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India to Conduct its First Hypersonic Flight Experiment (HEX-01) for AVATAR RLV-TD in March!

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Isro to carry out winged-reusable rocket tech demo
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Isro will carry out the technology demonstration of the reusable launch vehicle in March

Mumbai: Satellites are typically deployed by expensive rockets which disintegrate in phases en route to space; however, the Indian Space Research Organisation (Isro) is working on developing the technology for a winged rocket that can be used repeatedly, a senior official said.

Isro will carry out the technology demonstration of the reusable launch vehicle in March, the official said. Space vehicles are costly to build and launch, and making them reusable could help reduce space mission costs.

“The structure that makes a rocket has to be such that it should have 98% propellant and 2% structure. Only then reusability is possible. Today’s technology does not allow you to go to that level as 5% to 10% will be the mass of the structure and around 90% will be the propellant,” said S. Somanath, associate director of Isro’s Vikram Sarabhai Space Centre (VSSC).

“But then, new ideas are coming up, SpaceX is working on a reusable launch vehicle, but nobody is sure if in the next 10 years, reusable vehicles will be a reality,” Somanth added.

VSSC is trying to develop a Winged Reusable Launch Vehicle Technology Demonstrator (RLV-TD) which will act as a flying tester to assess hypersonic flight, autonomous landing, powered cruise flight and hypersonic flight using air-breathing propulsion. Isro is currently integrating the flight model.

In the technology demonstrator, Isro will test if the 12-tonne vehicle can reach five times the speed of sound, whether it can re-enter the atmosphere and land on the sea using its computer system. To be sure, this will be a technological demonstration and the tested vehicle will not be reusable. The VSSC director explained that take-off will be vertical like a rocket, and landing will be like that of an aircraft.

“The reusable launch vehicle is important because space orbiting currently costs us $5,000 per km. That kind of money, space exploration and commercial space activities, are not possible,” explained Somanth. “We want to come down to $500, and the one problem here is hardware. Propellant is not that costly, but the hardware is extremely costly and needs to be reused for space travel to be affordable,” he added.

Attempts at developing an operational reusable rocket launcher have not been quite successful so far. Till now, only two vehicles have come close to being a reusable launch vehicle—one being the space shuttle developed by the US, and the other, Buran developed by Russia. Both of these were only partially usable.

Source:- Isro to carry out winged-reusable rocket tech demo - Livemint
 
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RLV Technology Demonstration Programme

Reusable Launch Vehicle-Technology Demonstration Programme
or RLV-TD are a series of technology demonstration missions that have been conceived by ISRO as a first step towards realising a Two Stage To Orbit (TSTO) fully re-usable launch vehicle, Avatar.

For this purpose a Winged Reusable Launch Vehicle technology Demonstrator (RLV-TD) has been configured. The RLV-TD will act as a flying test bed to evaluate various technologies like hypersonic flight, autonomous landing, powered cruise flight and hypersonic flight using air-breathing propulsion.

A total of four RLV-TD flights are planned by ISRO.
HEX is scheduled to take place in March 2015.

Hypersonic Flight Experiment
Hypersonic Flight Experiment or HEX is to be the first test flight in the Avatar Reusable launch vehicle development program or the RLV-TD Program. It was to be first in a series of demonstration trials to be carried out by ISRO to validate the design of the Avatar RLV.

The demonstration trials will pave the way for a Two-Stage-To-Orbit (TSTO) fully re-usable Avatar launch vehicle. The Hypersonic Flight Experiment (HEX) is scheduled for launch in March 2015.

