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Adding SF startup "Astranis". May add Anduril as well, depends on if they launch
 
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{{More citations needed|date=March 2021}}
{{More citations needed|date=March 2021}}
}}
}}
{{Use dmy dates|date=September 2013}}
{{Use dmy dates|date=September 2024}}
{{Expand list|date=August 2008}}
{{Incomplete list|date=August 2008}}


==History==
==History==
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| United States
| United States
|
|
| formerly [[Boeing Integrated Defense Systems]]
| formerly [[Boeing Integrated Defense Systems]]
|-
|-
| [[INVAP]]
| [[INVAP]]
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| [[JSC Information Satellite Systems]]
| [[JSC Information Satellite Systems]]
| Russia
| Russia
| 1200<ref>{{Cite web|title=Company overview|url=http://www.iss-reshetnev.com/about|access-date=2022-01-30|website=www.iss-reshetnev.com}}</ref>
| 1200<ref>{{Cite web|title=Company overview|url=http://www.iss-reshetnev.com/about|access-date=2022-01-30|website=iss-reshetnev.com}}</ref>
| formerly NPO PM
| formerly NPO PM
|-
|-
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| [[SSL (company)|Maxar Space]]
| [[SSL (company)|Maxar Space]]
| United States
| United States
| 285<ref>{{Cite web|title=About Us|url=https://www.maxar.com/about|access-date=2022-01-30|website=www.maxar.com}}</ref><ref>{{Cite web|last=Cook|first=Kevin|title=Bull of the Day: Maxar Technologies (MAXR)|url=https://www.entrepreneur.com/article/412735|access-date=2022-01-30|website=Entrepreneur|language=en}}</ref>
| 285<ref>{{Cite web|title=About Us|url=https://www.maxar.com/about|access-date=2022-01-30|website=maxar.com}}</ref><ref>{{Cite web|last=Cook|first=Kevin|title=Bull of the Day: Maxar Technologies (MAXR)|url=https://www.entrepreneur.com/article/412735|access-date=2022-01-30|website=Entrepreneur|archive-date=31 January 2022|archive-url=https://web.archive.org/web/20220131113137/https://www.entrepreneur.com/article/412735|url-status=dead}}</ref>
| formerly Space Systems Loral, formally SSL, subsidiary of [[Maxar Technologies]]
| formerly Space Systems Loral, formally SSL, subsidiary of [[Maxar Technologies]]
|-
|-
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| United States
| United States
|
|
| Closed <ref>{{cite web|url=http://spacenews.com/comtech-shut-down-aeroastro-small-satellite-operation/|title=Comtech To Shut Down AeroAstro Small-satellite Operation - SpaceNews.com|date=16 July 2012|website=Spacenews.com|access-date=11 August 2017}}</ref>
| Closed<ref>{{cite web|url=http://spacenews.com/comtech-shut-down-aeroastro-small-satellite-operation/|title=Comtech To Shut Down AeroAstro Small-satellite Operation SpaceNews.com|date=16 July 2012|website=Spacenews.com|access-date=11 August 2017}}</ref>
|-
|-
| [[Argotec]]
| [[Argotec]]
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|
|
| CubeSats and Small Satellites
| CubeSats and Small Satellites
|-
| [[Astranis]]
| United States
| 1
| Geostationary & Small-scale Satellites
|-
|-
| [[British Aerospace]]
| [[British Aerospace]]
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| now part of [[EADS Astrium Satellites]]
| now part of [[EADS Astrium Satellites]]
|-
|-
| [[Dhruva Space]]<ref>{{cite web |url=http://dhruvaspace.com/ |title=Dhruva Space |access-date=26 September 2013 |url-status=dead |archive-url=https://web.archive.org/web/20130928035702/http://dhruvaspace.com/ |archive-date=28 September 2013 |df=dmy-all }}</ref>
| [[Dhruva Space]]<ref>{{cite web |url=http://dhruvaspace.com/ |title=Dhruva Space |access-date=26 September 2013 |url-status=dead |archive-url=https://web.archive.org/web/20130928035702/http://dhruvaspace.com/ |archive-date=28 September 2013 }}</ref>
| India
| India
|
|
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|
|
| Nano and Micro Satellites (1 to 50&nbsp;kg) for global tracking, Earth observation and science, communications, constellations, Internet-of-Things, defence and security, and deep-space missions.
| Nano and Micro Satellites (1 to 50&nbsp;kg) for global tracking, Earth observation and science, communications, constellations, Internet-of-Things, defence and security, and deep-space missions.
|-
|Hera Systems
|United States
|1
|Smart satellite bus provider. Spacecraft manufacturing and integration services, for small satellites (50–250&nbsp;kg).
|-
|-
| [[Hughes Aircraft]]
| [[Hughes Aircraft]]
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|Launching first satellite in Q2 2020
|Launching first satellite in Q2 2020
|-
|-
| Innovative Solutions In Space<ref>{{cite web |url=http://www.isispace.nl/ |title=ISIS |access-date=9 December 2013}}</ref>
| Innovative Solutions in Space<ref>{{cite web |url=http://www.isispace.nl/ |title=ISIS |access-date=9 December 2013}}</ref>
| Netherlands
| Netherlands
| 490
| 490
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| CubeSats, PocketQubes
| CubeSats, PocketQubes
|-
|-




