“SuperDraco”的意思、由来-开放百科全书

SuperDraco is a hypergolic propellant liquid rocket engine designed and built by SpaceX. It is part of SpaceX's Draco family of rocket engines. A redundant array of eight SuperDraco engines provides fault-tolerant propulsion for use as a launch escape system and propulsive-landing thrust for the Dragon V2 passenger-carrying space capsule.

SuperDraco rocket engines utilize a storable (non-cryogenic) propellant which allows the engines to be fired many months after fueling and launch. They combine the functions of both a reaction control system and a main propulsive engine.

The engines will be used on crew transport flights to low Earth orbit, and was also projected to be used for entry, descent and landing control of the cancelled Red Dragon robotic probe to Mars.

SuperDracos will be used on both the Dragon V2 crew- and cargo-transporting space capsule as well as on the DragonFly suborbital test rocket, a prototype low-altitude reusable rocket that will be used for flight testing various aspects of the propulsive-landing technology. While the engine is capable of {{convert|16400|lbf|N|disp=flip}} of thrust, during use for DragonFly testing, the engines will be throttled to {{convert|15325|lbf|N|disp=flip}} to maintain vehicle stability.^[4]

History

On February 1, 2012 SpaceX announced that it had completed the development of a new, more powerful version of a storable-propellant rocket engine, this one called SuperDraco. This high-thrust hypergolic engine—about 200 times larger than the Draco RCS thruster hypergolic engine—offers deep throttling ability,^[12] and just like the Draco thruster, was designed to provide multiple restart capability and use the same shared hypergolic propellants as Draco. Its primary purpose was to be for SpaceX's launch abort system (LAS) on the Dragon spacecraft. According to a NASA press release, the engine has a transient from ignition to full thrust of 100 ms. During launch abort, eight SuperDracos were expected to fire for 5 seconds at full thrust. The development of the engine was partially funded by NASA's CCDev 2 program.

Name: Draco comes from the Greek drakōn for dragon. Draco (constellation) is a constellation (the Dragon) in the polar region of the Northern Hemisphere near Cepheus and Ursa Major.

Design

SuperDraco engines use a storable propellant mixture of monomethylhydrazine^[1] fuel and dinitrogen tetroxide^[1] oxidizer. They are capable of being restarted many times, and have the capability to deeply reduce their thrust providing precise control during propulsive landing of the Dragon capsule.^[15]

SuperDraco is the second most powerful engine developed by SpaceX, third once the Raptor engines are completed. It is approximately 200 times^[5] more powerful than the Draco thruster engines. By comparison, it is more than twice as powerful as the Kestrel engine that was used in SpaceX's Falcon 1 launch vehicle second stage, about 1/9 the thrust of a Merlin 1D engine, and expected to be 1/26th as powerful as Raptor engines. The order of rocket engine power from lowest to highest will be: Draco, Kestrel, SuperDraco, Merlin, Raptor.

In addition to the use of the SuperDraco thrusters for powered-landings on Earth, NASA's Ames Research Center is studying the feasibility of a Dragon-derived Mars lander for scientific investigation.^[17] Preliminary analysis in 2011 indicated that the final deceleration would be within the retro-propulsion SuperDraco thruster capabilities.^[6]^[7]

SuperDraco is designed to be highly throttleable, from 100 to 20% of full thrust.^[12] This is used for precision controllable propulsive landings of the Dragon V2 spacecraft.

Engine testing

The SuperDraco engine development program had an extensive test program that spanned several years. {{asof|2012|12}}, the SuperDraco ground-test engines had been fired a total of 58 times for a total firing-time duration of 117 seconds and SpaceX expressed hope that the test results would exceed the original requirements for the engine.^[8]

A second version of the engine was developed in 2013, this one manufactured with 3D printing rather than the traditional casting technique. By July 2014, the 3D-printed engine combustion chamber had been fired over 80 times, for a total duration of more than 300 s, and it likewise completed a full qualification test.^[12]

The SuperDraco completed qualification testing in May 2014 – including testing "across a variety of conditions including multiple starts, extended firing durations and extreme off-nominal propellant flow and temperatures."^[9]

By January 2015, SpaceX demonstrated the SuperDraco engine pod with full functionality at McGregor, Texas. Four of these engine pods, each containing two SuperDraco engines, will be used in the Dragon v2 crewed spacecraft.^[10]

In April 2015, SpaceX and NASA set a timeframe to test a Dragon V2's SuperDraco engines with a pad abort test. The test eventually occurred on May 6, 2015, from a test stand at SLC-40, Cape Canaveral Air Force Station.^[11] and was successful.^[12]

Manufacturing

On September 5, 2013 Elon Musk tweeted an image of a regeneratively cooled SuperDraco rocket chamber emerging from an EOS 3D metal printer, and indicated that it was composed of the Inconel superalloy.^[13] This was later shown to be the production technique for the flight-level engines.

