'Misbehaviour' By Rocket Motor Failed ISRO's EOS-9 Satellite Launch. What Next
On board the rocket was EOS-9, designed to provide continuous and reliable remote sensing data for operational applications across various sectors.
The 'misbehaviour' of the rocket motor may have contributed to the failure of the Indian Space Research Organisation's (ISRO) workhorse rocket on its 63rd flight, experts suggest. ISRO's 63rd Polar Satellite Launch Vehicle (PSLV) launch to place into orbit the EOS-9 surveillance satellite could not be accomplished after PSLV-C61 encountered anomalies in the third of its four stages.
The PSLV-C61 was travelling at a phenomenal 20,160 km per hour - about 28 times the speed of an airplane - when some 888 km downrange from Sriharikota over the Indian Ocean, it tumbled down 6.26 minutes into its nearly 18-minute flight.
Advertisement - Scroll to continue
Experts say the third stage did not explode, as speculated. In fact, as the rocket coasted along while losing altitude and thrust, even the fourth stage was probably ignited. It is still being analysed why the rocket motor "misbehaved" 100 seconds after it ignited the third stage.
The rocket debris and the satellite today rests deep inside the Indian Ocean. Usually, ISRO tries to recover the debris for hardware failure analysis but the deep depths of the Indian Ocean pose a challenge.
"Today, we targeted the 101st launch from Sriharikota, the PSLVC6-1 EOS-09 mission. The PSLV is a four-stage vehicle and up to the second stage, the performance was normal. The third stage motor started perfectly, but during the functioning, we are seeing an observation and the mission could not be accomplished," ISRO Chairman V Narayanan said after the unsuccessful launch.
Mr Narayanan said there was a "fall in the chamber pressure of the motor case".
"We are studying the entire performance. We shall come back at the earliest," he added.
Experts suggest that on the third stage of the rocket motor, there are two vulnerable points - a nozzle at the bottom and the Kevlar joint and sheathing at the top. It seems hot gases from the burning Hydroxyl-terminated polybutadiene (HTPB) fuel entered some sensitive areas and caused the failure.
Dr G Madhavan Nair, former Chairman of ISRO, said he was "shocked and surprised that the solid-fuelled rocket motor with an enviable record of 62 successive launches failed like this". Dr Nair, a rocket specialist who played a key role as project director in mastering the PSLV rocket, estimates that a "possible rupture in the fibre casing of the nearly 8-tonne rocket motor could have been the cause of the failure".
Dr Nair also suggested a quality control or check-out lapse.
All About Earth Observation Satellite-9 (EOS-9), On Board PSLV-C61
On board the rocket was the Earth Observation Satellite-9 (EOS-9), designed to provide continuous and reliable remote sensing data for operational applications across various sectors. Had it been placed into orbit 500 km above the Earth's surface, it would have enhanced India's surveillance capabilities days after India-Pakistan hostilities. Its replacement will take a few years to build.
Though EOS-9 couldn't be put into orbit, four radar satellites and eight Cartosats continue to maintain vigil. EOS-9, however, had the capability to continue surveillance in all-weather conditions and at night because of its Synthetic Aperture Radar (SAR). Apart from maintaining a hawk's eye along India's borders, it would have been vital for applications ranging from agriculture and forestry monitoring to disaster management, urban planning and national security.
ISRO's EOS-9 Satellite Launch Failed. What Next
In 63 launches, the PSLV has failed just four times. With a success rate of over 94 per cent, PSLV is considered a highly reliable rocket.
On its last launch on December 30, 2024, it gave India the highly challenging SpaDex mission. Earlier, on December 5, 2024, it gave a precise launch to the European Space Agency on its Proba-3 satellite mission.
Usually, an internal ISRO 'failure analysis committee' is established, which delivers its findings in a time-bound manner. Occasionally, if the government desires, an external failure analysis committee comprising non-ISRO experts also looks into such setbacks. ISRO usually does not take insurance for its missions as the sovereign government takes the liability.
"ISRO always does thorough failure investigation and fixes the problems," says Dr Abhay A. Pashilkar, Director of the National Aerospace Laboratories (NAL), Bengaluru, who has been part of some of these committees.