| [[NPO Lavochkin]]
| [[NPO Lavochkin]]
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| [[OneWeb]]
| [[OneWeb]]
| United Kingdom
| United Kingdom
| 394<ref>{{Cite web|last=Clark|first=Stephen|title=OneWeb adds 36 more satellites to internet network – Spaceflight Now|url=https://spaceflightnow.com/2021/12/27/oneweb-adds-36-more-satellites-to-internet-network-2/|access-date=2022-01-30|language=en-US}}</ref>
| 640<ref>{{Cite web|title=OneWeb Launch Statistics|url=https://planet4589.org/space/con/ow/stats.html|access-date=2024-06-26}}</ref>
| [[OneWeb satellite constellation]]
| [[OneWeb satellite constellation]]
|-
|-
| [[Planet Labs]]
| [[Planet Labs]]
| United States
| United States
| ≥592<ref>{{Cite web|title=Planet Launch Statistics|url=https://planet4589.org/space/con/pln/stats.html|access-date=2024-06-26}}</ref>
| 298<ref name=tc20180914>{{cite news |url=https://techcrunch.com/2018/09/14/inside-planet-labs-new-satellite-manufacturing-site/ |title=Inside Planet Labs' new satellite manufacturing site |work=[[TechCrunch]] |date=2018-09-14 |access-date=2018-10-26}}</ref>
| Earth observation satellite constellation
| Earth observation satellite constellation
|-
|-
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| [[SpaceX]]
| [[SpaceX]]
| United States
| United States
| [[Starlink#Launches|1848]]<ref>{{Cite web|title=Jonathan's Space Report {{!}} Space Statistics|url=https://planet4589.org/space/stats/star/starstats.html|access-date=2022-01-30|website=planet4589.org}}</ref>
| [[List of Starlink and Starshield launches|6700]]<ref>{{Cite web|title=Jonathan's Space Report {{!}} Space Statistics|url=https://planet4589.org/space/con/star/stats.html|access-date=2024-06-26|website=planet4589.org}}</ref>
| largest commercial satellite constellation operator in the world with the [[Starlink]] constellation<ref>{{cite web |last1=Patel |first1=Neel |title=SpaceX now operates the world's biggest commercial satellite network |url=https://www.technologyreview.com/f/615016/spacex-now-operates-the-worlds-biggest-commercial-satellite-network/ |website=MIT Technology Review |access-date=9 January 2020}}</ref>
| largest commercial satellite constellation operator in the world with the [[Starlink]] constellation<ref>{{cite web |last1=Patel |first1=Neel |title=SpaceX now operates the world's biggest commercial satellite network |url=https://www.technologyreview.com/f/615016/spacex-now-operates-the-worlds-biggest-commercial-satellite-network/ |website=MIT Technology Review |access-date=9 January 2020}}</ref>
|-
|-
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| [[TRW Inc.|TRW]]
| [[TRW Inc.|TRW]]
| United States
| United States
| {{sort|199|nearly 200}} <ref>{{cite news |title = TRW Plays Key Role in Aerospace |url = http://articles.latimes.com/2002/feb/23/business/fi-trw23 |access-date = 3 Dec 2017}}</ref>
| {{sort|199|nearly 200}}<ref>{{cite news |title = TRW Plays Key Role in Aerospace |url = https://www.latimes.com/archives/la-xpm-2002-feb-23-fi-trw23-story.html |access-date = 3 December 2017}}</ref>
| now part of [[Northrop Grumman|Northrop Grumman Space Technology]]
| now part of [[Northrop Grumman|Northrop Grumman Space Technology]]
|-
|-
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| manufacturer of [[Bion-M]], [[Foton-M]], [[Resurs-P]] and [[Persona (satellite)|Persona]]
| manufacturer of [[Bion-M]], [[Foton-M]], [[Resurs-P]] and [[Persona (satellite)|Persona]]
|-
|-
| Xovian<ref>{{cite web |url = http://www.xovian.co.in/|title = Xovian|access-date = 26 December 2014}}</ref>
| Xovian<ref>{{cite web|url = http://www.xovian.co.in/|title = Xovian|access-date = 26 December 2014|archive-date = 20 March 2022|archive-url = https://web.archive.org/web/20220320032103/http://www.xovian.co.in/|url-status = dead}}</ref>
| India
| India
|
|
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|
|
|-
|-
| [[Iranian Space Agency]]<ref name="payvand1025">{{cite web |url=http://www.payvand.com/news/10/feb/1025.html |title=Iran unveils three new home-made satellites |access-date=26 September 2013}}</ref>
| [[Iranian Space Agency]]<ref name="payvand1025">{{cite web |url=http://www.payvand.com/news/10/feb/1025.html |title=Iran unveils three new home-made satellites |access-date=26 September 2013 |archive-date=6 February 2010 |archive-url=https://web.archive.org/web/20100206215559/http://www.payvand.com/news/10/feb/1025.html |url-status=dead }}</ref>
| Iran
| Iran
| 4/15
| 4/15
|
|
|-
|[https://www.innospc.com/main?lang=en&t=1711081650 INNOSPACE Co., Ltd.]
|Republic of Korea
|
|Successfully done Sub-Orbital Launch (HANBIT-TLV-Mar. 2023)
''Under Development (Hybrid Rocket)''
[https://www.innospc.com/page/sub01_01 HANBIT-Nano]

[https://www.innospc.com/page/sub01_02 HANBIT-Micro]

[https://www.innospc.com/page/sub01_03 HANBIT-Mini]
|-
|-
| [[ISC Kosmotras]]
| [[ISC Kosmotras]]
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|[[Rocket Lab]]
|[[Rocket Lab]]
| New Zealand/United States
| New Zealand/United States
| [[List of Electron rocket launches|20/23]]
| [[List of Electron rocket launches|46/50]]
| manufacturer of Electron launch vehicle
| manufacturer of Electron launch vehicle
|-
|[[Space One]]
|Japan
|
|manufacturer of the [[KAIROS (rocket)|KAIROS]] launch vehicle
|-
|-
| [[SpaceX]]
| [[SpaceX]]
| United States
| United States
| [[List of Falcon 9 and Falcon Heavy launches|{{#expr: {{Falcon rocket statistics|Totalsuccess}} + 2 }}/{{#expr: {{Falcon rocket statistics|Totallaunch}} + 5 }}]]<!-- Falcon 9 launches from template + 2/5 Falcon 1 launches-->
| [[List of Falcon 9 and Falcon Heavy launches|{{#expr: {{Falcon rocket statistics|Totalsuccess}} + 2 + 2 }}/{{#expr: {{Falcon rocket statistics|Totallaunch}} + 5 + 4}}]]<!-- Falcon 9 launches from template + 2/5 Falcon 1 launches + 2/4 Starship launches -->
| [[Falcon 1]], [[Falcon 9]] and [[Falcon Heavy]]
| [[Falcon 1]], [[Falcon 9]], [[Falcon Heavy]] and [[Starship]]
|-
|-
| [[Sea Launch]]
| [[Sea Launch]]
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| United States
| United States
|
|
| formerly known as Rocket Crafters, manufacturer of Dauntless<ref>{{Cite web|title=Florida rocket company rebrands, plans bigger rocket|url=https://www.upi.com/Science_News/2021/03/31/Rocket-Crafters-rebrands-Vaya-Space-Sid-Gutierrez/5591617132237/|access-date=2022-01-31|website=UPI|language=en}}</ref>
| formerly known as Rocket Crafters, manufacturer of Dauntless<ref>{{Cite web|title=Florida rocket company rebrands, plans bigger rocket|url=https://www.upi.com/Science_News/2021/03/31/Rocket-Crafters-rebrands-Vaya-Space-Sid-Gutierrez/5591617132237/|access-date=2022-01-31|website=UPI}}</ref>
|-
|-
| [[Start-1#History|United Start Launch]]
| [[Start-1#History|United Start Launch]]
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|[[Virgin Orbit]]
|[[Virgin Orbit]]
| United States / United Kingdom
| United States / United Kingdom
|[[LauncherOne|4/6]]
|[[LauncherOne|3/4]]<ref>{{Cite web|author1=Mike Wall|date=2022-01-14|title=Virgin Orbit sends 7 satellites to orbit in fourth mid-air launch|url=https://www.space.com/virgin-orbit-launches-seven-satellites-january-2022|access-date=2022-01-31|website=Space.com|language=en}}</ref>
| manufacturer of LauncherOne air-launched launch vehicle
| manufacturer of LauncherOne air-launched launch vehicle
|-
|-
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| [[Relativity Space]]
| [[Relativity Space]]
| United States
| United States
| 1?/1
| 0/1
| 95% 3D printed rocket
| 95% 3D printed rocket
|-
|-
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Commercial wings of national space agencies:
Commercial wings of national space agencies:
* [[Aerospace Industrial Development Corporation]] ([https://web.archive.org/web/20131004213834/http://www.aidc.com.tw/tw/index.asp AIDC]) and [https://web.archive.org/web/20131004213238/http://www.taia.org.tw/eng/ Taiwan Aerospace Industry Association] ([https://web.archive.org/web/20131004213238/http://www.taia.org.tw/eng/ TAIA]) Taiwan
* [[Aerospace Industrial Development Corporation]] ([https://web.archive.org/web/20131004213834/http://www.aidc.com.tw/tw/index.asp AIDC]) and [https://web.archive.org/web/20131004213238/http://www.taia.org.tw/eng/ Taiwan Aerospace Industry Association] ([https://web.archive.org/web/20131004213238/http://www.taia.org.tw/eng/ TAIA]) Taiwan
* [[Antrix Corporation]] India
* [[Antrix Corporation]] and [[NewSpace India Limited|NSIL]] India
*
* [[China Aerospace Science and Technology Corporation]] China
* [[China Aerospace Science and Technology Corporation]] China
*
*Aerockets


