharp-edged
dust particles. All these are needed to
visit Mars or the asteroids, and are
available on the moon “close by” in case of trouble.
The same base allows experimentation with ways and means to
dig and drill deep in a harsh environment.
It allows experimentation with the recovery of mineral resources. It allows experimentation with how to
establish roads under such conditions,
so that future long-distance surface transport becomes feasible. These things are needed for establishing
useful and prosperous industrial applications on the moon and Mars, and to some extent the asteroids.
This is the kind of thing we should have attempted to close-out
Apollo, had a useful lunar presence been
the goal, instead of
“flags-and-footprints”. It is still a
good rationale for returning and doing something very much like what I
described here, as a first step.
Addendum: Crew Dragon Modified to Leave Lunar Orbit
The “design” trajectory to reach lunar orbit is pretty much
the same as was used for Apollo decades ago. A direct launch from Canaveral into low Earth
orbit more or less eastward at low inclination (the part requiring factoring
ideal delta-vee for gravity and drag losses),
followed by a burn to escape onto the lunar transfer trajectory, and a final upper-stage burn to place the
payload into a retrograde orbit about the moon.
The worst-case total rocket design delta-vee for this is just about 12.4
km/s (factored), and worst-case 0.8 km/s
to leave lunar orbit onto a trajectory home.
See Figure 3.
Figure 3 – Design Trajectory and Delta-Vee Requirements
Design Requirements
for Modified Crew Dragon
Total delta-vee capability 1.35 km/s min, 1.40 preferred. Maximum spacecraft mass at launch 13.0 metric
tons. Minimum crew 3. I have a spreadsheet model already
constructed for this purpose, which I
proceeded to run again for these exact numbers.
Masses for the dry weights of capsule and trunk (before modification)
are my best guesses, but their sum
matches published data.
The modification is to install more tanks of NTO-MMH
propellants in the trunk, to a maximum
of the 3000 kg quoted cargo capacity for that trunk. I estimated propellant-tank mass split as
95-5 or a 19:1 ratio, same as for the
landers. I did not estimate
volumes, although there are 14 cubic
meters available in the trunk for this.
Results That Bound
the Design
These are shown in Figure 4.
Payload mass is limited more by the 13.00 ton thrown weight than the
1.35-1.4 km/s delta-vee requirement. That
payload mass is 1760 kg.
The per person allotment we used for the lander was 200 kg
person-plus-suit, and 100 kg of packed life
support supplies. The life support
supplies are probably a bit of an overkill,
so 1760 kg ~ 1800 kg, and 1800 kg
/ 300 kg/person is crew = 6 max.
Slightly less actually. Call
it no more than 5 crew at a time, plus
life support supplies, and no more than
about 150 kg of equipment or cargo in the capsule with them, for the trip to the moon.
Having the extra delta-vee means we can carry 6 crew, even 7,
home. That is a good safety
bonus. Crew Dragon is supposedly rated
for the same cargo home as cargo Dragon (3000 kg), so we are well within that limit.
This was accomplished by adding 2800 kg propellants to the
trunk, which also adds 147 kg of tank
inerts to the trunk inert weight. That
leaves a smidge for any extra plumbing before we hit the 3000 kg limit.
Figure 4 – Modifying Crew Dragon Into Lunar Orbit Dragon for
Falcon-Heavy Launch
Final Remarks
With these two bounding analyses, I have shown how it is possible to ship
13-ton lunar cargo and crew landers to the lunar orbit with Falcon-Heavy as the
launch rocket. I have also shown how it
is possible to ship crews to lunar orbit with the same rocket and a 13 ton
modified crew Dragon that has 2.8 extra tons of propellant in its trunk, connected to the Super Draco thruster systems
in the capsule.
The cargo landers deliver slightly over 5.3 tons to the
surface. The crew landers have a 5.3 ton
ascent stage that could carry as many as 6 crew back to lunar orbit.
At only $17M/delivered ton,
building a practical small experiment station that is permanently
occupied becomes easily possible, at a
price far below what was experienced doing the Apollo “flag-and-footprints”
stuff during the cold war.
What makes this feasible is a heavy lift rocket of adequate
size to put 13-ton payloads into lunar orbit,
and at a commercial launcher’s far lower price. This is true flying the rockets
fully-expendably. This capability should
become available within the next 1-2 years.
All that is needed from a vehicle development standpoint is
the two versions of the lander designed to these bounding limits, and then developed and made ready for
use. These share a common descent
stage. That should help lower costs and
development time.
Adding propellant capacity to crewed Dragon with tankage in
the trunk is not so much development work,
more of a routine modification that can be tested all-up in Earth
orbit, to make it ready to use.
