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The '''Sea Dragon''' was a 1962 conceptualized design study for a [[two stage to orbit|two-stage]] [[submarine-launched ballistic missile|sea-launched]] orbital [[super heavy-lift launch vehicle]]. The project was led by [[Robert Truax]] while working at [[Aerojet]], one of a number of designs he created that were to be launched by floating the rocket in the ocean. Although there was some interest at both [[NASA]] and [[Vigor Shipyards|Todd Shipyards]], the project was not implemented. At the massive dimensions of {{convert|150|m|ft|abbr=on}} long and {{convert|23|m|ft|abbr=on}} in diameter, Sea Dragon would have been the largest rocket ever built. {{Asof|2018}}, among rockets that have been fully conceived, it is by far the largest ever and, in terms of payload into [[low Earth orbit]] (LEO), rivaled only by the [[Interplanetary Transport System]] in its expendable configuration.
The '''Sea Dragon''' was a 1962 conceptualized design study for a [[two stage to orbit|two-stage]] [[submarine-launched ballistic missile|sea-launched]] orbital [[super heavy-lift launch vehicle]]. The project was led by [[Robert Truax]] while working at [[Aerojet]], one of a number of designs he created that were to be launched by floating the rocket in the ocean. Although there was some interest at both [[NASA]] and [[Vigor Shipyards|Todd Shipyards]], the project was not implemented. At the massive dimensions of {{convert|150|m|ft|abbr=on}} long and {{convert|23|m|ft|abbr=on}} in diameter, Sea Dragon would have been the largest rocket ever built. {{Asof|2018}}, among rockets that have been fully conceived, it is by far the largest ever and, in terms of payload into [[low Earth orbit]] (LEO), rivaled only by the [[Interplanetary Transport System]] in its expendable configuration.


==Design==ay of support systems. A large ballast tank system attached to the bottom of the first-stage [[de Laval nozzle|engine bell]] was used to "hoist" the rocket vertical foty. The system would be at least partially reusable with passive reentry and recovery of rocket sections for refurbishment and relaunch.<ref name=PopMech-2017-04-07>{{cite magazine |url= http://www.popularmechanics.com/space/rockets/a25915/sea-dragon-history-curious-droid/ |title= The Enormous Sea-Launched Rocket That Never Flew |author= David Grossman |date= 3 April 2017 |magazine= Popular Mechanics }}</ref><ref name=CiS-2013-01>{{cite web |url= http://www.citizensinspace.org/2013/01/historical-note-the-legend-of-the-sea-dragon/ |title= The Legend of the Sea Dragon |date= January 2013 |publisher= Citizens in Space }}</ref>
==Design==
Truax's basic idea was to produce a low-cost heavy launcher, a concept now called "[[big dumb booster]]". To lower the cost of operation, the rocket itself was launched from the ocean, requiring little in the way of support systems. A large ballast tank system attached to the bottom of the first-stage [[de Laval nozzle|engine bell]] was used to "hoist" the rocket vertical for launch. In this orientation the payload at the top of the second stage was just above the waterline, making it easy to access. Truax had already experimented with this basic system in the Sea Bee<ref>Astronautix.com, [http://www.astronautix.com/s/seabee.html Sea Bee]</ref><ref group=NB>Sea Bee was a proof of principle ''program'' to validate the sea-launch concept. A surplus [[Aerobee]] rocket was modified so that it could be fired underwater. The rocket worked properly the first time in restrained mode. Later tests of repeat firings proved so simple that the cost of turn-around was about 7% that of a new unit.</ref> and Sea Horse.<ref>Astronautix.com, [http://www.astronautix.com/s/seahorse.html Sea Horse]</ref><ref group=NB>Sea Horse demonstrated sea-launch at a larger scale and on a rocket with a complex set of guidance and control systems. It used a surplus {{convert|9000|kgf|lbf N|abbr=on}} pressure fed, acid/aniline [[Corporal missile]] on a barge in San Francisco Bay. This was first fired several metres above the water, then lowered and fired in successive steps until reaching a considerable depth. Firing from underwater posed no problems, and there was substantial noise attenuation.</ref> To lower the cost of the rocket, he intended it to be built of inexpensive materials, specifically 8&nbsp;mm [[steel sheeting]]. The rocket would be built at a sea-side shipbuilder and towed to sea for launch. It would use wide engineering margins with strong simple materials to further enhance reliability and reduce cost of complexity. The system would be at least partially reusable with passive reentry and recovery of rocket sections for refurbishment and relaunch.<ref name=PopMech-2017-04-07>{{cite magazine |url= http://www.popularmechanics.com/space/rockets/a25915/sea-dragon-history-curious-droid/ |title= The Enormous Sea-Launched Rocket That Never Flew |author= David Grossman |date= 3 April 2017 |magazine= Popular Mechanics }}</ref><ref name=CiS-2013-01>{{cite web |url= http://www.citizensinspace.org/2013/01/historical-note-the-legend-of-the-sea-dragon/ |title= The Legend of the Sea Dragon |date= January 2013 |publisher= Citizens in Space }}</ref>


