H-II Transfer Vehicle

H-II Transfer Vehicle
Description
Role: Automated cargo spacecraft to resupply the International Space Station
Crew: None
Dimensions
Height: ~9.8 m (including thrusters)[1]
Diameter: 4.4 m[1]
Spacecraft Mass: 10,500 kg[1]
Total Launch Payload: 6,000 kg[2] / 6,200 kg[3]
Pressurized Payload: 5,200 kg[2]
Unpressurized Payload: 1,500 kg[2]
Return Payload: None[4]
Mass at launch: 16.5 ton[2]
Pressurized Volume: 14 m3[5]
Performance
Endurance: Solo flight about 100 hours, stand-by more than a week, docked with the ISS about 30 days[1]
Apogee: 460 km[1]
Perigee: 350 km[1]
Inclination: 51.6 degrees[1]

The H-II Transfer Vehicle (HTV), also called Kounotori (こうのとり Kōnotori, "Oriental stork" or "white stork"), is an automated cargo spacecraft used to resupply the Kibō Japanese Experiment Module (JEM) and the International Space Station (ISS). The Japan Aerospace Exploration Agency (JAXA) has been working on the design since the early 1990s. The first mission, HTV-1, was originally intended to be launched in 2001. It launched at 17:01 UTC on 10 September 2009 on an H-IIB launch vehicle.[6] The name Kounotori was chosen for the HTV by JAXA because "a white stork carries an image of conveying an important thing (a baby, happiness, and other joyful things), therefore, it precisely expresses the HTV's mission to transport essential materials to the ISS".[7] It is the vehicle of choice to complete the ACES program, a project designed to put two atomic clocks in space—on the ISS.

Design

Structure
Inside view of the Pressurised Logistics Carrier section of HTV-1.
Canadarm2 removing unpressurised payload from HTV-2.

The HTV is about 9.8 m long (including maneuvering thrusters at one end) and 4.4 m in diameter. Total mass is 10.5 tonnes, with a 6,000 kilograms (13,000 lb) payload.[1] The HTV are comparable in function to the Russian Progress, European ATV, commercial Dragon, and commercial Cygnus spacecraft, all of which bring or are planned to bring supplies to the ISS. Like the ATV, the HTV carries more than twice the payload of the Progress, but is launched less than half as often. Unlike Progress capsules and ATVs, which dock automatically, HTVs and American commercial spacecraft approach the ISS in stages, and are signaled by ISS crew or ground control to continue from one holding point to the next. Once they reach their closest parking orbit to the ISS, crew grapple them using the robotic arm Canadarm2 and berth them to an open berthing port on the Harmony module.[8]

The HTV has an external payload bay which is accessed by robotic arm after it has been berthed to the ISS. New payloads can be moved directly from the HTV to Kibō's exposed facility. Internally, it has eight International Standard Payload Racks (ISPRs) in total which can be unloaded by the crew in a shirt-sleeve environment. After the retirement of NASA's Space Shuttle in 2011, HTVs became the only spacecraft capable of transporting ISPRs to the ISS. (The SpaceX Dragon and Orbital Sciences Cygnus can carry resupply cargo bags but not ISPRs.)

The four main thrusters. Smaller attitude control thrusters can be seen at the right side of this view of HTV-1.

The intention of HTV's modularized design was to use different module configuration to match the mission requirement.[9] However, to reduce the development cost it was decided to fly the mixed PLC/ULC configuration only.

To control the HTV's attitude and to perform the orbital maneuvers such as rendezvous and re-entry, the craft has four 500 N class main thrusters and twenty-eight 110 N class attitude control thrusters. Both use bipropellant, namely monomethylhydrazine (MMH) as fuel and mixed oxides of nitrogen (MON3) as oxidizer.[10] HTV-1, -2, and -4 use Aerojet's 110 N R-1E, Space Shuttle's vernier engine, and the 500 N based on the Apollo spacecraft's R-4D.[10] Later HTVs use 500 N class HBT-5 thrusters and 120 N class HBT-1 thrusters made by Japanese manufacturer IHI Aerospace Co., Ltd.[11] The HTV carries about 2400 kg of propellant in four tanks.[10]

After the unloading process is completed, the HTV will be loaded with waste and undocked. The vehicle will then deorbit and be destroyed during reentry, the debris falling into the Pacific Ocean.[4]

Flights

HTV-2 departing Tanegashima spaceport bound for the International space station

Initially seven missions were planned in 2008-2015. With the extension of ISS project after 2015 through 2020, three more missions are planned, possibly replacing the tenth flight with an improved, cost-reduced version (HTV-X).[12]

The first vehicle was launched on an H-IIB rocket, a more powerful version of the earlier H-IIA, at 17:01 GMT on 10 September 2009, from Launch Pad 2 of the Yoshinobu Launch Complex at the Tanegashima Space Center.[13]