We’ll need a 2 or 3 seat open electric rover car that weighs
no more than a ton. Between the Apollo
rovers and the recent Mars robot rovers,
this should not be a major development item.
Development,
yes, just not a “biggie”. Same for a 2-ton electric front-end
loader.
The hardest nut to crack is a surface habitat that can be
assembled from modules that fit within the 5 ton lander payload capacity, and that can be erected by men on foot in
spacesuits with hand tools. The idea is
to assemble it in an excavation done with the front end loader, and then bury it at least partially with that
front end loader.
This is the kind of thing that could be done within 1 or 2
presidential terms, which would net
returns orders of magnitude greater than Apollo, for costs orders of magnitude less than
Apollo.
Monday, March 6, 2017
Reverse-Engineered "Dragon" Data
Reverse-Engineering
What the Versions of “Dragon” Can Do
GWJ 2-17-17 updated
3-5-17
Sources: Spacex’s website and the Wikipedia articles
on cargo Dragon, crewed Dragon, and Red Dragon. There is also DragonLab, which is a very close variant of cargo
Dragon. These give dry weights for the
spacecraft that seem to include the associated trunks, except in the case of Red Dragon, which is listed in a very sparse article as
“6.5 ton plus payload up to 1 ton”. Comments
made in public by Spacex have indicated the possibility of more than 2 metric
tons payload to Mars for some time now.
Cargo Dragon: The Wikipedia article lists dry mass as 4200
kg, and speaks of a chute drop test at
5400 kg that includes a max cargo weight of 2500 kg. Propellant quantity for the Draco thrusters
is no longer on Spacex’s site, but was
once listed as just about 1290 kg. The
capsule has a jettisoned nose cone fairing for ascent, for which a wild guess is 50 kg.
The ocean landing test configuration would be capsule dry
mass plus max rated cargo, plus some
propellant residual if not jettisoned after entry and chute deployment. Being toxic,
they should be jettisoned before recovery is attempted by humans. I assumed zero propellant residuals, so that the actual capsule and trunk dry
masses could be determined in this way:
Weight statements for cargo Dragon can now be estimated to
the accuracy that trunk dry mass estimate is accurate, and that the nose cone mass can be
guessed. For three possible cargo
loadouts these are:
Compare the launch weights above with Falcon-9 capability to LEO from Spacex’s website. If flown as an all-expendable launcher, the rocket can send 22.8 metric tons to LEO, and only as a guess probably something close to perhaps 15-17 metric tons to ISS. All the cargo Dragon estimates shown above fall well within that capability, at none over 11.5 metric tons. Whether the booster core is recoverable at 11.5 tons is just not determinable (the website does not list those reduced payload limitations).
One of the
things in the weight statement is the set of ignition and burnout weights for
the capsule-only, no trunk. Cargo Dragon is not operated that way, however!
It retains the trunk until after the reentry burn. So it is capsule-plus-trunk ignition and
burnout weights that we are really interested in.
To get those
ignition and burnout weights, you add
the capsule-only ignition weight and the total loaded trunk weight for
capsule-plus-trunk ignition weight, from
which you delete the propellant for burnout weight. This leaves out the nose cap, which was already jettisoned during
ascent.
The cargo Dragon has 18 Draco thrusters arranged in two pods of 4 and two pods of 5 within the outer mold line. These provide attitude control and maneuvering delta-vee, plus re-entry delta-vee. Each Draco is about 90 lb thrust (400 N). These burn NTO-MMH, for which one might assume Isp = 335 sec for a “good vacuum” engine design, meaning a long bell for high expansion ratio. The corresponding mass ratios (MR) and max theoretical delta-vee capabilities for capsule-plus-trunk are:
Crewed Dragon (Dragon v2): This is the same basic capsule pressure shell and mold line, modified for four protruding pods, each pod containing two Super Draco thruster engines and four Draco thrusters for attitude control and minor maneuver. The Super Dracos are listed on the Wikipedia article as 16,000 lb thrust (71 KN) each. They use the same propellants as the Dracos. Spacex’s website lists the eight total Super Dracos as having 200,000 lb axially-directed thrust (890 KN). Older versions of the site listed the propellant load as just about 1890 kg.
The Wikipedia article lists dry weight as 6400 kg, which apparently includes an empty
trunk. This capsule has the same
chutes, a retained reusable nose
cap, crew life support, crewed interior seats and fitments, and landing legs. The trunk is of similar size, but arranged with conformal surface solar
panels instead of folding solar panel wings.