==Lander, rover and probe manufacturers==
==Lander, rover and probe manufacturers==
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| United States
| United States
|
|
| for ATHLETE lunar missions, Mars Pathfinder, Opportunity and Spirit rover
| for ATHLETE lunar missions, Mars Pathfinder, ''Opportunity'' and ''Spirit'' rover
|-
|-
| [[ISRO]]
| [[ISRO]]
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| Space Equipment mechanism expert, from design to MAIT (Manufacturing, Assembly, Integration, Test).
| Space Equipment mechanism expert, from design to MAIT (Manufacturing, Assembly, Integration, Test).
SmallSat off-the-shelf solutions including ADCS (reaction wheels range), SADM, deployable structure and electric propulsion (Plasma Jet Pack)
SmallSat off-the-shelf solutions including ADCS (reaction wheels range), SADM, deployable structure and electric propulsion (Plasma Jet Pack)
|COMAT’s reaction wheels and deployable antennas have been selected for use on the upcoming Kineis IoT constellation.
|COMAT's reaction wheels and deployable antennas have been selected for use on the upcoming Kineis IoT constellation.
|-
|-
| {{ill|Astro- und Feinwerktechnik Adlershof GmbH|de|Astro- und Feinwerktechnik}}
| {{ill|Astro- und Feinwerktechnik Adlershof GmbH|de|Astro- und Feinwerktechnik}}
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|[https://www.bradford-space.com/ Bradford Space]
|[https://www.bradford-space.com/ Bradford Space]
|New York, NY
|New York, NY
|Supplier of green propulsion systems, rocket engines, sun sensors, reaction wheels, acceleration measurement units, and astronaut workstations.
|Supplier of green propulsion systems, rocket engines, [[Sun sensor]]s, reaction wheels, acceleration measurement units, and astronaut workstations.
|Over 100 thrusters in-space
|Over 100 thrusters in-space
|-
|-
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| [[GomSpace]]
| [[GomSpace]]
| Denmark, Luxembourg, Sweden
| Denmark, Luxembourg, Sweden
| 1U to 16U platforms and structures, propulsion systems, software-defined radio, S-/X-/VHF band antennas, ADCS suite, electrical power systems, solar panels, on-board computers, ground equipment etc.
| 1U to 16U platforms and structures, propulsion systems, software-defined radio, S-/X-/VHF band antennas, ADCS suite, electrical power systems, solar panels, on-board computers, ground equipment etc.
|
|
|-
|-
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|{{ill|Jena-Optronik|de|Jena-Optronik}}<ref>{{cite web |url=http://productsandservices.bdli.de/#en/manufacturing-groups/aviation-and-aerospace-systems/J/jenaoptronik-gmbh | title=BDLI manufacturer for space |access-date=18 February 2014}}</ref>
|{{ill|Jena-Optronik|de|Jena-Optronik}}<ref>{{cite web |url=http://productsandservices.bdli.de/#en/manufacturing-groups/aviation-and-aerospace-systems/J/jenaoptronik-gmbh | title=BDLI manufacturer for space |access-date=18 February 2014}}</ref>
|Jena, Germany
|Jena, Germany
|Attitude and Orbit Control Systems (AOCS) sensors: star sensors, sun sensors, rendezvous- and docking sensors; Optical space instruments and components: multi-spectral imager (e.g. JSS 56 for RapidEye satellite constellation), efficient radiometer (e.g. METimage), electronic as well as opto-mechanical subsystems and components for operational Earth observation (e.g. for Copernicus Sentinel missions)
|Attitude and Orbit Control Systems (AOCS) sensors: star sensors, Sun sensors, rendezvous- and docking sensors; Optical space instruments and components: multi-spectral imager (e.g. JSS 56 for RapidEye satellite constellation), efficient radiometer (e.g. METimage), electronic as well as opto-mechanical subsystems and components for operational Earth observation (e.g. for Copernicus Sentinel missions)
|
|
|-
|-
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|-
|-
| Clyde Space
| Clyde Space
| [[Glasgow]], Scotland
| United Kingdom
| Power System Electronics, Batteries, Solar Panels, Attitude Control Systems
| Power System Electronics, Batteries, Solar Panels, Attitude Control Systems
| Acquired by ÅAC Microtec<ref>{{Cite news|url=https://www.bbc.com/news/uk-scotland-scotland-business-42459554|title=Satellite maker Clyde Space acquired by Swedish rival|work=BBC News|date=22 December 2017}}</ref>
| Acquired by ÅAC Microtec<ref>{{Cite news|url=https://www.bbc.com/news/uk-scotland-scotland-business-42459554|title=Satellite maker Clyde Space acquired by Swedish rival|publisher=BBC News|date=22 December 2017}}</ref>
|-
|-
| Astro Aerospace<ref>{{cite web |url=http://www.northropgrumman.com/astro |title=Astro Aerospace |access-date=4 June 2013}}</ref>
| Astro Aerospace<ref>{{cite web |url=http://www.northropgrumman.com/astro |title=Astro Aerospace |access-date=4 June 2013 }}{{Dead link|date=December 2023 |bot=InternetArchiveBot |fix-attempted=yes }}</ref>
| Carpinteria, CA United States
| Carpinteria, CA United States
| Deployable mechanisms, spacecraft structures, AstroMesh deployable reflector, deployable booms, large and small aperature mesh reflector antennas, STEM (Storable Tubular Extendable Member), hinge mechanisms,
| Deployable mechanisms, spacecraft structures, AstroMesh deployable reflector, deployable booms, large and small aperature mesh reflector antennas, STEM (Storable Tubular Extendable Member), hinge mechanisms,
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! Engine type
! Engine type
! Comments
! Comments
|-
|[[Dawn Aerospace]]
|Netherlands
|B20, B1, SatDrive, Cubedrive
|Bi-Propellant, Cold Gass
|Nitrous Oxide based, turnkey propulsion systems
|-
|-
|[[ArianeGroup]]
|[[ArianeGroup]]
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|hybrid Thrusters, Combined Liquid Electric Propulsion Systems, Methane/ Oxygen Ion Thrusters
|hybrid Thrusters, Combined Liquid Electric Propulsion Systems, Methane/ Oxygen Ion Thrusters
| Uses Electric and Liquid Propulsion simultaneously for space propulsion for LEO/MEOsatellites <ref>{{cite web |url= https://www.spacenewsbusiness.net/SNDE/42862f5ded502975ba753ddb80cb351c13cafa6f.pdf/ |title=SpaceNews August 2021 Newsletter |access-date=24 August 2021}}</ref>
| Uses Electric and Liquid Propulsion simultaneously for space propulsion for LEO/MEOsatellites<ref>{{cite web |url= https://www.spacenewsbusiness.net/SNDE/42862f5ded502975ba753ddb80cb351c13cafa6f.pdf/ |title= SpaceNews August 2021 Newsletter |access-date= 24 August 2021 |archive-date= 7 May 2023 |archive-url= https://web.archive.org/web/20230507141339/https://www.spacenewsbusiness.net/SNDE/42862f5ded502975ba753ddb80cb351c13cafa6f.pdf |url-status= dead }}</ref>
|-
|-