As of March 2015, five subsequent missions are planned—one each year for 2015–2019[14] —one fewer total mission than had been planned in August 2013 at the time the fourth HTV mission was underway.[15]

HTV Launch date/time (UTC) Berth date/time (UTC)[16] Carrier rocket Re-entry date/time
HTV-1 10 September 2009, 17:01:56 17 September 2009, 22:12 H-IIB F1 1 November 2009, 21:26[17]
HTV-2 22 January 2011, 05:37:57 27 January 2011, 14:51 H-IIB F2 30 March 2011, 03:09[18]
HTV-3 21 July 2012, 02:06:18 27 July 2012, 14:34 H-IIB F3 14 September 2012, 05:27
HTV-4 3 August 2013, 19:48:46 9 August 2013, 15:38 H-IIB F4[19] 7 September 2013, 06:37[20]
HTV-5 19 August 2015, 11:50:49 24 August 2015, 17:28 [21] H-IIB F5 29 September 2015, 20:33[22]
HTV-6 9 December 2016 H-IIB
HTV-7 2017[14] H-IIB
HTV-8 2018[14] H-IIB
HTV-9 2019[14] H-IIB

Planned successor

HTV-X

In May 2015, Ministry of Education, Culture, Sports, Science and Technology announced a proposal to replace HTV with an improved, cost-reduced version preliminary called HTV-X.[12][23]

Proposed concept of HTV-X as of July 2015 is:[24]

Re-using the PLC will allow minimizing the development cost and risk. Concentrating the Reaction Control System (RCS) and the solar panels to Service Module will allow simplifying the wiring and piping, to reduce the weight and the manufacturing cost. Loading the unpressurized cargo outside the spacecraft allows larger cargo, only limited by the launch vehicle fairing. The aim is to cut the cost in half, while keeping or extending the capability of existing HTV.[24]

The simplification of overall structure will allow the launch mass of HTV-X to be dropped to 15.5 t (planned) from HTV's 16.5 t, while the maximum weight of cargo will be increased to 7.2 t (net weight 5.85 t excluding support structure weight) from HTV's 6.0 t (net 4.0 t).[25]

In December 2015, the plan to develop HTV-X was approved by the Strategic Headquarters for Space Policy of the Cabinet Office, targeting fiscal year 2021 for the flight of HTV-X1 (Technical Demonstration Vehicle) to be launched by H3 rocket.[26][25]

With the agreement of Japan-US Open Platform Partnership Program (JP-US OP3) in December 2015 to extend the cooperation of ISS operation through 2024, Japan will provide its share of ISS operation costs with the form of transportation by HTV-X, and also a possibility to develop a small return capsule.[27]

Former evolutionary proposals

HTV-R

As of 2010, JAXA was planning to add a return capsule option. In this concept, HTV's pressurized cargo would be replaced by a reentry module capable of returning 1.6 tonnes (1.8 tons) cargo from ISS to Earth.[28][29]

Further, conceptual plans in 2012 included a follow-on spacecraft design by 2022 which would accommodate a crew of three and carry up to 400 kilograms (880 lb) of cargo.[30]

Lagrange outpost resupply

As of 2014, both JAXA and Mitsubishi conducted studies of a next generation HTV as a possible Japanese contribution to the proposed international manned outpost at Earth-Moon L2.[31][32] This variant of HTV was to be launched by H-X Heavy and can carry 1.8 tons of supplies to EML2.[31] Modifications from the current HTV includes the addition of solar electric paddles and extension of the propellant tank.[31]

Manned variant

A proposal announced in June 2008 suggested combining HTV's propulsion module with a manned capsule for four people.[33]

Japanese Space Station

There is also a proposal to build a Japanese Space Station by using the HTV as a basis.[34] This method is similar to how the modules in Mir, as well as many modules of the Russian Orbital Segment of the ISS are based on the TKS cargo vehicle design.