It was announced in May 2014 that the flight-qualified version of the SuperDraco engine is the first{{Clarify|date=May 2016}} fully 3D printed rocket engine. In particular, the engine combustion chamber is printed of Inconel, an alloy of nickel and iron, using a process of direct metal laser sintering, and operates at a chamber pressure {{convert|1000|psi|kPa|disp=flip}} at a very high temperature.{{Clarify|date=May 2016}} The engines are contained in a printed protective nacelle to prevent fault propagation in the event of an engine failure.^[14]^[15]^[16]

The ability to 3D print the complex parts was key to achieving the low-mass objective of the engine. According to Elon Musk, "It’s a very complex engine, and it was very difficult to form all the cooling channels, the injector head, and the throttling mechanism. Being able to print very high strength advanced alloys ... was crucial to being able to create the SuperDraco engine as it is."^[17]

The 3D printing process for the SuperDraco engine dramatically reduces lead-time compared to the traditional cast parts, and "has superior strength, ductility, and fracture resistance, with a lower variability in materials properties."^[18]

According to Elon Musk, cost reduction through 3D printing is also significant, in particular because SpaceX can print an hourglass chamber where the entire wall consists of interval cooling channels, which would be impossible without additive manufacturing.^[19]

See also

References

1. ^¹²³{{cite web|url=http://www.nasa.gov/press-release/spacex-demonstrates-astronaut-escape-system-for-crew-dragon-spacecraft-0|title=SpaceX Demonstrates Astronaut Escape System for Crew Dragon Spacecraft|date=6 May 2015|publisher=NASA|accessdate=7 May 2015}}
2. ^¹²http://www.faa.gov/about/office_org/headquarters_offices/ast/environmental/nepa_docs/review/launch/media/fonsi_dragon_pad_abort.pdf
3. ^http://www.spacex.com/press/2014/05/27/spacex-completes-qualification-testing-superdraco-thruster
4. ^¹²{{Citation| last1 = James | first1 = Michael| last2 = Salton| first2 = Alexandria| last3 = Downing| first3 = Micah | title = Draft Environmental Assessment for Issuing an Experimental Permit to SpaceX for Operation of the Dragon Fly Vehicle at the McGregor Test Site, Texas, May 2014 – Appendices| publisher = Blue Ridge Research and Consulting, LCC|pages = 12| date = November 12, 2013|url=http://www.faa.gov/about/office_org/headquarters_offices/ast/media/20140513_DragonFly_DraftEA_Appendices%28reduced%29.pdf}}
5. ^{{cite web |url=http://www.nasa.gov/exploration/commercial/crew/spacex_superdraco.html |title=SpaceX Test Fires Engine Prototype for Astronaut Escape System |publisher=NASA |date=2012-02-01 |accessdate=2012-02-01 }}
6. ^¹{{citation | contribution = Red Dragon | title = Feasibility of a Dragon-derived Mars lander for scientific and human-precursor investigations | publisher = 8m.net | date = October 31, 2011| id = | contribution-url = http://digitalvideo.8m.net/SpaceX/RedDragon/karcz-red_dragon-nac-2011-10-29-1.pdf | format = PDF | accessdate = 2012-05-14}}
7. ^{{cite web | archiveurl = https://web.archive.org/web/20130120203325/https://science.nasa.gov/media/medialibrary/2012/01/23/NAC_Science_Meeting_ReportOctober_31-November_1_2011-finalTAGGED.pdf | archivedate = 2013-01-20 | deadurl = yes | url = https://science.nasa.gov/media/medialibrary/2012/01/23/NAC_Science_Meeting_ReportOctober_31-November_1_2011-finalTAGGED.pdf | title = NASA ADVISORY COUNCIL (NAC) - Science Committee Report | accessdate = 2012-05-01 | date = 1 November 2011 | format = PDF | work = Ames Research Center, NASA | df =}}
