Geosynchronous Satellite Launch Vehicle Mark III

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LVM3 (GSLV Mk III)[1][2]
GSLV MkIII.JPG
Function Medium-lift launch vehicle
Manufacturer Indian Space Research Organisation
Country of origin India
Size
Height 43.43 m (142.5 ft)[1]
Diameter 4.0 m (13.1 ft)
Mass 640,000 kg (1,410,000 lb)[1]
Stages 3
Capacity
Payload to LEO (600 km) 8,000 kg (18,000 lb)[1]
Payload to GTO 4,000 kg (8,800 lb)[1]
Launch history
Status Development
Launch sites Satish Dhawan Space Centre SLP, Andhra Pradesh, India
Total launches 1 (2 stage version)
Successes 1 (2 stage version)
First flight 18 December 2014 (2 stage version; sub-orbital flight)
Booster stage - S200
Length 25 m (82 ft)[1]
Diameter 3.2 m (10 ft)[1]
Propellant mass 207,000 kg (456,000 lb)[1]
Engines 2 Solid
Thrust 5,150 kN (525 tf) each[3][4][5]
Specific impulse 274.5 (vacuum)[1]
Burn time 130 sec[1]
Fuel HTPB[1]
Core stage - L110
Length 17 m (56 ft)[1]
Diameter 4.0 m (13.1 ft)[1]
Propellant mass 110,000 kg (240,000 lb)[1]
Engines 2 Vikas engines
Thrust 1,598 kN (163.0 tf)[1][6][7]
Specific impulse 293 sec[1]
Burn time 200 sec[1]
Fuel UDMH/N2O4
Upper stage - C25
Length 13.5 m (44 ft)[1]
Diameter 4.0 m (13.1 ft)[1]
Propellant mass 27,000 kg (60,000 lb)[1]
Engines 1 CE-20
Thrust 200 kN (20 tf)[1]
Specific impulse 443 sec
Burn time 586 sec
Fuel LOX/LH2

The Geosynchronous Satellite Launch Vehicle Mark III (Hindi: भूस्थिर उपग्रह प्रक्षेपण यान एमके-३; also called LVM3 or GSLV-III)[2] is a launch vehicle developed by the Indian Space Research Organisation (ISRO).

It is intended to launch satellites into geostationary orbit and as a launcher for an Indian crew vehicle. The GSLV-III features an Indian cryogenic third stage and a higher payload capacity than the current GSLV.[8][9]

History

Development for the GSLV-III began in the early 2000s, with the first launch planned for 2009-2010.[10] Several factors have delayed the program, including the 15 April 2010 failure of the ISRO-developed cryogenic upper stage on the GSLV Mk II.[10]

A suborbital flight test of the GSLV-III launcher, with a passive cryogenic third stage, was successfully carried out on 18 December 2014, and was used to test a crew module on a suborbital trajectory.[11] The first orbital flight is planned to take place in 2017.[12] The first flight with a crew on board would take place after 2020.[10]

S200 static test

The S-200 solid rocket booster was successfully tested on 24 January 2010. The booster fired for 130 seconds and generated a peak thrust of about 500 tonnes. Nearly 600 ballistic and safety parameters were monitored during the test and indicated normal performance. A second successful static test was conducted on 4 September 2011.[4]

L110 static test

The Indian Space Research Organisation conducted the first static test of the L110 core stage at its Liquid Propulsion Systems Centre (LPSC) test facility at Mahendragiri, Tamil Nadu on 5 March 2010. Originally targeted for a full 200 second burn, the test was terminated at 150 seconds after a leakage in a control system was detected.[13] On 8 September 2010 ISRO successfully conducted a full 200 second test.[14]

Suborbital flight test

The GSLV LVM-3 lifted off from the second launch pad, Sriharikota, at 9.30 am IST on 18 December 2014. The 630.5 tonne launch vehicle stacking was as follows : a functional S200 solid propulsion stage, a functional L110 liquid propulsion stage, a non-functional dummy stage (in lieu of CE-20 cryogenic propulsion engine) and finally the 3.7-tonne Crew Module Atmospheric Re-entry Experiment (CARE) payload stage. Just over five minutes into the flight, the rocket ejected CARE at an altitude of 126 km. CARE then descended at high speed, controlled by its onboard motors. At an altitude of 80 km, the thrusters were shut down and the capsule began its ballistic re-entry into the atmosphere. CARE’s heat shield was expected to experience a temperature of around 1600 °C. ISRO downloaded launch telemetry during the ballistic coasting phase prior to the radio black-out to avoid data loss in the event of a splash-down failure. At an altitude of around 15 km, the module’s apex cover separated and the parachutes were deployed. CARE splashed down in the Bay of Bengal near the Andaman and Nicobar Islands[15][16][17]