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|
|
|-
|-
|[[Hanwha Aerospace]]
|South Korea
|KRE-075, KRE-007 and Monopropellant Thrusters
|Bipropellant, Monopropellant and Motor
|Hanwha aerospace manufacturing liquid rocket engine for [[Nuri (rocket)|KSLV-II]] and monopropellant enginesd spacecraft ([[Danuri|Lunar Orbiter]], [[KOMPSAT]] series, etc.). The engines are co-developed with [[Korea Aerospace Research Institute|KARI]].
|-
|-
| [[American Rocket Company]]
| [[American Rocket Company]]
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| PUC, CHIPS, PPT-11
| PUC, CHIPS, PPT-11
| [[Atmospheric-pressure plasma|MCD]]<ref>{{cite book|url=https://arc.aiaa.org/doi/abs/10.2514/6.2010-6616|title=46th AIAA/ASME/SAE/ASEE Joint Propulsion Conference & Exhibit|first1=Mark de|last1=Chadenedes|first2=Drew|last2=Ahern|first3=Jin-Hoon|last3=Cho|first4=Sung-Jin|last4=Park|first5=J.|last5=Eden|first6=Rodney|last6=Burton|first7=Je Kwon|last7=Yoon|first8=Stephen|last8=Garrett|first9=Hariswaran|last9=Sitaraman|first10=Laxminarayan|last10=Raja|first11=Julia|last11=Laystrom-Woodard|first12=David|last12=Carroll|first13=Gabriel|last13=Benavides|chapter=Advances in Microcavity Discharge Thruster Technology|year=2010|publisher=American Institute of Aeronautics and Astronautics|access-date=11 August 2017|doi=10.2514/6.2010-6616|isbn=978-1-60086-958-7}}</ref> / [[Resistojet rocket|Resistojet]] / [[Pulsed plasma thruster|PPT]]<ref>{{cite book|url=http://arc.aiaa.org/doi/pdf/10.2514/6.2003-5025|title=Geometric Optimization of a Coaxial Pulsed Plasma Thruster|first1=Julia|last1=Laystrom|first2=Rodney|last2=Burton|first3=Gabriel|last3=Benavides|website=Arc.aiaa.org|year=2003|access-date=11 August 2017|doi=10.2514/6.2003-5025|isbn=978-1-62410-098-7}}</ref>
| [[Atmospheric-pressure plasma|MCD]]<ref>{{cite book|url=https://arc.aiaa.org/doi/abs/10.2514/6.2010-6616|title=46th AIAA/ASME/SAE/ASEE Joint Propulsion Conference & Exhibit|first1=Mark de|last1=Chadenedes|first2=Drew|last2=Ahern|first3=Jin-Hoon|last3=Cho|first4=Sung-Jin|last4=Park|first5=J.|last5=Eden|first6=Rodney|last6=Burton|first7=Je Kwon|last7=Yoon|first8=Stephen|last8=Garrett|first9=Hariswaran|last9=Sitaraman|first10=Laxminarayan|last10=Raja|first11=Julia|last11=Laystrom-Woodard|first12=David|last12=Carroll|first13=Gabriel|last13=Benavides|chapter=Advances in Microcavity Discharge Thruster Technology|year=2010|publisher=American Institute of Aeronautics and Astronautics|access-date=11 August 2017|doi=10.2514/6.2010-6616|isbn=978-1-60086-958-7}}</ref> / [[Resistojet rocket|Resistojet]] / [[Pulsed plasma thruster|PPT]]<ref>{{cite book|url=http://arc.aiaa.org/doi/pdf/10.2514/6.2003-5025|title=Geometric Optimization of a Coaxial Pulsed Plasma Thruster|first1=Julia|last1=Laystrom|first2=Rodney|last2=Burton|first3=Gabriel|last3=Benavides|website=Arc.aiaa.org|year=2003|access-date=11 August 2017|doi=10.2514/6.2003-5025|isbn=978-1-62410-098-7}}</ref>
| [[Small satellite]] / [[CubeSat]] Propulsion Modules <ref>{{cite web|url=http://www.cuaerospace.com/Products/SmallSatellitePropulsion.aspx|title=CU Aerospace - Small-Satellite Propulsion|date=10 August 2014|access-date=11 August 2017|url-status=bot: unknown|archive-url=https://web.archive.org/web/20140810141928/http://www.cuaerospace.com/Products/SmallSatellitePropulsion.aspx|archive-date=10 August 2014|df=dmy-all}}</ref>
| [[Small satellite]] / [[CubeSat]] Propulsion Modules<ref>{{cite web|url=http://www.cuaerospace.com/Products/SmallSatellitePropulsion.aspx|title=CU Aerospace Small-Satellite Propulsion|date=10 August 2014|access-date=11 August 2017|url-status=bot: unknown|archive-url=https://web.archive.org/web/20140810141928/http://www.cuaerospace.com/Products/SmallSatellitePropulsion.aspx|archive-date=10 August 2014}}</ref>
|-
|-
| VIPER
| VIPER
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|
|
| [[Liquid-propellant rocket|liquid rocket engine]]
| [[Liquid-propellant rocket|liquid rocket engine]]
| reusable rocket engine <ref>{{Cite web|url=https://www.popsci.com/scitech/article/2008-05/rocket-engine-masses|title = A Rocket Engine for the Masses|date = 18 March 2019}}</ref>
| reusable rocket engine<ref>{{Cite web|url=https://www.popsci.com/scitech/article/2008-05/rocket-engine-masses|title = A Rocket Engine for the Masses|date = 18 March 2019}}</ref>
|-
|-
| [[Ad Astra Rocket Company]]
| [[Ad Astra Rocket Company]]
Line 771: Line 807:
| [[Merlin (rocket engine family)|Merlin]] / [[Raptor (rocket engine family)|Raptor]] / [[Draco (rocket engine family)|Draco]] / [[Kestrel (rocket engine)|Kestrel]]