8. ^{{cite web |last=Staff |title=NASA’s Return On Investment Report |url=http://www.nasa.gov/pdf/713805main_December_2012_60_Day_Report2.pdf |accessdate=2015-12-30 |date=2012-12-14 }}
9. ^¹{{cite news|title=SuperDraco Thruster Powers Revolutionary Launch Escape System (Rocket Thruster Test)|url=http://www.satnews.com/story.php?number=468976793&menu=1|accessdate=2014-05-28|newspaper=Satnews Daily|date=2014-05-27}}
10. ^{{cite web|title=Full functionality of Crew Dragon's SuperDraco jetpacks demonstrated with hotfire test in McGregor, TX.|url=https://vine.co/v/OTBtbH9Bxzm|website=vine.co|publisher=Vine|accessdate=24 January 2015}}
11. ^{{cite news|url=http://spaceflightnow.com/2015/04/21/dragon-pad-abort-test-set-for-early-may/|title=Dragon pad abort test set for early May|last=Clark|first=Stephen|date=21 April 2015|work=Spaceflight Now}}
12. ^{{cite news|url= https://arstechnica.com/science/2016/04/meet-spacexs-superdraco-thruster-the-key-to-landing-a-dragon-on-mars/ |title= From zero to 100mph in 1.2 seconds, the SuperDraco thruster delivers |work= Ars Technica |first= Eric |last= Berger |date= 2016-04-30 |accessdate= 2017-02-04}}
13. ^https://twitter.com/elonmusk/status/375737311641628672?screen_name=elonmusk
14. ^¹²{{cite news |last=Bergin|first=Chris |title=SpaceX lifts the lid on the Dragon V2 crew spacecraft |url=http://www.nasaspaceflight.com/2014/05/spacex-lifts-the-lid-dragon-v2-crew-spacecraft/ |accessdate=2014-05-30 |newspaper=NASAspaceflight.com |date=2014-05-30 }}
15. ^{{cite news |last=Norris|first=Guy |title=SpaceX Unveils ‘Step Change’ Dragon ‘V2’ |url=http://aviationweek.com/space/spacex-unveils-step-change-dragon-v2|accessdate=2014-05-30 |newspaper=Aviation Week |date=2014-05-30 }}
16. ^{{cite news |last=Kramer|first=Miriam |title=SpaceX Unveils Dragon V2 Spaceship, a Manned Space Taxi for Astronauts — Meet Dragon V2: SpaceX's Manned Space Taxi for Astronaut Trips |url=http://www.space.com/26063-spacex-unveils-dragon-v2-manned-spaceship.html |accessdate=2014-05-30 |newspaper=space.com |date=2014-05-30 }}
17. ^{{cite news|last=Foust|first=Jeff|url=http://www.newspacejournal.com/2014/05/30/spacex-unveils-its-21st-century-spaceship/|title=SpaceX unveils its "21st century spaceship"|accessdate=2014-05-31|newspaper=NewSpace Journal|date=2014-05-30}}
18. ^¹²³{{cite web |title=SpaceX Launches 3D-Printed Part to Space, Creates Printed Engine Chamber for Crewed Spaceflight |url=http://www.spacex.com/news/2014/07/31/spacex-launches-3d-printed-part-space-creates-printed-engine-chamber-crewed |publisher=SpaceX |accessdate=2014-08-01 |quote=Compared with a traditionally cast part, a printed [part] has superior strength, ductility, and fracture resistance, with a lower variability in materials properties. ... The chamber is regeneratively cooled and printed in Inconel, a high performance superalloy. Printing the chamber resulted in an order of magnitude reduction in lead-time compared with traditional machining – the path from the initial concept to the first hotfire was just over three months. During the hotfire test, ... the SuperDraco engine was fired in both a launch escape profile and a landing burn profile, successfully throttling between 20% and 100% thrust levels. To date the chamber has been fired more than 80 times, with more than 300 seconds of hot fire.}}
19. ^{{cite AV media |people=Elon Musk, Mike Suffradini |date=7 July 2015 |title=Elon Musk comments on Falcon 9 explosion - Huge Blow for SpaceX (2015.7.7)|medium=video |language= |url=https://www.youtube.com/watch?v=hJD0MMP4nkM |access-date=2015-12-30 |archive-url=https://web.archive.org/web/20150906075127/https://www.youtube.com/watch?v=hJD0MMP4nkM|archive-date=2015-09-06|format= |time= |dead-url=yes |quote=}}