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Progress MS
Прогресс МС
Progress MS-11 approaching the ISS
ManufacturerEnergia
Country of originRussia
OperatorRoscosmos
ApplicationsISS resupply
Specifications
Spacecraft typeCargo
Launch mass7,290 kg (16,070 lb)
Payload capacity
  • Total: 2,600 kg (5,700 lb)
  •      Dry cargo: 1,800 kg (4,000 lb)
  •      Propellant: 870 kg (1,920 lb)
  •      Water: 420 kg (930 lb)
  •      Gases: 50 kg (110 lb)
  • Disposal: 2,140 kg (4,720 lb)
Volume7 m (250 cu ft)
RegimeLow Earth orbit
Design life180 days docked to a space station
Production
StatusActive
On order8
Built29
Launched29 (as of 11 September 2024)
Operational2 (MS-28, MS-29)
Retired26
Lost1 (MS‑04)
Maiden launch21 December 2015 (MS-01)
Last launchActive
Related spacecraft
Derived fromProgress M
Flown withSoyuz-2.1a (2015–)
Soyuz-U (2016–2017)
Soyuz-FG (2018–2019)

The Progress MS (Russian: Прогресс МС; GRAU: 11F615A61) is the latest version of the Russian Progress spacecraft series, first launched in 2015. The "MS" stands for "modernized systems," reflecting upgrades primarily focused on the communications and navigation subsystems. An evolution of the Progress M spacecraft, the Soyuz MS features minimal external changes, mainly in the placement of antennas, sensors, and thrusters. It is used by Roscosmos for cargo spaceflight missions. Progress MS-01 conducted its maiden flight on 21 December 2015, heading to the International Space Station (ISS).

Design

Like all previous variants, the Progress MS spacecraft consists of three distinct sections:

  • Cargo Section: This pressurized carries supplies for the crew, including maintenance items, prepackaged and fresh food, scientific equipment, and clothing. Its docking drogue, similar to that of the Soyuz, features ducting that enables fuel transfer (described below).
  • Tanker Section: Replacing the Soyuz’s reentry module, this unpressurized compartment houses two tanks containing unsymmetrical dimethylhydrazine (UDMH) fuel and dinitrogen tetroxide (N2O4) oxidizer. Ducts run from these tanks around the outside of the pressurized module to connectors at the docking port, allowing automated fuel transfer. This design prevents any potential leaks of the toxic propellant from contaminating the station's atmosphere. This section also contains water tanks.
  • Propulsion Section: Located at the rear of the spacecraft, this unpressurized compartment remains largely unchanged from the Soyuz design. It contains the orientation engines used for automatic docking and can be utilized to boost the station's orbit once docked.

The Progress spacecraft’s uncrewed and disposable design enables significant weight reduction. Unlike Soyuz, it does not require life support systems, heat shields, parachutes, or automatic crew rescue systems. Additionally, it lacks the ability to separate into multiple modules. after completing its mission, the spacecraft undocks, performs a controlled retrofire, and burns up upon reentry into Earth's atmosphere.

Technical specifications
  • Launch mass: 7,290 kilograms (16,070 lb)
  • Total payload capacity at launch: 2,600 kilograms (5,700 lb) – the following amounts exceed this capacity, giving planners the ability to match the payload to the needs of the station
    • Dry cargo (in cargo section): Up to 1,800 kilograms (4,000 lb)
    • Propellant: Up to 870 kilograms (1,920 lb)
    • Water: Up to 420 kilograms (930 lb)
    • Gases: Up to 50 kilograms (110 lb)
  • Total payload capacity (in cargo section) for disposal: 2,140 kilograms (4,720 lb)

Progress MS improvements

The Progress MS received the following upgrades with compared to the Progress M:

  • New flight control system (SUD): Instead of relying only on six ground stations to determine its orbital path, the new SUD flight control system will also use signals from GLONASS navigation satellites.
  • New Kurs-NA rendezvous system: The new Kurs-NA (Russian: Курс-Новая Активная, romanized: Kurs-Novaya Aktivnaya, lit.'Course-New Active') automatic docking system is designed and manufactured in Russia, replacing its Ukrainian predecessor. This change addresses a political problem (with the two countries at war) and enhances the system’s capabilities with a higher level of computerization. While the original Kurs system was highly reliable over the years, many of its electronic components have become outdated. The Kurs-NA is 25 kg (55 lb) lighter, 30% smaller, and consumes 25% less power. Additionally, it features a single phased-array antenna, replacing four antennas on the older system, while the two narrow-angle antennas have been retained although re-positioned further toward the rear. To assist with docking, the old halogen headlight has been replaced with a brighter, more energy-efficient LED light.
  • Unified Command and Telemetry System (EKTS, Russian: Единая Командно-Телеметрическая Система, romanized: Edinaya Komandno-Telemetricheskaya Sistema): Instead of solely relying on ground stations in Russian territory, the spacecraft has a satellite-capable communications system, EKTS, that connects to Russia's Luch system, providing coverage 83 percent of the day. It also retains very high frequency (VHF) and ultra high frequency (UHF) radios for communications with ground stations. The large EKTS S-band satellite antenna array, one of the most prominent new features on the ship's exterior, is also capable of communicating via American TDRS and Europe's EDRS satellites. The EKTS integrates several previous systems, including the BRTS (radio), MBITS (telemetry), and Rassvet (radio voice), which have been replaced or upgraded for compatibility. Additionally, it features a COSPAS-SARSAT transponder for real-time location tracking during reentry and landing. These changes enable the Soyuz to use the same ground segment terminals as the Russian Segment of the ISS.
  • Additional micro-meteoroid protection: Additional anti-micro-meteoroid shielding was added to the cargo section module walls. This measure was designed to safeguard the spacecraft's most vulnerable component against the unlikely but potential threat of a meteoroid or space debris impact.
  • Improved docking mechanism: The docking system received a backup electric driving mechanism.
  • Digital camera system: The spacecraft utilizes a digital television camera system based on MPEG-2, replacing the older analog system. This upgrade enables space-to-space RF communication between the spacecraft and the station and reduces interference.
  • CubeSat deployment platform: New external compartment that enables it to deploy CubeSats. Each compartment can hold up to four launch containers. First time installed on Progress MS-03.

