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The Saturn MLV was a proposed concept family of
S-IC height growth would have been limited to , because of enclosed barge limits. If this was solved, height growth would have been limited to , because of vertical assembly crane limits.
The MS-IC-1 first stage would have been strengthened, because of higher structural loads. It would also have been stretched . The propellant pressurization system would have had 15% higher flow rates to account for the differences between the F-1 and F-1A engines. The stage would have weighed more than the S-IC while empty.
The MS-IC-1A would have been a variant of the MS-IC-1 with 6 engines individually weaker than the MS-IC-1's engines. The total amount of thrust would have been about 1.46% higher than the MS-IC-1. Because of the additional engine, inboard gimbal is limited to 2.5°, while outboard is restricted to 7.8°. This would have not posed large control issues. Additional supply lines would have been needed for the MS-IC-1A. The stage would have weighed more than the MS-IC-1 and more than the S-IC, while empty. Manufacturing would remain largely similar, while testing and vehicle assembly equipment would see major changes.
Other variants studied were the MS-IC-4(S)B (336 inch stretch), MS-IC/260 (fuel and propellant tanks housed above strap-on solid rocket motors), MS-IC-23(L) (240 inch stretch) and MS-IC-3B (20 foot stretch with F-1A engines).
The MS-II-1 variant would have been almost unchanged from the S-II stage, except for it being strengthened to handle increased flight loads. Manufacturing and GSE would not have had major changes.
The MS-II-1A variant would have had seven J-2 engines. Major changes would have been in the propulsion and thrust structure. The variant would have been extended to account for the of propellant.
The MS-II-2 variant would have had to have the thrust structure redesigned, because of the switch to the HG-3 engine. Propellant load would be increased up to a maximum of and stage length would have been extended less than or equal to , without major facility changes. Because of the HG-3 engine, the interface between the stage and engines would have needed changes. Electrical, propellant management and propellant dispersion systems would also have required changes.
Manufacturing changes for the MS-II-2 variant from the MS-II-1 variant would have been small, except for the increased diameter of the HG-3 engine's feedlines' increased diameter causing changes to the
The MS-IVB-1 third stage would have had the same size and shape as the unmodified S-IVB stage, but it would have been strengthened because of the larger payload capacity and flight stresses. The J-2
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Apollo program Saturn V Saturn MLV {{Saturns
The Saturn MLV was a proposed concept family of rocket
A rocket (from , and so named for its shape) is a vehicle that uses jet propulsion to accelerate without using any surrounding air. A rocket engine produces thrust by reaction to exhaust expelled at high speed. Rocket engines work entirely ...
s, intended as a follow-on to the Saturn V
The Saturn V is a retired American super heavy-lift launch vehicle developed by NASA under the Apollo program for human exploration of the Moon. The rocket was human-rated, had multistage rocket, three stages, and was powered by liquid-propel ...
. MLV stands for "Modified Launch Vehicle".
Vehicle configurations representative of several alternative uprating methods were specified by the Marshall Space Flight Center
Marshall Space Flight Center (officially the George C. Marshall Space Flight Center; MSFC), located in Redstone Arsenal, Alabama (Huntsville, Alabama, Huntsville postal address), is the Federal government of the United States, U.S. government's ...
for initial studies.
Proposed modifications
# Thrust uprating and modifying of the five F-1 rocket engines used in the firstS-IC
The S-IC (pronounced S-one-C) was the first stage of the American Saturn V rocket. The S-IC stage was manufactured by the Boeing Company. Like the first stages of most rockets, more than 90% of the mass at launch was propellant, in this case RP ...
stage, and corresponding increases in propellant tank capacities.
# Addition of a sixth F-1 engine in the S-IC stage, as an alternative to engine uprating, plus increased propellant capacities.
# Use of UA1205
UA120 was a family of American solid rocket boosters, manufactured by the Chemical Systems Division of United Aircraft (later United Technologies Corporation). They were used as strap-on boosters for the Titan rocket family. Several variants exist ...
solid rocket boosters
A solid rocket booster (SRB) is a solid propellant motor used to provide thrust in spacecraft launches from initial launch through the first ascent. Many launch vehicles, including the Atlas V, SLS and Space Shuttle, have used SRBs to give launch ...
derived from the Titan IIIC
The Titan IIIC was an expendable launch system used by the United States Air Force from 1965 until 1982. It was the first Titan (rocket family), Titan booster to feature large solid rocket motors and was planned to be used as a launcher for the D ...
vehicle.