It does have four aerodynamic fin surfaces for aerodynamic stability during
crew escape situations. There is no
information available anywhere I can find by which to separate the trunk dry
mass from the capsule-plus-trunk dry mass.
Crewed Dragon operates in space as capsule-plus-trunk, until after the reentry burn, when the trunk is jettisoned. The Wikipedia article lists exactly the same
cargo masses and volumes as for cargo dragon.
Unlike cargo Dragon, crewed
Dragon uses the chutes only as a safety backup landing method, or for landing in the ocean. Its intended mode is a propulsive landing on
dry land with the Super Draco engines,
no chutes at all. Because of
this, both the capsule-only and
capsule-with-trunk max theoretical delta-vees are of interest. Note however that you cannot achieve both
simultaneously, because there is only
one propellant supply to be used for both purposes!
The best I could do was to simply assume the two trunks were
comparable mass in spite of the design differences. The uncertainty in the resulting data is
dominated by that assumption.
Again, I assumed Isp = 335 sec for
an exhaust velocity of 3.285 km/s. Using
cargo Dragon’s trunk mass, the crewed dragon capsule dry mass (which includes
the reusable nosecone) is:
This capsule-only dry mass is slightly more than 2 tons higher than cargo Dragon, but there are the eight Super Draco engines, an uprated heat shield, landing legs, life support, and crew seats and fitments to consider, so it is “reasonable”. From this, one can estimate the same sort of weight statement breakout already reported for cargo Dragon, including both capsule-only and capsule-plus-trunk ignition and burnout weights. I did this for only one crew/cargo value, chosen to approximate a capsule-only delta-vee of 0.7 km/s to compare with Red Dragon.
These figures show comparable values of capsule-plus-trunk delta-vee to cargo Dragon’s ~0.5 km/s, which is realistic, considering crewed Dragon is a derivative design, operating in the same capsule-plus-trunk configuration. The slightly-higher capsule-only figure is to compare with crewed Dragon’s unmanned derivative Red Dragon (for one-way probes to Mars). Note that this would vary significantly as crew/cargo is adjusted. Under the assumptions of 100 kg person, 100 kg suit, 50 kg air and water, we are talking about 7 crew plus 1050 kg cargo in this 2800 kg loadout. The weight to launch falls well within the Falcon-9’s LEO capability, being just about like the heaviest cargo Dragon presented above.
Red Dragon: This is the crewed Dragon with the crew seats
and fitments, life support, and chutes removed, and some equipment racks installed. The heat shield is reduced in thickness as
well. Since the vehicle is not to be
reused, a jettisonable nose cap like
that of cargo Dragon is assumed. It will
need some sort of trunk for launch and for electricity during the trip, but this is jettisoned before Mars
entry. Course correction burn is assumed
trivial, so that essentially the entire
propellant load is available for powered landing on Mars.
There are no available data for the masses of any of the
change items just discussed. All that is
available are wild guesses and educated guesses. The lighter heat shield I estimated as a
reduction from 8 cm thick to 6 cm thick,
on a flat circle 3.7 m diameter,
and a specific gravity of ~0.3 for PICA-X. I just rounded off to the nearest 10 kg. It’s just too rough not to round off like
that.
I have just assumed the same trunk mass as I used for cargo and crewed Dragons. Trunk mass dominates the uncertainty, being the largest item. I simply took the crewed Dragon estimated dry mass, and subtracted things. Those guesses are listed in this estimate for Red Dragon dry mass:
If I load this vehicle with 1 ton of cargo and 1890 kg propellant, then mass at entry is 7640 kg, which is not far at all from the 7500 kg indicated the Wikipedia article! 1 ton of cargo is what is indicated as deliverable to Mars in that same article. (Some public announcements indicate that 2-4 tons are actually under consideration at Spacex.)
Using these figures,
the weight statement for Red Dragon can be roughly estimated. What is of interest here is the capsule-only
delta-vee, as a function of cargo
delivered to the surface of Mars. Bear
in mind that an utter minimum delta-vee capability for powered landing will be
near 0.7 km/s, the Mach 3 point coming
out of atmospheric entry hypersonics. There’s
very little in the way of gravity and drag losses to correct the theoretical
delta-vee in this scenario. The error is
less than the uncertainty in the basic requirement.
The 0.7 km/s figure is pretty rough, that being 3 times the nominal speed of sound
in the Martian atmosphere at something like 5 km altitudes. This could vary quite a bit. In order to successfully land reliably, you actually need a little more delta-vee to
cover final maneuvering around obstacles.
The Mach 3 point is also a bit arbitrary, that being only the definition of min-hypersonic for blunt objects. Prior probes deployed chutes at local Mach 2 to 2.5, although they did this much higher up (15-25 km altitudes or more). Waiting to lower speeds lets you penetrate to lower altitudes, while heavier items also penetrate to lower altitudes, simply because of higher ballistic coefficients.