List of flights

Spacecraft S/N Launch (UTC) Carrier
rocket
Launch
pad
Docking Deorbit
(UTC)
Remarks
Port Docking
(UTC)
Undocking
(UTC)
Progress MS-01 431 21 December 2015
08:44:39
Soyuz-2.1a Site 31/6 Pirs nadir 23 December
10:27
2 July 2016
23:48
3 July
07:03
ISS-62P
Progress MS-02 432 31 March 2016
16:23:57
Soyuz-2.1a Site 31/6 Zvezda aft 2 April
17:58
14 October
09:37
14 October ISS-63P
Progress MS-03 433 16 July 2016
21:41:45
Soyuz-U Site 31/6 Pirs nadir 19 July
00:20
31 January 2017
14:25
31 January
17:34
ISS-64P
Progress MS-04 434 1 December 2016
14:51:52
Soyuz-U Site 1/5 Zvezda aft 1 December (Failed to reach orbit) ISS-65P.
Soyuz third stage anomaly. Vehicle lost 190 km (120 mi) over Tuva. Failed to reach orbit.
Progress MS-05 435 22 February 2017
05:58:33
Soyuz-U Site 1/5 Pirs nadir 24 February
08:30
20 July
12:00
20 July ISS-66P
Progress MS-06 436 14 June 2017
09:20:13
Soyuz-2.1a Site 31/6 Zvezda aft 16 June
11:37
28 December
01:03
28 December ISS-67P
Progress MS-07 437 14 October 2017
08:47
Soyuz-2.1a Site 31/6 Pirs nadir 16 October
11:37
28 March 2018
13:50
26 April ISS-68P
Progress MS-08 438 13 February 2018
08:13:33
Soyuz-2.1a Site 31/6 Zvezda aft 15 February
10:38
23 August
02:16
30 August ISS-69P
Progress MS-09 439 9 July 2018
21:51:33
Soyuz-2.1a Site 31/6 Pirs nadir 10 July
01:31
25 January 2019
12:55
25 January ISS-70P.
It took just 3 hours, 40 minutes to dock the spacecraft to the ISS after the rocket's launch.
Progress MS-10 440 16 November 2018
18:14:08
Soyuz-FG Site 31/6 Zvezda aft 18 November
19:28
4 June 2019
08:40
4 June ISS-71P
Progress MS-11 441 4 April 2019
11:01:35
Soyuz-FG Site 31/6 Pirs nadir 4 April
14:25
29 July
10:44
29 July ISS-72P
Progress MS-12 442 31 July 2019
12:10:46
Soyuz-2.1a Site 31/6 Pirs nadir 31 July
15:29
29 November
10:25
29 November
14:19
ISS-73P
Progress MS-13 443 6 December 2019 09:34:11 Soyuz-2.1a Site 31/6 Pirs nadir 9 December
10:35:11
8 July 2020
18:22:00
8 July
22:05
ISS-74P
Progress MS-14 448 25 April 2020
01:51:41
Soyuz-2.1a Site 31/6 Zvezda aft 25 April
05:12:00
27 April 2021
23:11:00
29 April
00:42
ISS-75P
Progress MS-15 444 23 July 2020
14:26:22
Soyuz-2.1a Site 31/6 Pirs nadir 23 July 17:45:00 9 February 2021
05:21:00
9 February
09:13
ISS-76P
Progress MS-16 445 15 February 2021
04:45:06
Soyuz-2.1a Site 31/6 Pirs nadir/Zvezda nadir 17 February
06:27
26 July
10:55 (with Pirs)
26 July
14:51 (with Pirs)
ISS-77P
Removed Pirs module from ISS
Progress MS-17 446 30 June 2021
23:27:20
Soyuz-2.1a Site 31/6 Poisk zenith 2 July
00:59
20 October
23:42
25 November
14:34 (with docking adapter)
ISS-78P
Removed Nauka module nadir port passive docking adapter from ISS
Nauka nadir 22 October
04:21
25 November
11:22 (with docking adapter)
Progress MS-18 447 28 October 2021
00:00:32
Soyuz-2.1a Site 31/6 Zvezda aft 30 October
01:31:00
1 June 2022
08:03
1 June
11:51
ISS-79P
Delivered LCCS part of MLM Means of Attachment of Large payloads to ISS
Progress MS-19 449 15 February 2022
04:25:40
Soyuz-2.1a Site 31/6 Poisk zenith 17 February
07:03:20
23 October
22:45:34
24 October
01:51
ISS-80P
Progress MS-20 450 3 June 2022
09:03
Soyuz-2.1a Site 31/6 Zvezda aft 3 June
13:02
7 February 2023
05:01
7 February
08:37
ISS-81P
Progress MS-21 451 26 October 2022
00:20
Soyuz-2.1a Site 31/6 Poisk zenith 28 October
02:49
18 February 2023
02:26
19 February
03:15
ISS-82P
Progress MS-22 452 9 February 2023
06:15
Soyuz-2.1a Site 31/6 Zvezda aft 11 February
08:45
20 August
23:50
21 August
02:58
ISS-83P
Progress MS-23 453 24 May 2023
12:56
Soyuz-2.1a Site 31/6 Poisk zenith 24 May
16:19
29 November
07:55
29 November
11:02
ISS-84P
Progress MS-24 454 23 August 2023
01:08
Soyuz-2.1a Site 31/6 Zvezda aft 25 August
03:50
13 February 2024
02:09
13 February
05:16
ISS-85P
Progress MS-25 455 1 December 2023
09:25
Soyuz-2.1a Site 31/6 Poisk zenith 3 December
11:18
28 May 2024
08:39
29 May
11:48
ISS-86P
Progress MS-26 456 15 February 2024
03:25
Soyuz-2.1a Site 31/6 Zvezda aft 17 February
06:06
13 August
02:00
13 August
05:49
ISS-87P
Progress MS-27 457 30 May 2024
09:43
Soyuz-2.1a Site 31/6 Poisk zenith 1 June
11:43
19 November
12:53
19 November
16:51
ISS-88P
Progress MS-28 458 15 August 2024
03:20:17
Soyuz-2.1a Site 31/6 Zvezda aft 17 August
05:53
ISS-89P
Progress MS-29 459 21 November 2024
12:22:23
Soyuz-2.1a Site 31/6 Poisk zenith 23 November
14:31
ISS-90P