The current ISRO chairman, a rocket specialist, headed the committee that fixed the problem encountered in the lander of Chandrayaan-2. When it was fixed, ISRO bounced back with a highly successful Chandrayaan-3 mission.
In the past the committee reports were made public, but in recent times, they have been kept under wraps. This, from an agency where even the junior most engineer has the liberty to question the chairman of ISRO on technical grounds.
At least six critical missions are lined up for the PSLV, including the first non-ISRO-manufactured PSLV rocket spearheaded by a consortium of L&T and Hindustan Aeronautics Limited (HAL). It could be impacted by some delays.
ISRO is not deterred by the setback. Former ISRO Chairman Dr S Somanath is confident the space agency will soon dissect the anomaly and chalk out a way forward.
Experts say ISRO has the tenacity to bounce back very quickly from yesterday's setback.
"I am aware of the formidable challenges we faced during the development of the third-stage solid motor -- an endeavour marked by multiple failures. It is indeed unusual to witness such anomalies resurfacing at this stage. Nevertheless, I have complete confidence that the team will identify the root cause both swiftly and effectively," Dr Somanath said.
"Over the years, such challenges have only strengthened our conviction that failure is never defeat, but rather a formidable tutor. Every towering success of ISRO has been forged in the crucible of adversity -- shaped by lessons deeply learnt and courageously applied."
Sign up to read this article FREE!
Exclusive Stories:
Dive into content reserved just for members.
Fewer Ads:
A cleaner, more enjoyable reading experience.
Enhanced Interface:
Tailored just for you.
Join Now – It's Free!
Hashtags
Try Our AI Features
Explore what Daily8 AI can do for you:
Comments
No comments yet...
Related Articles
Time of India
18 minutes ago
- Time of India
Indian astronaut Shubhanshu Shukla's space mission's schedule out: Check launch date, arrival time, and how to watch live
Axiom Mission 4, carrying ISRO astronaut Shubhanshu Shukla, is set to launch to the ISS on June 10. NASA, Axiom Space, and SpaceX are targeting a launch at 8:22 a.m. EDT. This mission marks the first time an Indian astronaut will visit the ISS as part of a collaboration between NASA and ISRO, fulfilling a commitment to advance space collaboration. Disclaimer Statement: This content is authored by a 3rd party. The views expressed here are that of the respective authors/ entities and do not represent the views of Economic Times (ET). ET does not guarantee, vouch for or endorse any of its contents nor is responsible for them in any manner whatsoever. Please take all steps necessary to ascertain that any information and content provided is correct, updated, and verified. ET hereby disclaims any and all warranties, express or implied, relating to the report and any content therein. More
Hindustan Times
4 hours ago
- Hindustan Times
AI in space operations: Opportunities and challenges
As Artificial Intelligence (AI) technologies evolve, they hold immense potential for transforming space operations. However, there are significant challenges for both Earth-based and onboard AI, including cybersecurity threats, supply chain vulnerabilities, and the complexity of operating in extreme environments. Given the sector's strategic nature, the national security implications of these challenges make it imperative that India adopts a comprehensive approach to AI development in space. It must leverage its own strengths as well as strategic collaborations with trusted partners to balance innovation with security. This brief examines how key spacefaring countries are integrating AI into their space operations, identifies their strengths and areas of development, and charts a way forward for India's AI-driven space ambitions. In the new golden age of space exploration, AI is pushing the boundaries of human capabilities even further than previously imagined possible—by revolutionising space operations, from planning and automation to launch and communication. As the sector goes through a period of exponential growth, AI will be a key to unlocking the full potential of space exploration and creating breakthroughs for anticipated commercial ventures such as space tourism. India has acknowledged the importance of this niche. The Indian Space Research Organisation's (ISRO) Respond Basket 2023 included eight research areas focused on AI and Machine Learning (ML). It has also launched initiatives like the 'AI for Space and Geospatial Innovation: ISRO Immersion Startup Challenge' in 2024, that is aimed at fostering the development of AI applications in space. However, like in any other sector, AI in space is fraught with challenges and uncertainties. Given the sector's strategic nature, these threats are posed not just to the operations but to national security, overall. India can learn from and partner with other spacefaring nations to address these challenges while driving innovation in its domestic ecosystem. This brief examines how key countries are deploying AI in space operations, the challenges they face, and their strengths and areas of development. It outlines a path for the future of AI in space. This paper can be accessed here. This paper is authored by Amoha Basrur, ORF, New Delhi.