The first stage was to be powered by a single enormous {{convert|36000000|kgf|MN lbf|abbr=on}} thrust engine burning [[RP-1]] and LOX ([[liquid oxygen]]). The fuels were [[Pressure-fed engine (rocket)|pushed into the engine]] by [[liquid nitrogen]], which provided a pressure of {{convert|32|atm|kPa psi|abbr=on}} for the RP-1 and {{convert|17|atm|kPa psi|abbr=on}} for the LOX, providing a total pressure in the engine of {{convert|20|atm|kPa psi|abbr=on}} at takeoff. As the vehicle climbed the pressures dropped off, eventually burning out after 81 seconds. By this point the vehicle was {{convert|25|mi|km}} up and {{convert|20|mi|km|abbr=on}} downrange, traveling at a speed of {{convert|4,000|mph|kph km/s|abbr=on}}. The normal mission profile expended the stage in a high-speed splashdown some {{convert|180|mi|km}} downrange. Plans for stage recovery were studied as well.
The first stage was to be powered by a single enormous {{convert|36000000|kgf|MN lbf|abbr=on}} thrust engine burning [[RP-1]] and LOX ([[liquid oxygen]]). The fuels were [[Pressure-fed engine (rocket)|pushed into the engine]] by [[liquid nitrogen]], which provided a pressure of {{convert|32|atm|kPa psi|abbr=on}} for the RP-1 and {{convert|17|atm|kPa psi|abbr=on}} for the LOX, providing a total pressure in the engine of {{convert|20|atm|kPa psi|abbr=on}} at takeoff. As the vehicle climbed the pressures dropped off, eventually burning out after 81 seconds. By this point the vehicle was {{convert|25|mi|km}} up and {{convert|20|mi|km|abbr=on}} downrange, traveling at a speed of {{convert|4,000|mph|kph km/s|abbr=on}}. The normal mission profile expended the stage in a high-speed splashdown some {{convert|180|mi|km}} downrange. Plans for stage recovery were studied as well.

Revision as of 18:18, 12 February 2020

Sea Dragon internal and external views. Both show the ballast tank attached to the first stage engine bell. An Apollo CSM-like spacecraft is mounted on top.
Saturn V. Its second stage would fit inside the first stage engine and nozzle of the Sea Dragon.

The Sea Dragon was a 1962 conceptualized design study for a two-stage sea-launched orbital super heavy-lift launch vehicle. The project was led by Robert Truax while working at Aerojet, one of a number of designs he created that were to be launched by floating the rocket in the ocean. Although there was some interest at both NASA and Todd Shipyards, the project was not implemented. At the massive dimensions of 150 m (490 ft) long and 23 m (75 ft) in diameter, Sea Dragon would have been the largest rocket ever built. As of 2018, among rockets that have been fully conceived, it is by far the largest ever and, in terms of payload into low Earth orbit (LEO), rivaled only by the Interplanetary Transport System in its expendable configuration.