HEX will be the first test flight of a reusable launch vehicle like the Avatar. The test flight objectives include:
  • Validating the aerodynamic design characteristics during Hypersonic flight.
  • Characterize induced loads during the Hypersonic re-entry into the atmosphere.
  • Recovery of the HEX vehicle from the sea.
  • Assess the performance of the carbon fibre used in construction of the nose of the vehicle.
  • Demonstrating First Stage separation sequencing.
Mission -
  • First stage: live, 9 ton solid booster (S-9)
  • Second stage: dummy (Scramjet will be used in the future.
The HEX sits atop a 9 ton solid booster(S-9) which will propel the vehicle to a predetermined altitude. The first stage is then jettisoned and the vehicle re-enters the atmosphere at hypersonic speed. The vehicle gradually glides through the atmosphere and a parachute is deployed. The vehicle is then recovered from the sea.
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Avatar (spacecraft)

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A scaled down version of AVATAR undergoing aero-elastic test.​

AVATAR
(Sanskrit: अवतार) (from "Aerobic Vehicle for Transatmospheric Hypersonic Aerospace TrAnspoRtation") is a concept for a manned single-stage reusable spaceplane capable of horizontal takeoff and landing, by India's Defence Research and Development Organization along with Indian Space Research Organization and other research institutions. The mission concept is for low cost military and commercial satellite space launches, as well as for space tourism.

In January 2012, it was announced that a scaled prototype, called Reusable Launch Vehicle-Technology Demonstrator (RLV-TD), has been approved to be built. The first scaled-down tests are planned for 2015, and the first manned AVATAR flight is proposed for 2025.

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Concept
The idea is to develop a hyperplane vehicle that can take off from conventional airfields. Its liquid air cycle engine would collect air in the atmosphere on the way up, liquefy it, separate oxygen and store it on board for subsequent flight beyond the atmosphere. The AVATAR RLV was first announced in May 1998 at the Aero India 98 exhibition held at Bangalore.

AVATAR is projected to weigh 25 tons, of which 60% of that mass would be liquid hydrogen fuel. The oxygen required by the vehicle for combustion in outer space is collected from the atmosphere, thus reducing the need to carry oxygen during launch. The notional specification is for a payload weighing up to 1,000 kg to low earth orbit and to withstand up to 100 launches and re-entries.

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If built, AVATAR would take off horizontally like a conventional airplane from a conventional airstrip using turbo-ramjet engines that burn hydrogen and atmospheric oxygen. Once at a cruising altitude, the vehicle would use scramjet propulsion to accelerate from Mach 4 to Mach 8. During this cruising phase, an on-board system would collect air from the atmosphere, from which liquid oxygen would be separated and stored. The liquid oxygen collected would then be used to burn the carried hydrogen in the final flight phase to attain orbit. The vehicle would be designed to permit at least one hundred launches and re-entries into the atmosphere.

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Development
AVATAR is being developed by India's Defence Research and Development Organization. Air Commodore Raghavan Gopalaswami, who is heading the project, made a presentation on the space plane at the global conference on propulsion at Salt Lake City, USA on July 10, 2001. Gopalaswami said the idea for AVATAR originated from the work published by the RAND Corporation of the United States in 1987.

In January 2012, it was announced that an scaled prototype, called Reusable Launch Vehicle-Technology Demonstrator (RLV-TD), had been approved to be built and tested. The aerodynamics characterization of the RLV-TD was done by National Aerospace Laboratories in India. The unmanned scaled-down prototype weighs about 3 tonnes at takeoff, would have a diameter of 0.56 m and a length of 10 m. The RLV-TD is being built by a Hyderabad-based private company called CIM Technologies. The first tests may begin in 2015. RLV-TD will be mounted on top of a rocket and launched beyond the atmosphere, after which the RLV-TD will separate and re-enter the atmosphere traveling through the hypersonic regime. ISRO presentations indicate that the manned AVATAR spaceplane may fly approximately in 2025.

Source:- Avatar (spacecraft) - Wikipedia, the free encyclopedia
RLV Technology Demonstration Programme - Wikipedia, the free encyclopedia
Hypersonic Flight Experiment - Wikipedia, the free encyclopedia
 
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NAL India performs Dynamic testing of RLV-TD models

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Reusable Launch Vehicle is envisioned by ISRO as an alternative to expendable launch vehicles to cut down the cost of space transportation. To achieve this goal, ISRO is currently developing a Reusable Launch Vehicle Technology Demonstrator (RLV-TD) to act as a platform to demonstrate various technologies like
1) hypersonic flight,

2) autonomous landing,

3) flush air data measurements,

4) Re-entry thermal protection systems, etc.