The 0.7 km/s “requirement” I use here is thus just a figure of merit, although it is actually in the ballpark of the true requirement.
These numbers are too rough to judge “for sure”, but it looks like 1 or 2 metric tons should be easily deliverable to Mars with Red Dragon, just like Spacex has indicated. These numbers say 3.2 tons is getting to be quite marginal, but that would actually depend upon what the true landing delta-vee requirement really is. Note that the requirement would vary with location and season across Mars, as that atmosphere is much more variable in its density than is Earth’s.
Spacex’s website lists Falcon-Heavy as able to send 13.6
metric tons to Mars, flown
fully-expendably. All these
configurations fall within that capability.
Even at 4 tons cargo, the weight
to launch would be just about 12 tons,
which still falls within the launch capability. Therefore,
it will be landing delta-vee that sets the payload deliverable to Mars! That may explain the “extra propellant”
remark found in the Wikipedia article. Whether
11 tons at launch is small enough to recover the booster cores is unknown.
DragonLab: this is cargo Dragon with an instrument bay
between the pressure shell and the outer mold line. The door on this bay opens to space, and recloses before entry. It is otherwise the same as cargo
Dragon, so no separate analysis is done
here. Use my figures for cargo Dragon
to represent DragonLab.
Using variants of Red
Dragon as unmanned one-way probes elsewhere: This depends on the delta-vee requirement to
land, relative to the vehicle
capability. For airless destinations
with direct landings from the interplanetary trajectory, several-to-many percent above the body’s
escape speed is a figure of merit. Example: Mars escape 5 km/s, typical direct entry speed 6 to 7 km/s. Call it 1.5 Vesc as a typical
figure of merit. Remember that this is
only a very crude estimate, unlikely to
be correct!
The first thing apparent from the list is that any of the asteroids, Titan, and Mars all seem to be within reach of Red Dragon on a Falcon-Heavy, just as it is. The significant atmospheres of Mars and Titan make aerobraking feasible, the rest are airless or so tenuous as to make aerobraking infeasible. Like the Earth’s moon, the moons of Jupiter seem out-of-reach, due to escape speeds that are too high.
As a one-way probe destination, Earth’s moon is interesting on its own. Key here is getting into lunar orbit using
the upper stage of the launch rocket,
without using any of the Dragon’s propellant. As it turns out, that delta-vee requirement for the launch
rocket (no more than 12.4 km/s) is very similar to that for sending things to
Mars (at least 12.1 km/s). Those
figures include 5% gravity/drag losses on the first 8 km/s of that delta-vee. From there it takes 1.68 km/s to make a
powered landing. That’s out-of-reach for
Red Dragon without considerable extra propellant.
It might be more desirable to instead enter lunar orbit with
a crewed Dragon, and let them rendezvous
in lunar orbit with a separately-sent lunar lander.
The lander must descend and ascend to a delta-vee of
essentially the orbit velocity each way, for an utter minimum of something like
3.36 km/s plus a tad for gravity losses.
At the moon, the crew needs a
minimal place to ride, not a full
capsule, but the stage does need landing
legs. It needs to carry surface stay
gear and a rover, as well. That design is not explored here.
As for the missions to the outer moons, there needs to be a fairly-large propulsion
stage added to the Red Dragon. It seems
like the Dragon probe assembly could be sent to Earth orbit on a Falcon-9, and the propulsion stage sent there with a
Falcon-Heavy, to be docked together in
orbit, and launched on its mission from
there. Very much better information on
velocity requirements is needed to size such an exploration stage design. That is not addressed here.
Conclusions: Red Dragon as presently envisioned works for
Mars, Titan, and any of the asteroids. The other outer planet moons require a fairly
large powered stage added to the Red Dragon to achieve the necessary delta-vee
for capture and landing. The combined
weight exceeds Falcon-Heavy capabilities for direct interplanetary trajectories, so that something other than direct launch to
interplanetary travel is required. Falcon-Heavy
is able to fling 13.6 metric tons to Mars,
perhaps 12-13 tons into lunar orbit.
For Apollo-like lunar missions, crewed Dragon with extra propellant in the
trunk (yielding near 1.6 km/s capability) fits one Falcon-Heavy, and a lander not based on a Dragon fits
another Falcon-Heavy. These need to
weigh under 12-13 metric tons to be successfully launched direct from Earth’s
surface, and must rendezvous in lunar
orbit. Red Dragon itself, as it currently is envisioned, seems unattractive for one-way missions to
the moon, with a direct landing
delta-vee near 2.4 km/s. However, whatever added propulsive stage works for the
outer planet moons would work at Earth’s moon.