==Design==ay of support systems. A large ballast tank system attached to the bottom of the first-stage engine bell was used to "hoist" the rocket vertical foty. The system would be at least partially reusable with passive reentry and recovery of rocket sections for refurbishment and relaunch.[1][2]

The first stage was to be powered by a single enormous 36,000,000 kgf (350 MN; 79,000,000 lbf) thrust engine burning RP-1 and LOX (liquid oxygen). The fuels were pushed into the engine by liquid nitrogen, which provided a pressure of 32 atm (3,200 kPa; 470 psi) for the RP-1 and 17 atm (1,700 kPa; 250 psi) for the LOX, providing a total pressure in the engine of 20 atm (2,000 kPa; 290 psi) at takeoff. As the vehicle climbed the pressures dropped off, eventually burning out after 81 seconds. By this point the vehicle was 25 miles (40 km) up and 20 mi (32 km) downrange, traveling at a speed of 4,000 mph (6,400 km/h; 1.8 km/s). The normal mission profile expended the stage in a high-speed splashdown some 180 miles (290 km) downrange. Plans for stage recovery were studied as well.

The second stage was also equipped with a single very large engine, in this case a 6,000,000 kgf (59 MN; 13,000,000 lbf) thrust engine burning liquid hydrogen and LOX. It was also pressure-fed, at a constant lower pressure of 7 atm (710 kPa; 100 psi) throughout the entire 260 second burn, at which point it was 142 mi (229 km) up and 584 mi (940 km) downrange. To improve performance, the engine featured an expanding engine bell, changing from 7:1 to 27:1 expansion as it climbed. The overall height of the rocket was shortened somewhat by making the "nose" of the first stage pointed, lying inside the second stage engine bell.

A typical launch sequence would start with the rocket being refurbished and mated to its cargo and ballast tanks on shore. The RP-1 and nitrogen would also be loaded at this point. The rocket would then be towed to a launch site, where the LOX and LH2 would be generated on-site using electrolysis; Truax suggested using a nuclear-powered aircraft carrier as a power supply during this phase. The ballast tanks, which also served as a cap and protection for the first stage engine bell, would then be filled with water, raising the rocket to vertical. Last minute checks could then be carried out, and the rocket launched.

The rocket would have been able to carry a payload of up to 550 tonnes (540 long tons; 610 short tons) or 550,000 kg (1,210,000 lb) into LEO. Payload costs, in 1963, were estimated to be between $59 to $600 per kg. TRW (Space Technology Laboratories, Inc.) conducted a program review and validated the design and its expected costs.[3] However, budget pressures led to the closing of the Future Projects Branch, ending work on the super-heavy launchers they had proposed for a crewed mission to Mars.

Principle of the Sea Dragon rocket
Principle of the Sea Dragon
Composite of two NASA technical drawings, of the Saturn V rocket and the proposed Sea Dragon rocket, to the same scale

Sea Dragon in fiction

The Sea Dragon appears in the season finale of the 2019 Apple TV+ series For All Mankind. In the post-credits scene, set in 1983 in an alternate timeline in which the Soviet Union landed on the Moon before the United States, a Sea Dragon is depicted launching from the Pacific Ocean to resupply the US lunar colony. It is stated that the ocean launch is a precaution because the payload includes nuclear material.

See also

Notes

References

  1. ^ David Grossman (3 April 2017). "The Enormous Sea-Launched Rocket That Never Flew". Popular Mechanics.
  2. ^ "The Legend of the Sea Dragon". Citizens in Space. January 2013.
  3. ^ "Study of Large Sea-Launch Space Vehicle," Contract NAS8-2599, Space Technology Laboratories, Inc./Aerojet General Corporation Report #8659-6058-RU-000, Vol. 1 – Design, January 1963