“NK-33”的意思、由来-开放百科全书

The NK-33 and NK-43 are rocket engines designed and built in the late 1960s and early 1970s by the Kuznetsov Design Bureau. The NK designation is derived from the initials of chief designer Nikolay Kuznetsov. The NK-33 was among the most powerful LOX/RP-1 rocket engines when it was built, with a high specific impulse and low structural mass. They were intended for the ill-fated Soviet N-1 rocket Moon shot. The NK-33A rocket engine is now used on the first stage of the Soyuz-2-1v launch vehicle.

Design

The NK-33 series engines are high-pressure, regeneratively cooled staged combustion cycle bipropellant rocket engines. They use oxygen-rich preburners to drive the turbopumps. The turbopumps require subcooled liquid oxygen (LOX) to cool the bearings.^[2]^[3] These kinds of burners are highly unusual, since their hot, oxygen-rich exhaust tends to attack metal, causing burn-through failures. The United States had not investigated oxygen-rich combustion technologies until the Integrated Powerhead Demonstrator project in the early 2000s.^[4] The Soviets, however, perfected the metallurgy behind this method. The nozzle was constructed from corrugated metal, brazed to an outer and inner lining, giving a simple, light, but strong structure. In addition, since the NK-33 uses LOX and RP-1 as propellants, which have similar densities, a single rotating shaft could be used for both turbopumps.^[5]{{not in source|date=April 2016}} The NK-33 engine has among the highest thrust-to-weight ratio of any Earth-launchable rocket engine, only NPO Energomash RD-253 and SpaceX Merlin 1D engine achieve a higher ratio. The specific impulse of the NK-33 is significantly higher than of both these engines. The NK-43 is similar to the NK-33, but is designed for an upper stage, not a first stage. It has a longer nozzle, optimized for operation at altitude, where there is little to no ambient air pressure. This gives it a higher thrust and specific impulse, but makes it longer and heavier. It has a thrust-to-weight ratio of about 120:1.^[6]

The predecessors of NK-33 and NK-43 are the earlier NK-15 and NK-15V engines respectively.

The oxygen-rich technology lives on in the RD-170/-171 engines, their RD-180, and recently developed RD-191 derivatives, but these engines have no direct connection to the NK-33.

History

N-1

The N-1 launcher originally used NK-15 engines for its first stage and a high-altitude modification (NK-15V) in its second stage. After four consecutive launch failures and no successes, the project was cancelled. While other aspects of the vehicle were being modified or redesigned, Kuznetsov improved his contributions into the NK-33 and NK-43 respectively.^[7] The 2nd-generation vehicle was to be called the N-1F. By this point the Moon race was long lost, and the Soviet space program was looking to the Energia as its heavy launcher. No N-1F ever reached the launch pad.^[8]

When the N-1 program was shut down, all work on the project was ordered destroyed. A bureaucrat instead took the engines, worth millions of dollars each, and stored them in a warehouse. Word of the engines eventually spread to America. Nearly 30 years after they were built, disbelieving rocket engineers were led to the warehouse. One of the engines was later taken to America, and the precise specification of the engine was demonstrated on a test stand.^[8]

Combustion-chamber design

About 60 engines survived in the "Forest of Engines", as described by engineers on a trip to the warehouse. In the mid-1990s, Russia sold 36 engines to Aerojet General for $1.1 million each, shipping them to the company facility in Sacramento CA.^[9] During the engine test in Sacramento, the engine hit its specifications. Aerojet now had the proof they needed to sell the engines for the latest launch of satellites. The NK-33 closed-cycle technology works by sending the auxiliary engines' exhaust into the main combustion chamber. This made the engine design unique. This technology was believed to be impossible by Western rocket engineers.^[10] The fully heated liquid O₂ flows through the pre-burner and into the main chamber in this design. The extremely hot oxygen-rich mixture made the engine dangerous: it was known to melt {{convert|3|inch|adj=on}} thick castings "like candle wax". One of the controversies in the Kremlin over supplying the engine to the US was that the design of the engine was similar to Russian ICBM engine design. The NK-33's design was used in the later RD-180 engine, which had twice the size of the NK-33. The RD-180 engines were used (as of 2016) to power Atlas Rockets. This company also acquired a license for the production of new engines. Aerojet has modified and renamed the updated NK-33 to AJ26-58 and AJ26-62, and NK-43 to AJ26-59.^[11]^[12]^[13]