# Additional J-2 engines in the S-II stage, ~131 s increased upper stage propellant capacities.
# Improved or advanced upper stage engines, such as the HG-3, plus increased propellant capacities.
The baseline Saturn MLV would incorporate these changes from the Saturn V vehicle.
The Saturn IC first stage would have been stretched with of propellant and five new F-1A engines;
the S-II
The S-II (pronounced "S-two") was the second stage of the Saturn V rocket. It was built by North American Aviation. Using liquid hydrogen (LH2) and liquid oxygen (LOX) it had five J-2 engines in a quincunx pattern. The second stage accelerated ...
second stage would have been stretched with of propellant and five J-2 engines;
the S-IVB
The S-IVB (pronounced "S-four-B") was the third stage on the Saturn V and second stage on the Saturn IB launch vehicles. Built by the Douglas Aircraft Company, it had one J-2 rocket engine. For lunar missions it was fired twice: first for Earth ...
third stage would have been strengthened, but with a standard of propellant, and one J-2 engine. Nuclear propulsion
Nuclear propulsion includes a wide variety of propulsion methods that use some form of nuclear reaction as their primary power source. Many aircraft carriers and submarines currently use uranium fueled nuclear reactors that can provide propulsio ...
in the third stage and toroidal J-2 engines in the second and third stages were also investigated.
MS-IC first stage
S-IC height growth would have been limited to , because of enclosed barge limits. If this was solved, height growth would have been limited to , because of vertical assembly crane limits.
The MS-IC-1 first stage would have been strengthened, because of higher structural loads. It would also have been stretched . The propellant pressurization system would have had 15% higher flow rates to account for the differences between the F-1 and F-1A engines. The stage would have weighed more than the S-IC while empty.
The MS-IC-1A would have been a variant of the MS-IC-1 with 6 engines individually weaker than the MS-IC-1's engines. The total amount of thrust would have been about 1.46% higher than the MS-IC-1. Because of the additional engine, inboard gimbal is limited to 2.5°, while outboard is restricted to 7.8°. This would have not posed large control issues. Additional supply lines would have been needed for the MS-IC-1A. The stage would have weighed more than the MS-IC-1 and more than the S-IC, while empty. Manufacturing would remain largely similar, while testing and vehicle assembly equipment would see major changes.
Other variants studied were the MS-IC-4(S)B (336 inch stretch), MS-IC/260 (fuel and propellant tanks housed above strap-on solid rocket motors), MS-IC-23(L) (240 inch stretch) and MS-IC-3B (20 foot stretch with F-1A engines).
MS-II second stage
The MS-II-1 variant would have been almost unchanged from the S-II stage, except for it being strengthened to handle increased flight loads. Manufacturing and GSE would not have had major changes.
The MS-II-1A variant would have had seven J-2 engines. Major changes would have been in the propulsion and thrust structure. The variant would have been extended to account for the of propellant.
The MS-II-2 variant would have had to have the thrust structure redesigned, because of the switch to the HG-3 engine. Propellant load would be increased up to a maximum of and stage length would have been extended less than or equal to , without major facility changes. Because of the HG-3 engine, the interface between the stage and engines would have needed changes. Electrical, propellant management and propellant dispersion systems would also have required changes.
Manufacturing changes for the MS-II-2 variant from the MS-II-1 variant would have been small, except for the increased diameter of the HG-3 engine's feedlines' increased diameter causing changes to the LH2
Liquid hydrogen () is the liquid state of the element hydrogen. Hydrogen is found naturally in the molecular H2 form.
To exist as a liquid, H2 must be cooled below its critical point of 33 K. However, for it to be in a fully liquid stat ...
tanks feedline fittings. Changes to the LOX
Lox is a fillet of brined salmon, which may be smoked. Lox is frequently served on a bagel with cream cheese, and often garnished with tomato, onion, cucumber, and capers.
Etymology
The American English word ''lox'' is a borrowing of Yiddi ...
tank and thrust structure would also have required changes. GSE changes would also have required changes for handling, transportation. New equipment for propulsion systems would also have been required. Changes would have been required to facilities, in order to have space for duplicate tooling. Testing would only have required minor changes to facilities.