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RLV-TD Ascent and Descent configuration models (Credit NAL)

ISRO is utilizing various NAL facilities to perform tests on scaled model of RLV-TD. Dynamic tests were performed by NAL using forced oscillation rig to determine the pitch/yaw damping characteristics of a scaled model of RLV-TD configuration. This will help in building flight stability augmentation system for both ascent and descent configuration of RLV-TD. These tests were carried out in the 1.2 m trisonic wind tunnel facility.

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RLV-TD Ascent configuration model in wind tunnel testing at NAL.

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RLV-TD Descent configuration model in wind tunnel testing at NAL.

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RLV-TD REX

As man's space exploration ambitions are becoming insatiable, a demanding need has arisen to make space missions more affordable and reliable.

To date, space missions have been quite expensive undertakings – be it placing satellites in low-Earth orbit or sending astronauts to space or robotics for inter-planetary explorations.

According to estimates, US space agency NASA spent around 20 to 25 billion US dollars on its Apollo 11 Moon landing mission in 1969.

While executing manned missions is exorbitantly high, the cost of launching satellites also comes at a high price.

Hence, devising new ways and means for low-cost and reliable access to space has become the clear objective for all space-faring nations today.

Development of the Reusable Launch Vehicle (RLV) technology is a pioneering step in this direction. Such a launch vehicle, if developed successfully, will not only be a major technological breakthrough, but would also yield rich economic dividends for future space programmes.

A Reusable Launch Vehicle (RLV) refers to a vehicle that can be launched into space more than once. The vehicle can stay in orbit during its mission period and return to Earth after the mission’s completion. It can then be used to conduct subsequent space missions.

An RLV can be used either to launch payloads such as satellites (small/large) or it can ferry astronauts to space and bring them back.

The Reusable Launch Vehicle is different from an Expendable Launch Vehicle (ELV) system in the sense that it can be used for more than one space mission. An Expendable Launch Vehicle is capable of carrying payloads to space only once and its components cannot be recovered for reuse.

The space shuttles of NASA, presently used to ferry astronauts to space, are partially reusable launch vehicles. Each shuttle is reused after several months of refitting work for each launch.

Several countries, including US, Russia and India, are working on the concept of Reusable Launch Vehicle system. However, with several technological challenges involved, no major breakthrough has been achieved in this direction so far.

While designing an RLV, the key technological aspects to focus on could be its;

1. Composite, low-weight structure
2. A well-developed heat shield to protect the system from disintegration while re-entering Earth
3. Improved propulsion
4. Increased range
5. High payload carrying capacity


One of the conceptual designs for RLV is the single-stage-to-orbit (SSTO) vehicle. An SSTO reaches space orbit by using its propellants and fluids and does not abandon any hardware during its space journey to reduce weight.

However, as per rocket equation, an SSTO should be ultra light in its mass to achieve flight acceleration. Such a light structure in turn could make the vehicle very small which would mean low/small payload carrying capacity and hence, higher costs.

Another more reliable design structure for the RLV is the two-stage-to-orbit (TSTO) vehicle. In a two-stage-to-orbit (TSTO) launch vehicle, two distinct stages provide propulsion consecutively in order to achieve orbital velocity.

In the TSTO launch system, two independent vehicles operate. While the first stage vehicle can return to the launch site for re-use, the second stage can return after flying one or more orbits and re-entering.

This is usually proposed to be done by flying a compromise trajectory that keeps the first stage above or close to the launch site at all times, or by using small airbreathing engines to fly the vehicle back, or by recovering the first stage downrange and returning it some other way (often landing in the sea, and returning it by ship.)

The US’s effort for designing a fully operational Reusable Launch Vehicle is the development and testing of its X-37 space plane. The X-37 is a technology demonstration project that will test and validate technologies in the environment of space as well as test system performance of the vehicle during orbital flight, reentry and landing. Results from the X-37 will aid in the design and development of NASA’s Orbital Space Plane – designed to provide a crew rescue and crew transport capability to and from the International Space Station.