Hans India
14 hours ago
- Hans India
Top 5 emerging career options in aerospace engineering
The Indian aerospace industry is experiencing significant growth, driven by both the defense and civil aviation sectors, and is projected to reach around $70 billion by 2030. With this growth, the aerospace and the aviation sector would require more and more skilled manpower to design, develop, operate and maintain the aircraft, rotorcraft, rockets (launch vehicles), spacecraft, missiles, unmanned aerial vehicles (UAVs) and support systems including test opportunitiescreate huge job opportunities in both private and public sectors. To become an aerospace engineer, a bachelor's degree in aerospace/aeronautical engineering is required. Apart from that astrong foundation of STEM subjects like Mathematics, physics, and Chemistry is required. Students can pursue graduation, master's, or doctorate degrees in specialized fields such as aerospace engineering, aeronautical engineering, aerodynamic engineering, aerospace structures and design engineering, aerospace propulsionand many more courses for research and other advanced roles in the domain. The field also includes roles in areas like maintenance, quality control, and project management. Furthermore, with increasing breakthrough and innovations in areas like electric propulsion, UAVs, and additive manufacturing, the domain of aerospace engineering and aviation sectors have become highly multi-disciplinary. Design and development job roles Aircraft/spacecraft design engineers, aerodynamics engineers, propulsion engineers, structural engineers, avionics engineers look after the design and development, flow of air and gases, propulsion system, structure, and electronic and electrical part of the aircrafts/spacecrafts respectively. Testing and research jobs Flight Test Engineers oversee the testing and evaluation of aircraft and spacecraft performance whereas the job of Research and Development (R&D) Engineers are to conduct research and develop new technologies for the aerospace industry. Tunnel Engineers conduct experiments in wind tunnels to study the aerodynamic properties of aircraft and spacecraft. Manufacturing and Production jobs Manufacturing engineers, quality control engineers, aircraft production managers optimize the manufacturing processes, quality standards, and oversee the production of aircraft, missiles, launch vehicles, artificial satellites and manned and unmanned spacecraft. Management and Support jobs To manage the operations of airlines and other aviation related business, oversee the integration of different systems, and to assist in the maintenance, repair and operation in the aircraft and spacecraft, the role of aviation managers, systems manager and aerospace technicians are integral. Government, Defense and private sector jobs Other than the above roles, aerospace engineers have major roles to play in government and defense organisations. While aerospace Engineers with ISRO (Indian Space Research Organization) work on launch vehicles, communication satellites, space missions and related research, those with DRDO (Defense Research and Development Organization) develop defense-related aerospace technologies, such as advanced military aircraft, aero-engines, missiles, and many other systems. In addition, aeronautical engineers work on aircraft maintenance, repair, and operations with the Indian Air Force and also in the private airline sector. Other job roles with the degree includeRobotics Engineers, Materials Engineers, manufacturing engineers, Communications Officers, Academic Researchers, Pilots, etc. The institutions/ organisations who hire the degree holders are Aerospace Manufacturers (HAL), Government Agencies (ISRO, DRDO, and the Indian Air Force), Airlines and Aviation Companies, Research and Development Institutions (that conduct research and development in aerospace), Consulting Firms etc. Conclusion In conclusion, the field of aerospace offers vast opportunities for those passionate about innovation, technology and exploration. With specialized academic paths in Aerospace Engineering students can equip themselves with the knowledge and skills required to contribute to cutting-edge technologies. Whether it's pursuing research, design, or specialized roles, the aerospace domain promises a dynamic and rewarding career for future engineers and scientists. (The author is Professor- IIAEM, JAIN (Deemed- to-be University)