Other variants studied were the MS-II-1-J-2T-200K (41 inch stretch and J-2T-200K engines), MS-II-1-J-2T-250K (41 inch stretch and J-2T-250k engines), MS-II-3B (15.5 foot stretch) and MS-II-4(S)B.
MS-IVB third stage
The MS-IVB-1 third stage would have had the same size and shape as the unmodified S-IVB stage, but it would have been strengthened because of the larger payload capacity and flight stresses. The J-2 LOX
Lox is a fillet of brined salmon, which may be smoked. Lox is frequently served on a bagel with cream cheese, and often garnished with tomato, onion, cucumber, and capers.
Etymology
The American English word ''lox'' is a borrowing of Yiddi ...
pump would have been modified. The MS-IVB-1 would have weighed more than the S-IVB. Manufacturing for the MS-IVB-1 would only have required minor changes. The helium repressurization system would have replaced ambient helium bottles with cold ones and a heater.
The MS-IVB-2 would have been a stretched version of the S-IVB using the HG-3 engine. The MS-IVB-2 would also have required strengthening. The thrust structure would have been replaced, because of the higher thrust of the HG-3 engine. The LOX tank would have received an additional cylindrical segment. The propulsion system's helium system would have been modified in a similar way as the MS-IVB-1, but with an additional heater. The common bulkhead would have been flatter. Because of the switch to the HG-3 engine, the LOX and LH2
Liquid hydrogen () is the liquid state of the element hydrogen. Hydrogen is found naturally in the molecular H2 form.
To exist as a liquid, H2 must be cooled below its critical point of 33 K. However, for it to be in a fully liquid stat ...
chilldown pumps would have been removed. Manufacturing would have required major changes, with under half of the 52 major tools unchanged. GSE models would also have to be largely modified, with again under half remaining unchanged.
The MS-IVB-1A is similar to the MS-IVB-2, but with a J-2 engine and thrust structure. It also has heavier tank walls and other less notable changes.
Other variants studied were the MS-IVB-3B and the MS-IVB-4(S)B.
Engine uprating
Some MLV configurations would have required that some engines were uprated.F-1 Uprating
As an alternative to adding an additional engine, uprating the thrust was investigated. The investigation used the 1522K configuration as the base for uprating. All uprated engines would have had to use a turbine, because the uprating was limited by the turbine used on the 1552K configuration. Besides the 30 inch turbine, the 1650K config would have required improved pump impellers, and a stronger gas generator at a lower mixture ratio. The 1800K configuration would have required an increased pump impeller diameter, increasing gas generator volume to solve temperature control issues, and reducing turbine exhaust back-pressure. Uprating past the 1800K configuration would have been limited byturbopump
A turbopump is a fluid pump with two main components: a rotodynamic pump and a driving gas turbine, usually both mounted on the same shaft, or sometimes geared together. They were initially developed in Germany in the early 1940s. The most co ...
torque and critical speed.
J-2 Uprating
and thrust variants were selected for uprating studies, with the base variant being the variant. Uprating to the variant would have required changes to the turbopumps, gas generator control valve, thrust chamber bypass system, and the injector. To uprate to the variant from the variant would have required changes to the oxidizer turbopump assembly, concentric gas generator control valve, fuel turbopump, and high-pressure ducts added with the uprating.Nuclear propulsion
In the MS-IVB stages, the use of nuclear propulsion could have been used to achieve higherTrans-lunar injection
A trans-lunar injection (TLI) is a propulsive maneuver, which is used to send a spacecraft to the Moon. Typical lunar transfer trajectories approximate Hohmann transfers, although low-energy transfers have also been used in some cases, as with ...
performance.
Because of the lower density of LH2, the vehicle would have been taller. This would have caused higher structural loads and sometimes would have exceeded facility height limitations. The higher structural loads are believed to be solvable without major changes. Both V-3 vehicles and the V-1/NERVA would have had exceeded the height limit by up to . Limiting nuclear engine propellant to reduce the height to would have caused payload to TLI being reduced by up to approximately . This could have been solved by:
# Using diameter stages.
# Shortening off-loaded chemical boost stage propellant tanks.
# Assembling the uppermost stages outside the VAB.
# Using hammerhead nuclear stages.
# Increasing the height of one VAB cell's hook height.
Crawler-related changes and issues are road load limits, and location of service arms and checkout equipment.
References
*External links
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Apollo program Saturn V Saturn MLV {{Saturns