Notes

  1. Progress MS-14 remained docked more than one year

References

  1. "Progress cargo ship". www.russianspaceweb.com. Retrieved 23 November 2024.
  2. ^ Zak, Anatoly. "Progress-MS cargo ship". RussianSpaceWeb.com. Retrieved 29 November 2024.
  3. "Upgraded Progress Transport Cargo Spacecraft Getting Ready for Launch". Yuzhny Space Center. 10 August 2015. Archived from the original on 4 March 2016. Retrieved 13 August 2015.
  4. Blau, Patrick. "Progress MS Spacecraft". Spaceflight101.com. Retrieved 17 November 2020.
  5. Krebs, Gunter (1 December 2015). "Progress-MS 01-19". Gunter's Space Page. Retrieved 16 November 2018.
  6. Zak, Anatoly (8 July 2016). "The Kurs-NA docking system for Soyuz MS". RussianSpaceWeb.com. Retrieved 9 July 2016.
  7. Harding, Pete (28 July 2012). "Progress M-15M re-docks to ISS following resolution of Kurs-NA failure". NASASpaceFlight (not associated with NASA). Retrieved 1 September 2012.
  8. Zak, Anatoly (7 July 2016). "The EKTS communications system for Soyuz MS spacecraft". RussianSpaceWeb.com. Retrieved 6 July 2016.
  9. Zak, Anatoly (3 July 2016). "Soyuz rocket flies critical test mission with Progress-MS". RussianSpaceWeb.com. Retrieved 6 July 2016.
  10. Zak, Anatoly (17 July 2016). "Progress MS-03 heads to the ISS". Russian Space web. Retrieved 18 July 2016.
  11. Clark, Stephen (16 July 2016). "Progress supply ship heads for International Space Station". Retrieved 18 July 2016.
  12. "Progress MS-09 mission to ISS". Retrieved 10 July 2018.
  13. "Schedule of ISS flight events (part 2)". forum.nasaspaceflight.com. Retrieved 31 July 2022.
  14. "Год "Науки" на МКС" [Year of "Science" on the ISS] (in Russian). Roscosmos. 29 July 2022. Archived from the original on 21 August 2022.
  15. "Progress-MS 01 - 19". Gunter's Space Page. Retrieved 9 November 2021.

External links

Progress spacecraft
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See also
  • Signsindicate launch or spacecraft failures.
Soyuz spacecraft variants
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