| [[Merlin (rocket engine family)|Merlin]] / [[Raptor (rocket engine family)|Raptor]] / [[Draco (rocket engine family)|Draco]] / [[Kestrel (rocket engine)|Kestrel]]
| [[Liquid-propellant rocket|liquid rocket engine]]
| [[Liquid-propellant rocket|liquid rocket engine]]
| used on [[Falcon (rocket family)|Falcon]] Rockets
| used on SpaceX rockets and spacecraft ([[Falcon (rocket family)|Falcon]], [[SpaceX Starship|Starship]], [[SpaceX Dragon|Dragon]])
|-
|-
| [[ArianeGroup]]
| [[ArianeGroup]]
Line 884: Line 920:
|France
|France
|NPT30, I2T5
|NPT30, I2T5
|[[Gridded ion thruster]],<ref>{{cite news |last1=Werner |first1=Debra |title=Spacety launches satellite to test ThrustMe iodine electric propulsion and constellation technologies |url=https://spacenews.com/thrustme-2020-demonstration/ |access-date=1 September 2021 |work=Space News |date=6 November 2020}}</ref><ref>{{cite web|language=en|author1=|title=French startup demonstrates iodine propulsion in potential boost for space debris mitigation efforts|url=https://spacenews.com/french-startup-demonstrates-iodine-propulsion-in-potential-boost-for-space-debris-mitigation-efforts/|website=Spacenews|date=2020-03-25|access-date=2021-07-26}}</ref> [[Cold gas thruster]]<ref>{{cite web|language=en|author1=|title=Iodine Impulse for Smallsats Demo'd On-Orbit by ThrustMe and Spacety|url=https://smallsatnews.com/2019/11/25/iodine-impulse-for-smallsats-demod-on-orbit-by-thrustme-and-spacety/|website=Smallsat News|date=2019-11-25|access-date=2021-07-26}}</ref>
|[[Gridded ion thruster]],<ref>{{cite news |last1=Werner |first1=Debra |title=Spacety launches satellite to test ThrustMe iodine electric propulsion and constellation technologies |url=https://spacenews.com/thrustme-2020-demonstration/ |access-date=1 September 2021 |work=Space News |date=6 November 2020}}</ref><ref>{{cite web|title=French startup demonstrates iodine propulsion in potential boost for space debris mitigation efforts|url=https://spacenews.com/french-startup-demonstrates-iodine-propulsion-in-potential-boost-for-space-debris-mitigation-efforts/|website=Spacenews|date=2020-03-25|access-date=2021-07-26}}</ref> [[Cold gas thruster]]<ref>{{cite web|title=Iodine Impulse for Smallsats Demo'd On-Orbit by ThrustMe and Spacety|url=https://smallsatnews.com/2019/11/25/iodine-impulse-for-smallsats-demod-on-orbit-by-thrustme-and-spacety/|website=Smallsat News|date=2019-11-25|access-date=2021-07-26}}</ref>
|first in-orbit demonstration of an [[Electrically powered spacecraft propulsion|electric propulsion system]] powered by iodine<ref>{{cite web|language=en|author1=|title=Iodine thruster could slow space junk accumulation|url=https://www.esa.int/Applications/Telecommunications_Integrated_Applications/Iodine_thruster_could_slow_space_junk_accumulation|website=esa.int|date=2021-01-22|access-date=2021-07-26}}</ref><ref>{{cite journal|language=en|title=In-orbit demonstration of an iodine electric propulsion system|journal=Nature|year=2021|doi=10.1038/s41586-021-04015-y|last1=Rafalskyi|first1=Dmytro|last2=Martínez|first2=Javier Martínez|last3=Habl|first3=Lui|last4=Zorzoli Rossi|first4=Elena|last5=Proynov|first5=Plamen|last6=Boré|first6=Antoine|last7=Baret|first7=Thomas|last8=Poyet|first8=Antoine|last9=Lafleur|first9=Trevor|last10=Dudin|first10=Stanislav|last11=Aanesland|first11=Ane|volume=599|issue=7885|pages=411–415|pmid=34789903|pmc=8599014|bibcode=2021Natur.599..411R|s2cid=244347528}}</ref>
|first in-orbit demonstration of an [[Electrically powered spacecraft propulsion|electric propulsion system]] powered by iodine<ref>{{cite web|title=Iodine thruster could slow space junk accumulation|url=https://www.esa.int/Applications/Telecommunications_Integrated_Applications/Iodine_thruster_could_slow_space_junk_accumulation|website=esa.int|date=2021-01-22|access-date=2021-07-26}}</ref><ref>{{cite journal|title=In-orbit demonstration of an iodine electric propulsion system|journal=Nature|year=2021|doi=10.1038/s41586-021-04015-y|last1=Rafalskyi|first1=Dmytro|last2=Martínez|first2=Javier Martínez|last3=Habl|first3=Lui|last4=Zorzoli Rossi|first4=Elena|last5=Proynov|first5=Plamen|last6=Boré|first6=Antoine|last7=Baret|first7=Thomas|last8=Poyet|first8=Antoine|last9=Lafleur|first9=Trevor|last10=Dudin|first10=Stanislav|last11=Aanesland|first11=Ane|volume=599|issue=7885|pages=411–415|pmid=34789903|pmc=8599014|bibcode=2021Natur.599..411R|s2cid=244347528}}</ref>
|}
|}