Addendum 3-4-17:
I looked very crudely at how much propellant to carry in the
trunk to enable a crew Dragon to depart from lunar orbit and still have
propulsive landing capability at Earth.
This would be for a crew of only two,
with their suits, and about 500
kg of supplies and samples. I did actually
add propellant tank inert mass to the trunk (about 147 kg), which requires iterations. One needs the trunk for electrical power during
the trip home to Earth, so it is
capsule-plus-trunk mass ratio and delta-vee that are pertinent.
Results are given in the Figure just below. It is slightly over 12 metric tons as
launched. Falcon-Heavy just might be
able to deliver this to lunar orbit with a delta-vee of no more than 12.4
km/s, because Spacex’s website says it
can send 13.6 metric tons to Mars (with an estimated delta vee no less than
12.1 km/s). Those delta vee estimates
are my calculations made using Hohmann min-energy transfer ellipses at orbital
semi-major axes that produce the largest delta-vee requirements, and for which I applied 5% gravity and drag loss
to the first 8 km/s getting off the surface of the Earth.
The capsule-plus-trunk needs about 0.8 km/s sec to depart
lunar orbit onto a free-fall homeward trajectory to an aerobraking entry. It perhaps needs about 0.7 km/s capability to
cover a propulsive landing on land, per
the basic design of the crewed Dragon.
The total is 1.5 km/s, for which
a few percent margin gets you quickly to 1.6 km/s capability. The configuration shown in the figure has
such capability by adding some 2800 kg pf propellants to the trunk, in tankage weighing about 147 kg. That total is 2947 kg, within the 3000 kg cargo rating of the trunk. It is the capsule that is lightly loaded at
only 2 suited persons plus modest supplies.
Adding a third crew person pushes the total closer to 13 metric
tons, just about the limit that Falcon
Heavy could possibly deliver to lunar orbit.
Addendum 3-5-17:
The same sort of added propellant in the trunk could also be
done with Red Dragon. Note that I have
already pretty much defined the maximum propellant already at about 2800
kg. Red Dragon being similar to crew
Dragon, the capsule-plus-trunk delta-vees
will fall far short of what is needed to capture and land on the outer planet
moons (1.6 km/s or thereabouts versus 2.5+ km/s). The capsule-only value indicated in the
figure is wrong, because most of that
propellant must be in the trunk.
I’m not at all convinced that a capsule is the best vehicle by which to send probes to the airless bodies, including the asteroids, which Red Dragon could certainly reach. But Red Dragon should serve very well for probes to Mars, and maybe Titan. With aerobraking entry, a capsule and heat shield are necessary.
Crewed Dragon could easily become part of a system to send
men back to the moon with very few changes from what will start flying this
year. Flyby missions need no
changes, and orbit missions require some
extra propellant in the trunk for the Super Dracos. Landings will require a separate lander sent
ahead to lunar orbit unmanned, for the
crew to rendezvous with and utilize. If
such a lander totals under 12-13 metric tons,
Falcon-Heavy could fling it to lunar orbit launched directly from
Earth’s surface.
Final Comments as of Posting 3-6-17:
Enjoy! These figures may not be exactly right, but they are pretty close. I suggest you create spreadsheets to calculate delta-vee in capsule-plus-trunk configurations for cargo Dragon and for crewed Dragon, and for both capsule-plus-trunk and capsule-only Red Dragon.
Then, given real delta-vee data to reach a destination, you can compute for yourself whether the corresponding Dragon configuration can reach it. Be sure to factor-up astronomical values for gravity and drag losses where those apply. This is required before you size mass ratios and weight statements.
There's no information out there about it, but I would hazard the guess that Spacex is already looking at versions of crew Dragon and Red Dragon that have extra propellants in the trunk. That just makes too much sense for them not to be doing that.
GW
Enjoy! These figures may not be exactly right, but they are pretty close. I suggest you create spreadsheets to calculate delta-vee in capsule-plus-trunk configurations for cargo Dragon and for crewed Dragon, and for both capsule-plus-trunk and capsule-only Red Dragon.
Then, given real delta-vee data to reach a destination, you can compute for yourself whether the corresponding Dragon configuration can reach it. Be sure to factor-up astronomical values for gravity and drag losses where those apply. This is required before you size mass ratios and weight statements.
There's no information out there about it, but I would hazard the guess that Spacex is already looking at versions of crew Dragon and Red Dragon that have extra propellants in the trunk. That just makes too much sense for them not to be doing that.