Indian space agency ISRO has conceived similar plans to design, develop and test a two-stage-to-orbit (TSTO) fully re-usable launch vehicle system. For this, a series of technology demonstration missions have been conceived.
Indian RLVs for low cost access to space

The Indian RLV has been conceived by ISRO as a space launch system that will significantly cut down launch cost from the present level of around $12,000 / kg. ISRO's RLV is a pure launcher. It is not designed to enter orbit.

The RLV will loft a satellite into orbit and immediately re-enter the atmosphere and glide back for a conventional landing. The RLV and the rocket booster will be recovered separately, with the former making a conventional landing on a runway and booster making a parachute landing.

ISRO’s RLV will possess wings and tail fins, and will be launched atop a 9 ton solid booster called S-9, similar to the ones on the PSLV. The space agency plans to achieve RLV capability in three phases - Re-entry Technology Development, RLV Runway Recovery, and Scramjet Power.

The RLV-TD prototype will look vaguely like a mini Space Shuttle, and will be used to carry out a series of experiments - HEX, LEX, REX, SPEX.

For HEX (Hypersonic Flight Experiment), the RLV-TD will be mounted on top of a rocket and launched beyond the atmosphere, after which the RLV-TD will separate and re-enter the atmosphere like the Space Shuttle, traveling through the hypersonic regime. This is to prove the aerobody, which will be ditched in the ocean at the end.

The next experiment LEX (Landing Experiment) will see an RLV-TD fitted with deployable landing gear and probably dropped from a larger aircraft, to prove the technology of autonomous landing.

The next experiment REX (Return Flight Experiment) would see RLV-TD fitted with small engines to take off horizontally like an aircraft and also then land again horizontally like an aircraft.

The final experiment SPEX (Scramjet Propulsion Experiment) will see RLV TD fitted with a hypersonic scramjet engine of waverider type underneath. It will take off and land like an aircraft as before, but in between it will accelerate to supersonic speed and activate its scramjet engines to accelerate hypersonically.

The eventual AVATAR TSTO vehicle will however look somewhat different than RLV-TD.

AVATAR (Aerobic Vehicle for hypersonic Aerospace Transportation) is a conceptual single-stage reusable rocket plane which is capable of horizontal launch and land SSTO Reusable launch vehicle being developed by India's Defense Research and Development Organization (DRDO) along with Indian Space Research Organization (ISRO) and other research institutions, which can be used for cheaper military and civilian satellite launches.

When operational, it is planned to be capable of delivering a payload weighing up to 1000 kg to low earth orbit. The hyperplane will takeoff from conventional airfields, collect air in the atmosphere on the way up, liquefy it, separate oxygen and store it on board for subsequent flight beyond the atmosphere.

It is planned to be the size of a MiG-25 fighter and would be capable of delivering a 500 kg to 1000 kg payload to low earth orbit at very cheap rate for an estimated vehicle life of 100 launches.

Avatar is proposed to weighing only 25 tonnes in which 60 per cent of mass will be liquid hydrogen fuel. The oxygen required by the vehicle for combustion is collected from the atmosphere, thus reducing the need to carry oxygen during launch. Avatar is said to be capable of entering into a 100-km orbit in a single stage and launching satellites weighing up to one tonne.

Currently DRDO plans to build and fly a scaled down version of Avatar, weighing just 3 tonnes at take off. AVATAR design has already been patented in India and applications for registration of the design have been filed in patent offices in the United States, Germany, Russia and China.

Finally, in a nutshell, the successful development of the reusable launch vehicle system certainly promises to make future space missions more affordable and easy!
 
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RLV-TD
Structural Model has been realised, which consists of fuselage nose body, fuselage straight body, a pair of double delta wings and two vertical tails. This structural assembly incorporates all the complexities of an aircraft and rocket embedded in it.

S9 booster static tests: second static test of RLV-TD HS9 motor with Secondary Injection Thrust Vector Control (SITVC) system was successfully conducted.