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[[Category:Spacecraft manufacturers|*]]
[[Category:Spacecraft manufacturers|*]]
[[Category:Space lists|spacecraft manufacturers]]
[[Category:Outer space lists|spacecraft manufacturers]]

Latest revision as of 03:33, 5 October 2024

History

[edit]

During the early years of spaceflight only nation states had the resources to develop and fly spacecraft. Both the U.S. space program and Soviet space program were operated using mainly military (ex Airforce) pilots as astronauts. During this period, no commercial space launches were available to private operators, and no private organization was able to offer space launches.

In the 1980s, the European Space Agency created Arianespace, the world's first commercial space transportation company, and, following the Challenger disaster, the American government deregulated the American space transportation market as well. In the 1990s the Russian government sold their majority stake in RSC Energia to private investors (although it has recently renationalized the Russian space sector in 2013–2014.[1]) These events for the first time allowed private organizations to purchase, develop and offer space launch services; beginning the period of private spaceflight in the late-1980s and early-1990s.

Satellite manufacturers

[edit]

There are 10 major companies that build large, commercial, Geosynchronous satellite platforms:

Company Location No of satellites launched Comments
Airbus Defence and Space Europe (France/Germany/Spain/United Kingdom) formerly Astrium
OHB SE Europe (Germany/Italy/Luxembourg/Sweden/France/Belgium)
Boeing Defense, Space & Security United States formerly Boeing Integrated Defense Systems
INVAP Argentina 6 INVAP is developing new satellites ARSAT-3 SAOCOM SABIA-Mar
JSC Information Satellite Systems Russia 1200[2] formerly NPO PM
Lockheed Martin Space United States
Northrop Grumman United States formerly Orbital ATK
Raytheon United States One of worlds largest space sensor providers.
Maxar Space United States 285[3][4] formerly Space Systems Loral, formally SSL, subsidiary of Maxar Technologies
Thales Alenia Space Europe (France/Italy/United Kingdom/Spain/Belgium/Germany/Poland) formerly Alcatel Alenia Space

In addition to those above, the following companies have successfully built and launched (smaller) satellite platforms:

Company Location No of satellites launched Comments
AeroAstro, Inc. United States Closed[5]
Argotec Italy CubeSats and Small Satellites
Astranis United States 1 Geostationary & Small-scale Satellites
British Aerospace United Kingdom purchased Marconi Electronic Systems, to form BAE Systems
CBERS Brazil China 5
EnduroSat Europe (Bulgaria) CubeSats and Nanosatellites
Fairchild Space and Electronics Division United States sold to Matra Marconi Space, then sold to Orbital Sciences Corporation
Fokker Space & Systems Netherlands then Dutch Space, now part of EADS Astrium Satellites
GAUSS Srl Italy 9 CubeSats and Small Satellites (<50 kg)
General Electric United States then merged into Martin Marietta, now part of Lockheed Martin
Hawker Siddeley Dynamics United Kingdom now part of EADS Astrium Satellites
Dhruva Space[6] India Nano Satellites (>8 to <35 kg)
GomSpace[7] Denmark, Luxembourg, Sweden Nano and Micro Satellites (1 to 50 kg) for global tracking, Earth observation and science, communications, constellations, Internet-of-Things, defence and security, and deep-space missions.
Hera Systems United States 1 Smart satellite bus provider. Spacecraft manufacturing and integration services, for small satellites (50–250 kg).
Hughes Aircraft United States purchased by Boeing
IHI Corporation Japan
In-Space Missions[8] United Kingdom Launching first satellite in Q2 2020
Innovative Solutions in Space[9] Netherlands 490 CubeSats
Libre Space Foundation[10] Greece 3 CubeSats, PocketQubes
NPO Lavochkin Russia
Mitsubishi Heavy Industries Japan
Northrop Grumman Space Technology United States
NanoAvionics United States 90 CubeSats and Small Sats
Pumpkin, Inc.[11] United States CubeSat Kit
OneWeb United Kingdom 640[12] OneWeb satellite constellation
Planet Labs United States ≥592[13] Earth observation satellite constellation
Philco Ford United States then Ford Aerospace, now Space Systems/Loral
QinetiQ Space N.V. Belgium 3 then Verhaert Space
Rockwell United States purchased by Boeing
RKK Energiya Russia produced Sputnik 1
Satrec Initiative Korea 5
SPAR Aerospace Canada 8 bought by MacDonald Dettwiler
Sierra Space United States formerly SpaceDev, owned by Sierra Space
SpaceX United States 6700[14] largest commercial satellite constellation operator in the world with the Starlink constellation[15]
Spectrum Astro United States bought by General Dynamics
Surrey Satellite Technology Ltd United Kingdom now part of Airbus Defence & Space
Swales Aerospace United States bought by Alliant Techsystems, now Orbital ATK
TRANSPACE Technologies[16] India On-Board Satellite Systems Fabrication, Testing and Reliability Analysis
TRW United States nearly 200[17] now part of Northrop Grumman Space Technology
TsSKB-Progress Russia manufacturer of Bion-M, Foton-M, Resurs-P and Persona
Xovian[18] India Nanosat and services
York Space Systems United States 1[19] Up to 250 kg spacecraft production and launch services[20]
Yuzhnoye Design Bureau Ukraine

Launch vehicle manufacturers and providers of third party services

[edit]
Company Location No. of successful launches Comments
Arianespace Europe (France/Germany/Italy/Belgium/Switzerland/Sweden/Spain/Netherlands/Norway/Denmark) 244/256 Ariane (rocket family)
Delft Aerospace Rocket Engineering Netherlands Suborbital student-built sounding rockets
ISRO India 65/72 PSLV, GSLV, LVM3, SSLV
COSMOS International Russia/Germany commercialises the Kosmos-3M launcher
Eurockot Launch Services Europe (Germany/France/United Kingdom/Spain/Netherlands/Russia) 29/31[21] owned by EADS Astrium
International Launch Services United States
Russia
97/100[when?][citation needed]
Iranian Space Agency[22] Iran 4/15
INNOSPACE Co., Ltd. Republic of Korea Successfully done Sub-Orbital Launch (HANBIT-TLV-Mar. 2023)

Under Development (Hybrid Rocket) HANBIT-Nano

HANBIT-Micro

HANBIT-Mini

ISC Kosmotras Russia/Ukraine/Kazakhstan
Mitsubishi Heavy Industries Japan 81/85
Northrop Grumman United States 81/90 manufacturer of Antares, Minotaur and Pegasus
PLD Space Spain manufacturer of Miura 1 and Miura 5
Rocket Lab New Zealand/United States 46/50 manufacturer of Electron launch vehicle
Space One Japan manufacturer of the KAIROS launch vehicle
SpaceX United States 422/430 Falcon 1, Falcon 9, Falcon Heavy and Starship
Sea Launch United States/Russia/Ukraine/Norway 32/36[when?][citation needed] provider of Sea Launch and Land Launch service
Makeyev Rocket Design Bureau Russia commercialises the Volna and Shtil' launchers
NPO Mashinostroyeniya Russia commercialises the Strela launcher
Starsem Europe (Germany/France/United Kingdom/Spain/Netherlands/Italy/Belgium/Switzerland/Sweden/Norway/Denmark/ and Russia) commercialises the Soyuz launcher
The Spaceship Company United States Reusable spaceship launched from the White Knight Aircraft for space tourism and zero-g experimentation
TsSKB-Progress Russia manufacturer of Soyuz launch vehicle
United Launch Alliance United States 147/148
Vaya Space United States formerly known as Rocket Crafters, manufacturer of Dauntless[23]
United Start Launch United States
Russia
commercialises the Start-1 launcher[24]
Virgin Galactic United States Space Tourism Using 'The Spaceship Company spacecraft
Virgin Orbit United States / United Kingdom 4/6 manufacturer of LauncherOne air-launched launch vehicle
Blue Origin United States manufacturer of the New Shepard suborbital rocket and New Glenn
Independence-X Aerospace Malaysia manufacturer of DNLV launch vehicle
Borneo SubOrbitals Malaysia manufacturer of unnamed suborbital rocket
Relativity Space United States 0/1 95% 3D printed rocket
Stoke Space United States Areospike 2nd stage engine

Commercial wings of national space agencies:

Lander, rover and probe manufacturers

[edit]
Company Location No. of probes launched Comments
Brown Engineering Company Huntsville, AL United States Rover for Apollo lunar program
China National Space Administration China for Chang'e 3 program in 2013
Deep Space Industries Mountain View, CA United States
Lavochkin Russia rovers for Lunokhod 1
NASA JPL United States for ATHLETE lunar missions, Mars Pathfinder, Opportunity and Spirit rover
ISRO India Chandrayaan-1, Chandrayaan-2, Mars Orbiter Mission
Planetary Resources Redmond, WA United States Arkyd-100 for asteroid searching

Spacecraft component manufacturers

[edit]
Company Location Production Notes
Orbital Machines AS Trondheim, Norway and Berlin, Germany Electric propellant pumps for launch vehicles and spacecraft
Comat Flourens, France Space Equipment mechanism expert, from design to MAIT (Manufacturing, Assembly, Integration, Test).