Kistler K-1

Kistler Aerospace, later called Rocketplane Kistler (RpK), designed their K-1 rocket around three NK-33s and an NK-43. On August 18, 2006, NASA announced that RpK had been chosen to develop Commercial Orbital Transportation Services for the International Space Station. The plan called for demonstration flights between 2008 and 2010. RpK would have received up to $207 million if they met all NASA milestones,^[14]^[15]^[16] but on September 7, 2007, NASA issued a default letter, warning that it would terminate the COTS agreement with Rocketplane Kistler in 30 days because RpK had not met several contract milestones.^[17] Eventually the COTS program was won by SpaceX with their Falcon 9, being powered by their self-developed rocket engine, the Merlin.

Antares

The initial version of the Orbital Sciences Antares light-to-medium-lift launcher had two modified NK-33 in the first stage, a solid Castor 30-based second stage and an optional solid or hypergolic third stage.^[18] The NK-33s were imported from Russia to the United States, modified, and re-designated as Aerojet AJ26s. This involved removing some electrical harnessing, adding U.S. electronics, qualifying it for U.S. propellants, and modifying the steering system.^[20]

In 2010 stockpiled NK-33 engines were successfully tested for use by the Orbital Sciences Antares light-to-medium-lift launcher.^[19] The Antares rocket was successfully launched from NASA's Wallops Flight Facility on April 21, 2013. This marked the first successful launch of the NK-33 heritage engines built in early 1970s.^[20]

Aerojet agreed to recondition sufficient NK-33s to serve Orbital's 16-flight NASA Commercial Resupply Services contract. Beyond that, it had a stockpile of 23 1960s- and 1970s-era engines. Kuznetsov no longer manufactures the engines, so Orbital sought to buy RD-180 engines. Because NPO Energomash's contract with United Launch Alliance prevented this, Orbital sued ULA, alleging anti-trust violations.^[21] Aerojet offered to work with Kuznetsov to restart production of new NK-33 engines, to assure Orbital of an ongoing supply.^[22] However, manufacturing defects in the engine's liquid-oxygen turbopump and design flaws in the hydraulic balance assembly and thrust bearings were proposed as two possible causes^[23] of the 2014 Antares launch failure. As announced on 5 November 2014, Orbital decided to drop the AJ-26 first stage from the Antares and source an alternative engine. On 17 December 2014, Orbital Sciences announced that it would use the NPO Energomash RD-181 on second-generation Antares launch vehicles and had contracted directly with NPO Energomash for up to 60 RD-181 engines. Two engines are used on the first stage of the current Antares.^[24]

Current and proposed uses

Soyuz-2-1v

In the early 2010s the Soyuz launch vehicle family was retrofitted with the NK-33 engine – using the lower weight and greater efficiency to increase payload; the simpler design and use of surplus hardware might actually reduce cost.^[26] TsSKB-Progress uses the NK-33 as the first-stage engine of the lightweight version of the Soyuz rocket family, the Soyuz-2-1v.^[27] The NK-33A intended for the Soyuz-2-1v was successfully hot-fired on 15 January 2013,^[28] following a series of cold-fire and systems tests of the fully assembled Soyuz-1 in 2011–2012.^[29] The NK-33 powered rocket was finally designated Soyuz-2-1v, with its maiden flight having taken place on 28 December 2013. One NK-33 engine replaces the Soyuz's central RD-108, with the four boosters of the first stage omitted – a version of the Soyuz rocket with four boosters powered by NK-33 engines (with one engine per booster) is as of 2015 not realized, which results in a reduced payload compared to the Soyuz-2 launch vehicle.