RLVTD-S9 booster stage separation system qualified.

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For HEX01 TPS will be a combination of ablative, silica tiles, ceramic matrix and carbon composites and probably matellic. There is no data available on the reusability of the TPS, but it seems that ISRO is more inclined towards using metallic TPS for the TSTO. ex.

"Manufacturing of Inconel 718 Based Honeycomb Panels for Metallic Thermal Protection Systems" 2012
Abstract: Metallic thermal protection system (MTPS) offers significant improvements over the ceramic based TPS for reentry applications. Space shuttle refurbishment time is estimated to be around 17000 man hours between flights. Metallic based TPS can be fabricated easily and provides wide range of design options for TPS. Adaptability and robustness of metallic thermal protection systems offers the potential for reusability. In this work, a unique manufacturing process has been evolved to realize light weight honeycomb panels through corrugation, laser welding and diffusion brazing of faceplates, where in 50 micron thick Inconel718 foil is used for making honeycomb core and 0.2mm thick Inconel718 foil as faceplates. The compression and three point bend test on these panels have shown no debond between faceplates and honeycomb core. 150x150x5mm size honeycomb panels were coated with YSZ and NiCrAlY based Thermal Barrier Coatings (TBC) and high temperature tests have shown thermal resistance of around 570 0C with front wall temperature of 1186 0C and back wall of 533 0C. Also these panels have been characterized for reusability by the testing of same panel at different heat flux levels. Though it is found that honeycomb panel has shown its integrity without debond a certain acceptable level of degradation in coating is observed. Thus Inconel718 based honeycomb panels with TBC coating are proved for use as thermal protection system for reusable launch vehicle systems.

Development of Functionally Graded Coating Material for Metallic Thermal Protection System of Reusable Launch Vehicle, 2011.

Abstract: Functionally graded coating material (FGM) based on yttria-stabilized zirconia (YSZ) and Ni-Cr-Al-Y was designed and developed for metallic thermal protection system of reusable launch vehicle (RLV). Coating was made using premixed mechanically alloyed YSZ and Ni-Cr-Al-Y powders through plasma spray technique. Thermal stress analysis was carried out, which showed significant reduction in stress in FGM coating as compared to dual coating. The phase composition of coating was found to be close to the designed one. Porosity varied in the range of 8-18%. Average emissivity of three different time exposures of 30, 60 and 90 s was found to be 0.8. Solar absorptivity was found to be 0.55. Fatigue life of FGM coating evaluated along with Inconel and Ti6Al4V metallic substrate was compared with dual coating. FGM coating could be fatigue tested to relatively higher thermal cycles as compared to dual coating on the Inconel substrate. Heat flux measured at top surface was found to be close to simulated heat flux for windward side of RLV. Top surface temperature was similar for both type of metallic substrates and was matching with predicted temperature. However, substrate temperature was higher for Ti6Al4V as compared to Inconel alloy due to higher thermal diffusivity of Ti6Al4V.

Thermostructural Analysis of Metallic Thermal Protection System’: Sponsored by Vikram Sarabhai Space Centre, Thiruvananthapuram, Indian Space Research Organisation, 2008-09.
Manned space missions returning to the Earth require thermal protection system to absorb the thermal energy due to aerodynamic heating. Of the four mechanisms of thermal protection: (i) heat sink, (ii) cooling, (iii) surface insulation and (iv) ablation, the third one is considered suitable for vehicles used in multiple missions, such as space shuttle. In order to avoid / reduce damage, requiring extensive repair before next flight, metallic thermal protection systems (MTPS) are considered suitable. ISRO is presently involved in the design and development of MTPS for its Re-usable Launch Vehicle (RLV) programme. A finite element method based software has been developed as a design tool to carry out thermal and structural analyses of MTPS.