SmallSat off-the-shelf solutions including ADCS (reaction wheels range), SADM, deployable structure and electric propulsion (Plasma Jet Pack)

COMAT's reaction wheels and deployable antennas have been selected for use on the upcoming Kineis IoT constellation.
Astro- und Feinwerktechnik Adlershof GmbH [de] Berlin, Germany Design, Manufacturing, Assembly, Integration and Verification of small satellite buses (TET-1, launched July 2012) and components. Attitude control components (reaction wheels, gyro system, GPS receiver, magnetometer)

Supplier of space systems and ISS payload NightPod

Bradford Space New York, NY Supplier of green propulsion systems, rocket engines, Sun sensors, reaction wheels, acceleration measurement units, and astronaut workstations. Over 100 thrusters in-space
Dynetics Madison, AL United States used on Sundancer and Ares I
Tethers Unlimited, Inc. Seattle, WA United States De-Orbiting Devices, Deployable Solar Arrays, Propulsion Systems, Radio Communications, and Robotics
RUAG Space Switzerland Structures, Fairings, Mechanisms, Opto-Electronics
AB 360 Space United States manufacturer of CLEPS-C100 Combined electric Propulsion systems, Adjustable Thruster Engines for Mars travel
GAUSS Srl Rome, Italy Complete Space Platforms, Nanosatellites Structures and Deployers, OBDH, EPS, Radio Communications, Solar Panels and Groundstation systems
GomSpace Denmark, Luxembourg, Sweden 1U to 16U platforms and structures, propulsion systems, software-defined radio, S-/X-/VHF band antennas, ADCS suite, electrical power systems, solar panels, on-board computers, ground equipment etc.
Andrews Space Seattle, WA United States
Jena-Optronik [de][25] Jena, Germany Attitude and Orbit Control Systems (AOCS) sensors: star sensors, Sun sensors, rendezvous- and docking sensors; Optical space instruments and components: multi-spectral imager (e.g. JSS 56 for RapidEye satellite constellation), efficient radiometer (e.g. METimage), electronic as well as opto-mechanical subsystems and components for operational Earth observation (e.g. for Copernicus Sentinel missions)
Pumpkin, Inc San Francisco, CA United States CubeSat Kits[26]
Mynaric Munich Germany Laser communication equipment for airborne and spaceborne communication networks, so called constellations.
Kongsberg Defence & Aerospace[27] Kongsberg Norway Kongsberg Adaptive Rotational Mechanism Assembly [KARMA] in configuration as Solar Array Drive Mechanism (SADM), used on Rosetta (spacecraft), Mars Express, Venus Express, Sentinel 1, Sentinel 3 and BepiColombo MTM.

Drive electronics for Sentinel 1 and BepiColombo MTM. Booster attachment struts, including separation function, for Ariane 5.

Production Corporation Polyot Russia
Rocketstar Robotics Inc[28] Camarillo, CA United States Space Interferometry Mission Optical Shutter Mechanisms
Sierra Space United States formerly SpaceDev, owned by Sierra Space
Clyde Space Glasgow, Scotland Power System Electronics, Batteries, Solar Panels, Attitude Control Systems Acquired by ÅAC Microtec[29]
Astro Aerospace[30] Carpinteria, CA United States Deployable mechanisms, spacecraft structures, AstroMesh deployable reflector, deployable booms, large and small aperature mesh reflector antennas, STEM (Storable Tubular Extendable Member), hinge mechanisms, A special business unit of Northrop Grumman
TRANSPACE Technologies[31] Bangalore, KA India On-Board Satellite Sub-Systems Fabrication, Testing, Reliability Analysis and PCB Design Approved Vendor for ISRO Satellite Center, India
RadioBro Corporation[32] Huntsville, Alabama United States Small Spacecraft Communications, Flight Readiness Testing, Training Services[33]
Howco Additive Manufacturing[34] Houston, Texas, United States 3D Printing Aerospace Components in In718 and Titanium
Solar MEMS Technologies[35] Spain Sun Sensors for Satellites[36]
krypton technology solutions United States Small Spacecraft components, on-orbit servicing,1U to 24U spacecraft buses
CisLunar Industries United States Power supplies for electric propulsion systems and space hardware

Propulsion manufacturers

[edit]
Company name Country Engine Engine type Comments
Dawn Aerospace Netherlands B20, B1, SatDrive, Cubedrive Bi-Propellant, Cold Gass Nitrous Oxide based, turnkey propulsion systems
ArianeGroup Lampoldshausen, Germany S10, S20, S200, S400

CHT-1N, CHT-20N, CHT-400N

RIT-10, RIT-2x

propellant and Monopropellant Thrusters, Gridded Ion Thrusters Main manufacturer for Propulsion Systems, Equipments and Services in Europe, serving major space projects like ATV, ORION-ESM, ExoMars, JUICE, MTG, GEO and EO satellites with Propulsion Solutions.
Comat Flourens, France Plasma Jet Pack Vacuum Arc thruster ; Modular installation (PPSU + Nozzles) To be used on @Isispace and @U-space platforms for French and European missions.

Modular Thruster with up to 4 nozzles per PPSCU.

AB 360 Space Washington DC, United States CLEPS X-100, CLEPS C100 hybrid Thrusters, Combined Liquid Electric Propulsion Systems, Methane/ Oxygen Ion Thrusters Uses Electric and Liquid Propulsion simultaneously for space propulsion for LEO/MEOsatellites[37]
Moog-ISP (In Space Propulsion) Westcott, Buckinghamshire United Kingdom

Niagara Falls, NY United States

All Forms of Chemical Propulsion including Main Apogee Engines and AOCS Thrusters Bipropellant and Monopropellant Product Families Include: LEROS, MONARC Thruster, LTT Thruster Division of Moog Inc.
Bradford Space New York, NY LMP-103s thrusters,