Versions

Gallery

See also

References

1. ^{{cite web|title=LRE NC-33 (11D111) and NC-43 (11D112)|url=http://www.lpre.de/sntk/NK-33/index.htm|accessdate=1 April 2015|language=Russian}}
2. ^{{cite web|title=Soyuz 2-1v|url=http://www.spaceflight101.net/soyuz-2-1v.html|website=spaceflight101.net|accessdate=18 March 2016}}
3. ^{{cite web|title=Orbital ATK ready for Antares’ second life|url=https://www.nasaspaceflight.com/2016/01/orbital-atk-antares-second-life/|website=NASASpaceflight|accessdate=18 March 2016}}
4. ^U.S. Air Force-NASA Technology Demonstrator Engine for Future Launch Vehicles Successfully Fired During Initial Full Duration Test.
5. ^Astronautix NK-33 entry.
6. ^Astronautix NK-43 entry {{webarchive|url=https://web.archive.org/web/20071028111624/http://www.astronautix.com/engines/nk43.htm |date=2007-10-28 }}
7. ^Lindroos, Marcus. The Soviet Manned Lunar Program Massachusetts Institute of Technology. Accessed: 4 October 2011.
8. ^¹{{cite news| last = Clifton| first = Dan| title = The Engines That Came in from the Cold| url = https://www.youtube.com/watch?v=TMbl_ofF3AM| accessdate = 2014-01-03| newspaper = Channel 4| date = 2001-03-01| agency = Ideal World Productions| location = London}}
9. ^{{Cite web|url=http://spacenews.com/36232space-propulsion-development-of-us-closed-loop-kerolox-engine-stuck-in/|title=Space Propulsion {{!}} Development of U.S. Closed-loop Kerolox Engine Stuck in 2nd Gear - SpaceNews.com|date=2013-07-12|language=en-US|access-date=2016-09-17}}
10. ^{{Cite web|url=http://www.russianspaceweb.com/nk33.html|title=NK-33 (14D15) rocket engine|website=www.russianspaceweb.com|access-date=2016-09-17}}
11. ^{{cite web |url = http://www.aerojet.com/capabilities/spacelift.php |title = Space Lift Propulsion |publisher = Aerojet |date = April 2011 |deadurl = yes |archiveurl = https://web.archive.org/web/20110814162849/http://www.aerojet.com/capabilities/spacelift.php |archivedate = 2011-08-14 |df = }}
12. ^{{cite news |last = Clark |first = Stephen |title = Taurus 2 main engine passes gimbal steering test |newspaper = Spaceflight Now |date = 2010-12-19 |location = Tonbridge, Kent, UK |url = http://www.spaceflightnow.com/news/n1012/19aj26test/ |accessdate = 2014-01-03 |archiveurl = https://www.webcitation.org/6MMLYePw3?url=http://www.spaceflightnow.com/news/n1012/19aj26test/ |archivedate = 2014-01-03 |deadurl = no |df = }}
13. ^{{cite web| url = http://www.astronautix.com/engines/nk33.htm| title = NK-33| publisher = Mark Wade (Encyclopedia Astronautica)}}
14. ^{{cite web | url=http://www.spaceflightnow.com/news/n0608/18cots/ | title=NASA selects crew, cargo launch partners | publisher=Spaceflight Now | date=August 18, 2006}}
15. ^{{cite web | url=http://www.spaceref.com/news/viewpr.html?pid=20628 | title=NASA Selects Crew and Cargo Transportation to Orbit Partners | publisher=SpaceRef | date=August 18, 2006}}
16. ^{{cite news | url=http://www.msnbc.msn.com/id/14411983/ | title=SpaceX, Rocketplane win spaceship contest | publisher=MSNBC | date=August 18, 2006 | author=Alan Boyle}}