Title of Invention MANUFACTURING PROCESS TO REALIZE LIGHTWEIGHT INCONEL-718 PANELS FOR METALLIC THERMAL PROTECTION SYSTEM
Abstract ABSTRACT "A method of manufacturing lightweight, honeycomb metallic thermal protection panels." This invention relates to lightweight honeycomb metallic thermal panels, which are reusable, heat resistant and are useful in making aerospace vehicle parts. Structures made from such panels are capable of with standing temperature conditions at re-entry of space vehicles. These panels are made from honeycomb structures made from thin corrugated films of super alloys like NiCr alloy Titanium Aluminize and the like which are laser welded to form honey comb structures of the desired thickness. They are then sandwiched between two face plates, which are treated to withstand oxidation.

As far as choice of design is concerned, ISRO must have chosen the design based on required mission profile, respective aerodynamic challenges involved and over all cost analysis of different configuration. Its nothing to do with looks.

To be used for the flight regime of 2.5 Mach to 0 Mach.
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NEURAL NETWORK BASED FLUSH AIR DATA SYSTEM (FADS) FOR REUSABLE LAUNCH VEHICLES
Abstract
Flush air data systems (FADS) are gaining importance for use in measurement of air data parameters like angle of attack, sideslip angle, Mach number and dynamic pressure for reentry and reusable vehicles, advanced aircrafts, interplanetary space probes etc. These air data parameters are critical for successful mission management of the vehicle during the flight phases dominated by complex aero thermal effects.

Flush Air Data System makes use of a matrix of flush pressure orifices located on the nose region (or stagnation region) of the vehicle to estimate air data parameters. The surface pressures are sensed using highly accurate absolute pressure transducers. The multivariable relationship between the pressure measurement and the output air data parameters is complex and highly nonlinear. Different methods are proposed in literature for the estimation of air data parameters using surface pressure measurements. Some of the earlier semi-empirical model based approaches used to process FADS pressure data have experienced numerical instabilities resulting in momentary degradation in system performance.

In this paper a neural network based FADS algorithm is developed for a reusable launch vehicle technology demonstrator. FADS is proposed to be used for the flight regime from Mach number 2.5 to 0. Neural networks, which require large quantities of training aerodynamic data set offer a simple, flexible and accurate solution for such complex applications. Neural network systems allow for the correlation of complex nonlinear systems without requiring explicit knowledge of the functional relationship that exists between the input and output variables of the system. Further, algorithms with neural network techniques are inherently stable for the calibration of nonlinear data involving more number of independent parameters.

The pressure port configuration used in this paper consists of nine pressure ports located on the nosecone of the vehicle. The pressure ports are arranged in a crucifix fashion with five ports located in the vertical meridian and four in the horizontal meridian. The pressure ports are connected to the pressure transducer using pneumatic tubing designed to satisfy frequency and thermal response requirements. The developed algorithm is validated using calibration data generated from wind tunnel tests. Back propagation technique is used to train the neural network to achieve the desired level of accuracy. The present study shows that with properly trained networks, the neural network can be used effectively for real-time prediction of air data states during the critical flight phases.

First stage: vertical launch powered by 3 semi-cryogenic engines (2000 kn each). Unpowered glide back to airstrip after separation around 100-150 km. RLV-TD programme to demonstrate the technologies involved in this stage development.

Second stage: Recoverable stage powered to orbit by cryogenic propulsion involving 2 cryogenic engines. Spacecraft/satellite separation by opening the cargo bay doors. Ballistic re-entry into the earth atmosphere and to be recovered at sea. SRE programme to demonstrate the technologies involved in the development of this stage
 
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Hold on the first stage is using semi cryo engines. But that isnnot ready yet. So which rocket is going to lauch this vehicle.
 
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Isro to carry out winged-reusable rocket tech demo
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Isro will carry out the technology demonstration of the reusable launch vehicle in March

Mumbai: Satellites are typically deployed by expensive rockets which disintegrate in phases en route to space; however, the Indian Space Research Organisation (Isro) is working on developing the technology for a winged rocket that can be used repeatedly, a senior official said.

Isro will carry out the technology demonstration of the reusable launch vehicle in March, the official said. Space vehicles are costly to build and launch, and making them reusable could help reduce space mission costs.