Water based thrusters

LMP-103s green monopropellant propulsion systems & thrusters,

COMET water based propulsion systems

>100 thrusters on flight satellites
Busek Natick, Massachusetts United States BHT-200, BHT-1500, BHT-20k, BET-1, BmP-220, BIT-1, BIT-3, BIT-7, uPPT-3 Hall-effect thruster, Gridded Ion, Electrospray, micro Pulsed Plasma, Green Monopropellant, Electrothermal, Hollow Cathodes, Field Emission Cathode TacSat-2, FalconSat-5, FalconSat-6, ST-7/LISA Pathfinder. Licensed technology for BPT-4000 aboard AEHF 1, AEHF 2, AEHF 3. Propulsion options ranging from CubeSats to GEO Communications Satellites to Asteroid Redirect Mission Spacecraft.[38]
Aerojet Rocketdyne Rancho Cordova, California United States Numerous liquid rocket engine, Solid rocket engine, Hall-effect thruster, Gridded Ion thruster.
Hanwha Aerospace South Korea KRE-075, KRE-007 and Monopropellant Thrusters Bipropellant, Monopropellant and Motor Hanwha aerospace manufacturing liquid rocket engine for KSLV-II and monopropellant enginesd spacecraft (Lunar Orbiter, KOMPSAT series, etc.). The engines are co-developed with KARI.
American Rocket Company United States hybrid rocket intellectual property acquired by SpaceDev
CU Aerospace Champaign, IL United States PUC, CHIPS, PPT-11 MCD[39] / Resistojet / PPT[40] Small satellite / CubeSat Propulsion Modules[41]
VIPER liquid rocket engine reusable rocket engine[42]
Ad Astra Rocket Company Webster, TX United States VASIMR magnetoplasma may be used for future Mars missions
Enpulsion GmbH Wiener Neustadt, Austria Propulsion Systems for Cubesats, Small Sats, and Medium/Large Satellites Field Emission Electric Propulsion Enpulsion is commercializing a technology that has been developed for ESA science missions for more than 10 years.[43]
PLD Space Spain TREPEL family used on Miura Rockets
Reaction Engines Ltd. Oxfordshire, England United Kingdom SABRE combined cycle precooled jet engine and closed cycle rocket engine planned to be used in Skylon
LIA Aerospace Ltd. England United Kingdom KX11 Pressure Fed, bipropellant, green, non-toxic, storable regen cooled used in Zonda 1.0
Sierra Space United States VR35K-A[44] hybrid rocket, liquid rocket engine[45] Commercial space subsidiary of Sierra Nevada Corporation
SpaceDev Poway, CA United States hybrid rocket acquired by Sierra Space; used on SpaceShipOne and SpaceShipTwo
SpaceX Hawthorne, California, United States Merlin / Raptor / Draco / Kestrel liquid rocket engine used on SpaceX rockets and spacecraft (Falcon, Starship, Dragon)
ArianeGroup Vernon, France Vinci / Viking / Vulcain / HM7B liquid rocket engine used on Ariane rockets
NPO Energomash Russia liquid rocket engine used on R-7, Molniya, Soyuz, Energia, Zenit, Atlas III, Atlas V, Angara, Antares
KBKhA Russia liquid rocket engine used on Soyuz, Proton, Energia
KBKhM Russia liquid rocket engine used on Vostok, Voskhod, Zenit, Soyuz, Progress, Salyut 1, Salyut 4, Salyut 6, Salyut 7, Mir Core Module, Zvezda, GSLV Mk I
NIIMash Russia liquid rocket engine used on Almaz, Buran, Briz-M
TsNIIMash Russia used on STEX
Kuznetsov Design Bureau Russia liquid rocket engine used on N1, Soyuz-2-1v, Antares
OKB Fakel Russia Hall-effect thruster used on SMART-1, LS-1300
Proton-PM Russia liquid rocket engine used on Proton, Angara
Keldysh Research Center Russia
Voronezh Mechanical Plant Russia liquid rocket engine used on Vostok, Voskhod, Molniya, Soyuz, Proton, Energia, Luna
Yuzhnoye Design Office / Yuzhmash Ukraine used on
Independence-X Aerospace Malaysia ID-1, ID-2, ID-3 and unnamed 2-stage rocket engine for DNLV solid rocket motor and liquid rocket engine used on ID-1, ID-2 and DNLV rocket
Borneo SubOrbitals Malaysia hybrid rocket used on yet-to-be-named rocket
Apollo Fusion United States ACE, ACE Max Hall-effect thruster To be used on Spaceflight, Inc.'s Sherpa-LTE space tug[46]
Benchmark Space Systems United States Starling, Halcyon, Peregrine Warm gas thruster, High-test peroxide thruster, Hypergolic thruster To be used on Spaceflight, Inc.'s Sherpa-LTC space tug[46]
ThrustMe France NPT30, I2T5 Gridded ion thruster,[47][48] Cold gas thruster[49] first in-orbit demonstration of an electric propulsion system powered by iodine[50][51]

See also

[edit]

References

[edit]
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  2. ^ "Company overview". iss-reshetnev.com. Retrieved 30 January 2022.
  3. ^ "About Us". maxar.com. Retrieved 30 January 2022.
  4. ^ Cook, Kevin. "Bull of the Day: Maxar Technologies (MAXR)". Entrepreneur. Archived from the original on 31 January 2022. Retrieved 30 January 2022.
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  7. ^ "GomSpace". Retrieved 8 October 2021.
  8. ^ "In-Space". Retrieved 20 May 2020.
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  10. ^ "Libre Space Foundation". Retrieved 6 April 2022.
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  24. ^ "Archived copy". unitedstartlaunch.com. Archived from the original on 11 January 2016. Retrieved 12 January 2022.{{cite web}}: CS1 maint: archived copy as title (link)
  25. ^ "BDLI manufacturer for space". Retrieved 18 February 2014.
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  27. ^ "Kongsberg Gruppen". Retrieved 26 September 2013.
  28. ^ "Rocketstar Robotics". Retrieved 26 September 2013.
  29. ^ "Satellite maker Clyde Space acquired by Swedish rival". BBC News. 22 December 2017.
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  31. ^ "TRANSPACE". Retrieved 18 August 2014.
  32. ^ "RadioBro". Retrieved 15 September 2014.
  33. ^ "RadioBro entrepreneurs prep for launch of Cyclone flight test system". 9 August 2016.
  34. ^ "HowcoAM". Retrieved 10 October 2021.
  35. ^ "SolarMEMS". Retrieved 1 September 2016.
  36. ^ "Archived copy". Archived from the original on 4 March 2017. Retrieved 16 March 2018.{{cite web}}: CS1 maint: archived copy as title (link)
  37. ^ "SpaceNews August 2021 Newsletter" (PDF). Archived from the original on 7 May 2023. Retrieved 24 August 2021.
  38. ^ "Busek Home Page". Busek.com. Retrieved 11 August 2017.
  39. ^ Chadenedes, Mark de; Ahern, Drew; Cho, Jin-Hoon; Park, Sung-Jin; Eden, J.; Burton, Rodney; Yoon, Je Kwon; Garrett, Stephen; Sitaraman, Hariswaran; Raja, Laxminarayan; Laystrom-Woodard, Julia; Carroll, David; Benavides, Gabriel (2010). "Advances in Microcavity Discharge Thruster Technology". 46th AIAA/ASME/SAE/ASEE Joint Propulsion Conference & Exhibit. American Institute of Aeronautics and Astronautics. doi:10.2514/6.2010-6616. ISBN 978-1-60086-958-7. Retrieved 11 August 2017.
  40. ^ Laystrom, Julia; Burton, Rodney; Benavides, Gabriel (2003). Geometric Optimization of a Coaxial Pulsed Plasma Thruster. doi:10.2514/6.2003-5025. ISBN 978-1-62410-098-7. Retrieved 11 August 2017. {{cite book}}: |website= ignored (help)
  41. ^ "CU Aerospace – Small-Satellite Propulsion". 10 August 2014. Archived from the original on 10 August 2014. Retrieved 11 August 2017.{{cite web}}: CS1 maint: bot: original URL status unknown (link)
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