17. ^{{cite press release |publisher=Aviation Week |date=2007-09-10 |title=RpK's COTS Contract Terminated |url=http://www.aviationweek.com/aw/generic/story.jsp?id=news/rocketplane091007.xml&headline=RpK's%20COTS%20Contract%20Terminated%20&channel=space |accessdate=2007-09-10 |deadurl=yes |archiveurl=https://web.archive.org/web/20110512185739/http://www.aviationweek.com/aw/generic/story.jsp?id=news%2Frocketplane091007.xml&headline=RpK%27s%20COTS%20Contract%20Terminated%20&channel=space |archivedate=2011-05-12 |df= }}
18. ^{{cite web |url=http://www.orbital.com/LaunchSystems/Publications/Antares_UsersGuide.pdf |title=Antares |publisher=Orbital}}
19. ^¹{{cite news|url=http://spaceflightnow.com/news/n1003/15nk33/|title=Aerojet confirms Russian engine is ready for duty|date=March 15, 2010|publisher=Spaceflight Now|first=Stephen|last=Clark|accessdate=2010-03-18|archive-url = https://web.archive.org/web/20130813051804/http://spaceflightnow.com/news/n1003/15nk33|archive-date = 2013-08-13}}
20. ^{{cite web | url=https://www.npr.org/blogs/thetwo-way/2013/04/21/178289293/antares-rocket-launch-is-a-go-in-test-of-space-station-supply-vehicle |title=Antares Rocket Launch Is A Success, In Test Of Orbital Supply Vehicle |author=Bill Chappell |publisher=NPR |date=21 April 2013}}
21. ^{{cite news | url=http://www.spacenews.com/article/launch-report/35956orbital-sues-ula-seeks-rd-180-engines-515-million-in-damages |author=Dan Leone |newspaper=Space News |date=June 24, 2013|title=Orbital Sues ULA, Seeks RD-180 Engines, $515 Million in Damages}}
22. ^{{cite news |url=http://www.aviationweek.com/Article.aspx?id=/article-xml/AW_06_24_2013_p32-590271.xml&p=1 |author=Amy Butler |newspaper=Aviation Week and Space Technology |title=Orbital Frustrated By Lack Of Antares Engine Options |date=24 June 2013 |deadurl=yes |archiveurl=https://web.archive.org/web/20131029202341/http://www.aviationweek.com/Article.aspx?id=%2Farticle-xml%2FAW_06_24_2013_p32-590271.xml&p=1 |archivedate=29 October 2013 |df= }}
23. ^{{cite news|url=http://spaceflightnow.com/2015/11/01/two-antares-failure-probes-produce-different-results/|title=Two Antares failure probes produce different results|date=November 1, 2015|publisher=Spaceflight Now|first=Stephen|last=Clark|accessdate=2015-11-01}}
24. ^{{cite news |last1=Morring|first1=Frank, Jr. |title=Antares Upgrade Will Use RD-181s In Direct Buy From Energomash |url=http://aviationweek.com/space/antares-upgrade-will-use-rd-181s-direct-buy-energomash |accessdate=28 December 2014 |work=Aviation Week |date=16 December 2014 }}
25. ^{{cite web | url = http://www.energia.ru/english/energia/launchers/history.html | title = S.P.Korolev RSC Energia - LAUNCHERS | publisher = Energia}}
26. ^{{cite web | url=http://www.russianspaceweb.com/soyuz1_lv.html | title=The Soyuz 1 (Soyuz 2-1v) Rocket | publisher=Russian Space Web | date=November 2010}}
27. ^{{cite web|url=http://www.russianspaceweb.com/soyuz1_lv.html|title=The Soyuz-1 rocket|last=Zak|first=Anatoly |publisher=Russian Space Web|accessdate=7 March 2010}}
28. ^{{cite web|url=http://samaratoday.ru/news/100779|title=NK-33 Engine Test Successful|publisher=Samara Today|language=Russian|accessdate=March 3, 2013}}
29. ^http://www.kosmonavtika.com/lanceurs/soyouz/version/14A15/14A15.html