“The structure that makes a rocket has to be such that it should have 98% propellant and 2% structure. Only then reusability is possible. Today’s technology does not allow you to go to that level as 5% to 10% will be the mass of the structure and around 90% will be the propellant,” said S. Somanath, associate director of Isro’s Vikram Sarabhai Space Centre (VSSC).

“But then, new ideas are coming up, SpaceX is working on a reusable launch vehicle, but nobody is sure if in the next 10 years, reusable vehicles will be a reality,” Somanth added.

VSSC is trying to develop a Winged Reusable Launch Vehicle Technology Demonstrator (RLV-TD) which will act as a flying tester to assess hypersonic flight, autonomous landing, powered cruise flight and hypersonic flight using air-breathing propulsion. Isro is currently integrating the flight model.

In the technology demonstrator, Isro will test if the 12-tonne vehicle can reach five times the speed of sound, whether it can re-enter the atmosphere and land on the sea using its computer system. To be sure, this will be a technological demonstration and the tested vehicle will not be reusable. The VSSC director explained that take-off will be vertical like a rocket, and landing will be like that of an aircraft.

“The reusable launch vehicle is important because space orbiting currently costs us $5,000 per km. That kind of money, space exploration and commercial space activities, are not possible,” explained Somanth. “We want to come down to $500, and the one problem here is hardware. Propellant is not that costly, but the hardware is extremely costly and needs to be reused for space travel to be affordable,” he added.

Attempts at developing an operational reusable rocket launcher have not been quite successful so far. Till now, only two vehicles have come close to being a reusable launch vehicle—one being the space shuttle developed by the US, and the other, Buran developed by Russia. Both of these were only partially usable.

Source:- Isro to carry out winged-reusable rocket tech demo - Livemint

All the best to ISRO I have full confidence that they will deliver

Sadhu. Sadhu. Sadhu.

Best of luck.

Thx btw what's this
 
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Hold on the first stage is using semi cryo engines. But that isnnot ready yet. So which rocket is going to lauch this vehicle.

Our indigenous semi-cryogenic engine is nearing completion - it is up for component level testing -

The design of the semi-cryogenic engine by LPSC is complete, now the fabrication of sub-systems including booster turbo-pump and pre-burner has commenced and is in the realization stage. The component level testing is set for next month.

The government has already approved an ISRO proposal to develop a 2000 kilo newton semi-cryogenic engine.

The project is expected to cost about Rs 2,500 crore.

Post Mangalyaan, space scientists on mission mode - The Times of India
 
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Hold on the first stage is using semi cryo engines. But that isnnot ready yet. So which rocket is going to lauch this vehicle.

Semi-cryos will be used by TSTO .

This test is just an experimental test to validate hypersonic flight profile .

The TD will be taken up by a solid rocket booster in this flight .
 
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How powerful is a 2000 kilo newton semi-cryogenic engine. & how many countries have it

Powerful enough to power a SLV lifting a 6 ton class payload in the Geosynchronous Transfer Orbit (GTO) or a 12 ton class payload in the Low Earth Orbit. This 2000 kN SCE is envisaged to initially replace the L-110 core stage of the GSLV Mk-3 allowing an upgraded version of the launcher to lift a 6 ton class payload into a GTO, instead of the current 5 ton class.

Till date only 5 nations - US, Russia, China, Japan and France/Europe (ESA) posses this technology.
 
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Powerful enough to power a SLV lifting a 6 ton class payload in the Geosynchronous Transfer Orbit (GTO) or a 12 ton class payload in the Low Earth Orbit. This 2000 kN SCE is envisaged to initially replace the L-110 core stage of the GSLV Mk-3 allowing an upgraded version of the launcher to lift a 6 ton class payload into a GTO, instead of the current 5 ton class.

Till date only 5 nations - US, Russia, China, Japan and France/Europe (ESA) posses this capability.

Damn we need to move fast with this
 
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Please can anyone update us about the status DRDO's HSDTV?

Can this technology being used in the RLV be used in the development of hypersonic cruise missile as well?
 
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