See also

References

  1. 1 2 3 4 5 6 7 8 "H-II Transfer Vehicle "KOUNOTORI" (HTV)". Japan Aerospace Exploration Agency. 2007. Retrieved 2010-11-11.
  2. 1 2 3 4 Overview of the "KOUNOTORI". Japan Aerospace Exploration Agency. Retrieved 2011-01-18.
  3. 「こうのとり」(HTV)5号機の搭載物変更について (PDF). 31 July 2015. Retrieved 17 December 2015.
  4. 1 2 JAXA (2007). "HTV Operations". Retrieved 2011-01-02.
  5. "JAXA H-II Transfer Vehicle (HTV)" (PDF). NASA. Retrieved 8 December 2013.
  6. "NASA Sets Briefing, TV Coverage of Japan's First Cargo Spacecraft". NASA. Retrieved 2009-09-03.
  7. ""KOUNOTORI" Chosen as Nickname of the H-II Transfer Vehicle (HTV)". JAXA. 11 November 2010. Retrieved 11 November 2010.
  8. http://www.aprsaf.org/data/aprsaf17_data/DAY1-seu_0950-Kibo_Utilization_Status.pdf Archived March 17, 2012, at the Wayback Machine.
  9. Miki, Yoichiro; Abe, Naohiko; Matsuyama, Koichi; Masuda, Kazumi; Fukuda, Nobuhiko; Sasaki, Hiroshi (March 2010). "Development of the H-II Transfer Vehicle (HTV)" (PDF). Mitsubishi Heavy Industries Technical Review. Mitsubishi Heavy Industries. 47 (1).
  10. 1 2 3 IAC paper IAC-05-C4.1.03 - Shinobu Matsuo and al. "The design characteristics of the HTV propulsion module"
  11. "宇宙ステーション補給機「こうのとり」3号機(HTV3)ミッションプレスキット" (PDF) (in Japanese). June 20, 2012. Retrieved June 24, 2012.
  12. 1 2 Research and Development Division, Ministry of Education, Culture, Sports, Science and Technology (May 20, 2015). 2016年~2020年のISS共通システム運用経費(次期CSOC)の我が国の負担方法の在り方について (PDF). Retrieved June 4, 2015.
  13. Launch of the H-IIB Launch Vehicle Test Flight, JAXA Press release, 8 July 2009 (JST)
  14. 1 2 3 4 "International Space Station Flight Schedule". SEDS. 2015-03-13. Retrieved 15 March 2015.
  15. "International Space Station Flight Schedule". SEDS. 15 May 2013. Retrieved 9 August 2013.
  16. "H-II Transfer Vehicle "KOUNOTORI" (HTV) Topics". Japan Aerospace Exploration Agency.
  17. Stephen Clark (1 November 2009). "History-making Japanese space mission ends in flames". Spaceflight Now. Retrieved 13 November 2010.
  18. Stephen Clark (29 March 2011). "Japan's HTV cargo freighter proves useful to the end". Spaceflight Now. Retrieved 21 April 2011.
  19. Stephen Clark (3 August 2013). "Japan launches resupply mission to space station". Spaceflight Now. Retrieved 3 August 2013.
  20. Stephen Clark (9 August 2013). "JJapan's cargo craft makes in-orbit delivery to space station". Spaceflight Now. Retrieved 9 August 2013.
  21. "Successful berthing of the H-II Transfer Vehicle KOUNOTORI5 (HTV5) to the International Space Station (ISS)".
  22. "Successful re-entry of H-II Transfer Vehicle "KOUNOTORI5" (HTV5)". JAXA. September 30, 2015. Retrieved September 30, 2015.
  23. "国際宇宙ステーション計画を含む有人計画について" (PDF) (in Japanese). June 3, 2015. Retrieved July 13, 2015.
  24. 1 2 HTV-X(仮称)の開発(案)について (PDF) (in Japanese). July 2, 2015. Retrieved July 17, 2015.
  25. 1 2 JAXA (14 July 2016). HTV‐Xの開発状況について (PDF) (in Japanese). Retrieved 18 July 2016.
  26. Strategic Headquarters for Space Policy (8 December 2015). 宇宙基本計画工程表(平成27年度改訂) (PDF) (in Japanese). Retrieved 18 July 2016.
  27. "Japan - United States Space Cooperation and the International Space Station Program" (PDF). Ministry of Education, Culture, Sports, Science, and Technology. 22 December 2015. Retrieved 25 July 2016.
  28. "回収機能付加型宇宙ステーション補給機(HTV-R)検討状況" (in Japanese). JAXA. August 11, 2010. Retrieved September 7, 2011.
  29. "回収機能付加型HTV(HTV-R)" (in Japanese). JAXA. Archived from the original on August 26, 2011. Retrieved September 7, 2011.
  30. Rob Coppinger. "Japan Wants Space Plane or Capsule by 2022". Space.com. Retrieved October 25, 2012.
  31. 1 2 3 "International Human Lunar Mission Architecture / System and its Technologies" (PDF). JAXA. 2014-04-10. Retrieved 22 January 2015.
  32. "An International Industry Perspective on Extended Duration Missions Near the Moon" (PDF). Lockheed Martin Corporation. 2014-04-10. Retrieved 22 January 2015.
  33. Takane Imada, Michio Ito, Shinichi Takata (June 2008). "Preliminary Study for Manned Spacecraft with Escape System and H-IIB Rocket" (PDF). 26th ISTS. Retrieved 2010-12-25.
  34. Sasaki, Hiroshi; Imada, Takane; Takata, Shinichi (2008). "Development Plan for Future Mission from HTV System" (PDF). JAXA. Retrieved 2016-07-19.
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