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India to send two astronauts into space in 2016

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Pakistan already has one :P

for Nasa though :P

I don't understand why you feel the need to compare India and Pakistan at every given opportunity.:P

India != Pakistan.

Since you want to compare, I know of at least three Indians who've been to space. :P

Keep it up ISRO!!! :tup:
 
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apreciatted ur concern
wy?coz there is logic

i am no space expert
but if isro is saying then tey must have something up ther sleevs but it might get delayed

Do you know why Indian project always failed in the timeline?
 
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i think its landing in water(sea) splash type
but i may be wrong


Yes it has sucsessfuly tested and recoverd from the sea

6c8a90a24af88e26b11795b228e22330.jpg




Following is govt. press release for reading full please click the link

YEAR ENDER 2007

Indian space programme witnessed several major accomplishments and scaled newer heights in mastering space technology during the year. It is significant to note that the remarkable successes were the result of well-orchestrated programmes undertaken by the department aimed at achieving total self-reliance in this cutting edge technology solely through indigenous efforts and utilizing the expertise available within the organization.

Some of the recent, important developments, were the successful orbiting and recovery of a space capsule from the Indian soil using our own launch vehicle, launching of the state of the art remote sensing satellite Cartosat-2 with better than one meter resolution, launching of a satellite exclusively for an European customer under a commercial contract, successful ground testing of indigenously developed cryogenic upper stage and fabrication and installation of a large antenna for providing tracking and command support for deep space missions in general and Chandrayaan-I, India`s first un-manned lunar mission in particular.

Launch Vehicle Programmes: The launching of Polar Satellite Launch Vehicle (PSLV-C7) on January 10, 2007 carrying our own 680 kg remote sensing satellite Cartosat-2, 56 kg LAPAN-TUBSAT satellite from Indonesia, 6 kg Pehuensat from Argentina and 550 kg Space capsule Recovery Experiment (SRE) aimed at establishing India`s capability to orbit and bring back to earth successfully heralded a new era in the launch vehicle and satellite technology development in the country. PSLV-C7 also demonstrated our capability to launch multiple payloads into different orbits precisely. Space capsule Recovery Experiment carried two experiments to conduct studies in micro gravity was launched into 485 km by 639 km orbit. SRE comprises aero thermal structure, spacecraft platform, deceleration and floatation system besides the micro gravity payloads. After successfully accomplishing the mission the SRE was reoriented and de-orbited to splash down at the designated location in the Indian Ocean region on January 22, 2007. The precise splash down established India`s capability to launch and control accurately to bring back a space capsule. The demonstration of SRE experiment has given confidence to undertake more complex manned missions into low earth orbit. Closely following this was the launch of PSLV-C8 on April 23, 2007 carrying an Italian satellite AGILE into a low earth orbit. Considering the mission requirements PSLV-C8 was launched in core alone configuration which also proved the versatility of PSLV as the vehicle.

Geosynchronous Satellite Launch Vehicle (GSLV-F04) was launched successfully on September 2, 2007 carrying INSAT-4CR into the desired orbit. The launch of GSLV-F04 was significant as the previous flight GSLV-D3 had failed to accomplish the mission owing to a fabrication anomaly. The detailed failure analysis carried out established that the design of GSLV is robust and certain strict quality control measures needs to be enforced during fabrication and inspection. The successful launch of GSLV-F04 reinforced ISRO`s ability to look at failures critically and draw lessons. The recent successful ground testing of the Cryogenic Upper Stage to be used in place of Russian cryogenic stages in GSLV was the crowning glory for ISRO. The cryogenic upper stage was tested for the full flight duration of 12 minutes and the test results fully met all the specified parameters. The development of cryogenic engines involves mastering materials technology, operating rotary pumps and turbines which run at 42,000 rpm at cryogenic temperatures. The successful testing has resulted in total self-reliance in launch vehicle technology.

Efforts to develop and launch the advanced version of GSLV namely GSLV - Mark III capable of putting 4 t payloads into geosynchronous transfer orbit is progressing well with the establishment of necessary infrastructure at ISRO centres such as the casting of 200 t solid boosters etc. GSLV-Mk III uses heavy propulsion stages such as 200 t solid boosters, 110 t liquid stages and 25 t cryogenic upper stages. The launch of GSLV Mk III is scheduled during 2008-09.

Research and development activities in semi-cryogenic propulsion stages, air breathing propulsion, re-usable launch vehicle technology is also being pursued vigorously in an effort towards reducing the launch costs.