Vehicle description

Stage 1 – solid boosters

The GSLV-III uses S200 solid motors. Each booster has a diameter of 3.2 metres, a length of 25 metres, and carries 207 tonnes of propellant. These boosters burn for 130 seconds and produce a peak thrust of about 5,150 kilonewtons (525 tf) each.[3]

A separate facility has been established at Sriharikota to make the S200 boosters. Another major feature is that the S200’s large nozzle has been equipped with a ‘flex seal.’ The nozzle can therefore be gimballed when the rocket’s orientation needs correction.[18]

In flight, as the thrust from the S200 boosters begins to tail off, the decline in acceleration is sensed by the rocket’s onboard sensors and the twin Vikas engines on the ‘L110’ liquid propellant core stage are then ignited. Before the S200s separate and fall away from the rocket, the solid boosters as well as the Vikas engines operate together for a short period of time.[18]

Stage 2 – liquid motor

The core stage, designated L110, is a 4-meter-diameter liquid-fueled stage carrying 110 tonnes of UDMH and N2O4. It is the first Indian liquid-engine cluster design, and uses two improved Vikas (rocket engine)s, each producing about Lua error in Module:Convert at line 1851: attempt to index local 'en_value' (a nil value)..[6][7] The improved Vikas engine uses regenerative cooling, providing improved weight and specific impulse, compared to earlier rockets.[19] The L110 core stage ignites 113 seconds after liftoff and burns for about 200 seconds.[7]

Stage 3 – cryogenic upper stage

The cryogenic upper stage is designated the C25 and will be powered by the Indian-developed CE-20 engine burning LOX and LH2, producing 186 kilonewtons (19.0 tf) of thrust. The C-25 will be 4 metres (13 ft) in diameter and 13.5 metres (44 ft) long, and contain 27 tonnes of propellant.[19]

This engine is slated for completion and testing by 2015, it will then be integrated with the C25 stage and be put through a series of tests. The first C25 stage will be used on the GSLV-III D-1 mission in early 2017. This mission will put in orbit the GSAT-19E communication satellite.[20] Work on the C25 stage and CE-20 engine for GSLV Mk-III upper stage was initiated in 2003, the project has been subject to many delays due to problems with ISRO's smaller cryogenic engine, the CE-7.5 for GSLV MK-II upper stage.

Payload fairing

The payload fairing has a diameter of 5 metres (16 ft) and a payload volume of 110 cubic metres (3,900 cu ft).[1]

Launches

Flight Launch date/time (UTC) Variant Launch Pad Payload Payload Mass Result
X 18 December 2014
04:00[21]
LVM3-X Second Crew Module Atmospheric Re-entry Experiment (CARE) 3,775 kg[22] Success
Sub-orbital development test flight[23][24][25]
This flight carried a non functional version of the C25 upper stage to simulate its weight and attributes.[18][26]

The launch of LVM3 vehicle on 18 December was successful, with both the launch vehicle and the CARE module meeting the parameters of the mission.[2]

D1 December 2016 (planned)[27] Mk III Second GSAT-19E 3,500 kg[26]
For launching new generation GSAT weighing about 3.5t.[20][26][28]
Will have a functional cryogenic stage.[26]

Future Improvement

There is a proposal to include the Indigenous semi-cryogenic engine[29] to LVM-3 in order to boost its payload capacity to 6 tonnes to GTO.[30]

Comparable rockets

See also

References

  1. 1.00 1.01 1.02 1.03 1.04 1.05 1.06 1.07 1.08 1.09 1.10 1.11 1.12 1.13 1.14 1.15 1.16 1.17 1.18 1.19 1.20 1.21 Lua error in package.lua at line 80: module 'strict' not found.
  2. 2.0 2.1 2.2 Lua error in package.lua at line 80: module 'strict' not found.
  3. 3.0 3.1 ISRO Press Release: S200 First Static Test (S-200-ST-01)
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  9. GSLV MkIII, the next milestone : Interview: K. Radhakrishnan Frontline 7 February 2014
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  14. ISRO Press Release:Successful Static Testing of L 110 Liquid Core Stage of GSLV - Mk III
  15. As it happened: Isro's launch of India's heaviest rocket Times of India 18 December 2014
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  19. 19.0 19.1 LVM3 ISRO 23 December 2014
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  26. 26.0 26.1 26.2 26.3 GSLV Mark-III set for partial test flight The Hindu 2 November 2014
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External links