PIB Press Release
 
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Materials Development for Future Reusable Launch Vehicles
Dr. M R Suresh
Vikram Sarabhai Space Centre, ISRO, Thiruvananthapuram,India, mr_suresh@vssc.gov.in

EXTENDED ABSTRACT: Indian Space Program is on the verge of venturing into planetary explorations
to Moon, Mars, Sun, etc. and also into the area of advanced Space Transportation Systems for reducing the
cost of access to outer space after successfully realizing the objectives laid down by eminent visionaries
such as Dr.Vikram A Sarabhai and Dr. Satish Dhawan. The commercial launches of Polar Satellite Launch
Vehicle (PSLV) and Geosynchronous Satellite Launch Vehicle (GSLV) have fulfilled the dreams of our
predecessors. The successful culmination of Space-capsule Recovery Experiment (SRE) was the first step
towards the next phase of Space Program. The enthusing future program include development of Reusable
Launch Vehicles, Chandrayaan-1 with Moon Impact Probe, Advanced propulsion technologies such as Air-
Breathing module, Semi-cryogenic and bigger Cryogenic stages, Mission to Sun namely ‘Aditya’,
Geosynchronous Satellite Launch Vehicle–MkIII having higher payload capability, etc. Other eminent
research establishments such as Defense Research and Development Organisation (DRDO) have made
significant strides in the field of missile technologies including under-water deployment of missiles. The
capability to indigenously design, develop and produce aircrafts and helicopters such as LCA (by the
consortium led by ADA) and ALH and Dhruv (by HAL) for defense applications, and SARAS & HANSA
(by NAL) for commercial use have also been accomplished. Synergic partnerships among academia, R&D
laboratories and industries only can make these achievements possible and lead to total self-reliance in
aerospace technologies.
One of the most important factors underlying the success of all the above programs is the fruits of
advanced research in the field of materials science whereby new generation materials, meeting the
properties set by the designers, have been developed through continuous research and development. The
future aerospace systems on the anvil call for advanced materials having the combination of exotic
properties such as high strength, low density, high temperature resistance, high stiffness, high toughness,
low cost, reusability, etc. The launch cost per kg of payload using expendable vehicles is very high and
efforts are made to reduce the same substantially.
The cost reduction can be optimally achieved either by (a)overall weight / cost reduction of the
present vehicles by selecting suitable low cost materials and optimum design methodology of components
and structures, or by (b)opting for reusable vehicles so that the initial high development cost can be
recovered over number of flights.
In the former case the options are limited in terms of new materials as well as design parameters.
The principal design drivers and the possible materials used in the case of aircraft structures are given in
Table-1. However, the driving factors may vary with the type of vehicle that is being designed. For long
range extended capacity aircrafts, weight saving is the driving factor and cost reduction is given second
priority while in the case of smaller custom jets, cost is the driving factor. However, in the area of launch
vehicles, thrust is on safety / reliability and weight saving factors. Reduction in launch cost is also given
due importance in order to be competitive in the international scenario.........

Read full report here
 
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So we will be calling them astronauts? Isn't that the American term? Russia uses Cosmonauts and China uses Taikonauts...
 
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Do you know why Indian project always failed in the timeline?

well india is no developed country hence development comes with delay isnt it
 
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more comming


The term Aakashagami (meaning 'sky traveller'), is a literary word in Sanskit, similar to word 'Astronaut'. 'Brahmāndagami'(Brahmānda- Space and Gami-traveller) is another Sanskrit word literally meaning 'Space traveller'. However, the name Gaganaut, derived from gagana (meaning 'the heavens' or 'vast sky above us'), has become popular amongst the Indian space community as a term for Indian astronauts. The term Antariksha yaatri has been suggested as a more proper name (antariksha signifies space beyond our Earth and yaatri means 'traveller'), and this is the name used in official documents, as well as the Indian media. Other suggestions include vishvanaut (vishva = world = this reality) and brahmanaut (brahmand = universe). After considering several terms, the term Vyomanaut has been finalised by the ISRO.The term Vyomanaut stands for Vyoma which means space or sky in Sankrit.
 
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I dont think the pic is incorrect.
It is a space ship entering the atmosphere. not like a plane fly just 30000ft above the land.
I think the pic shows "entering atmosphere" process but not "landing process", the "landing" process will be more like a normal plane.
It enter the atmosphere with rocket and land with parachute in this pic,the sharp as a shuttle is no use,this has high risk landing
 
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It enter the atmosphere with rocket and land with parachute in this pic,the sharp as a shuttle is no use,this has high risk landing

Geez mate, thats just a cartoon depiction of some of the steps involved in launch and recovery. The actual process, lets be assured, is far more complicated, and no, the spacecraft wont splash into the ocean with a nose down configuration.
 
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I am not yet convinced that as of now, we need a manned space flight. Sure it will give us some bragging rights, but does that warrant a whooping $ 2 bil + price tag. I wonder what is the tangible gain out of this. There are many other niche areas that we can spend this money on.

I am sure we are not going to colonize Mars anytime soon.
 
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