Weather still a factor: Last call on Shubhanshu Shukla's Axiom-4 launch early today
CAPE CANAVERAL (FLORIDA): The rescheduled launch of Shubhanshu Shukla-piloted Axiom-4 mission remained unchanged at 5.30pm IST on Wednesday after a 'weather call' taken at Kennedy Space Centre on Tuesday (8pm IST). However, the weather continues to be a key variable as the stakeholders will take a final call after the 'L-8 hour
weather briefing
', scheduled around midnight in US (around 10am IST).
At the mission readiness review briefing, Jimmy Taeger, launch weather officer with 45th Weather Squadron of US Space Force, said conditions across central Florida is being shaped by a high-pressure system to the southeast. The system is expected to move north in the coming days, which could shift the winds and bring in scattered showers. While wind conditions are projected to improve mid-week, forecasters are keeping a close eye on the risk of passing showers, especially as launch windows approach. "Though winds are likely to improve, Wednesday looks better, and Thursday even better. The one thing we are going to be watching closely is the possibility of showers moving into the area," Taeger said.
Liquid oxygen leak detected during fire test on Falcon-9
William Gerstenmaier, SpaceX vice-president, build and flight reliability, stressed on the company's continued focus on safety and precision, noting that "space flight is really hard, and we're learning every day". During a static fire test of the Falcon-9, SpaceX engineers discovered a liquid oxygen leak that had initially gone undetected during the booster's post-flight refurbishment. "We discovered that we had not fully repaired the booster ... we're installing a purge that will essentially mitigate the leak if it continues," he said.
In addition, a thrust vector control issue with engine five was also identified. The affected components have since been replaced.
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As a precaution, SpaceX, the company which owns and operates Falcon 9, has paused the launch to repair the issue and conduct additional tests before setting a new launch DOES LOX DO IN ROCKETS?To understand what went wrong, it is important to know the role of LOX in rocket launches. Rockets need two main components to create the thrust needed to escape Earth's gravity: a fuel and an fuel provides the energy, while the oxidizer enables it to burn. On Earth, oxygen from the atmosphere acts as the oxidizer in everyday in space or even higher altitudes, where there is less or no air, rockets must carry their own source of is where LOX comes acts as the oxidizer and is combined with fuels like kerosene, liquid hydrogen, or methane in the rocket's engine. When ignited, the fuel and LOX burn together at very high temperatures and pressure, creating the powerful thrust that pushes the rocket into space. 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He is an author and an IIM Ahmedabad graduate, who was the Advisor for Policy and Technology to Dr. APJ Abdul Kalam, 11th President of India.)Tune InTrending Reel
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Home News India's second son in space: Shubhanshu Shukla's historic journey to the ISS India's second son in space: Shubhanshu Shukla's historic journey to the ISS The Falcon 9 rocket, a creation of Elon Musk's SpaceX, is a partially reusable launch vehicle. Its components can be recovered and reused for subsequent missions, making space travel more sustainable. India's second son in space: Shubhanshu Shukla's historic journey to the ISS The upcoming Axiom-4 mission to the International Space Station (ISS) marks a pivotal moment for India, as Shubhanshu Shukla is set to become only the second Indian to venture into space. The mission, initially slated for Wednesday from NASA's Kennedy Space Center, has been temporarily delayed due to a technical issue. This important flight will carry a crew of four astronauts: Peggy Whitson (United States), Shubhanshu Shukla (India), Slawosz Uznanski-Wisniewski (Poland), and Tibor Kapu (Hungary), aboard SpaceX's Crew Dragon spacecraft, propelled by a Falcon 9 rocket. As reported by The Indian Express, this delay is due to a 'technical snag' with the SpaceX rocket. Mastering the Launch Window Before any space launch, scientists meticulously determine a 'launch window' – a precise timeframe during which the rocket must lift off to efficiently and safely reach its destination, whether the ISS, the Moon, or Mars. This careful planning is crucial because all celestial bodies, including Earth, the Moon, and the ISS, are in constant motion. Rockets cannot simply launch at any moment; scientists must calculate the exact timing for the spacecraft to follow a precise trajectory and intercept its target, a process known as 'celestial alignment.' Consider it like catching a moving train: arriving too early or too late means you miss it. Similarly, rockets must launch at the perfect instant to 'catch' the ISS as both orbit Earth. The Orbital Dance to the ISS A spacecraft doesn't fly directly to the ISS. Instead, it first enters orbit around Earth, circling the planet multiple times. This gradual approach allows it to progressively match the ISS's orbit, conserving substantial fuel – a critical factor for mission success and cost-effectiveness. Attempting a direct, straight-line flight to the ISS would necessitate constant acceleration against gravity, consuming an immense amount of fuel. Imagine cycling straight up a steep hill – it's arduous and energy-intensive. A winding path with gentler turns, however, allows for easier ascent with less energy expended. Similarly, spacecraft follow a curved trajectory after reaching a certain height and speed, smoothly transitioning into orbit and conserving energy far more efficiently than a straight ascent. The Falcon 9 and Dragon Capsule: Powering the Journey The Falcon 9 rocket, a creation of Elon Musk's SpaceX, is a partially reusable launch vehicle. Its components can be recovered and reused for subsequent missions, making space travel more sustainable. Falcon 9 is employed to deploy satellites, deliver supplies, and transport the Dragon spacecraft into space, primarily for missions to low Earth orbit (up to 2,000 kilometers above Earth), but capable of reaching farther distances when required. The rocket comprises two main sections, or stages: First Stage (Booster): Equipped with nine powerful Merlin engines and tanks filled with liquid oxygen and rocket-grade kerosene, this stage provides the immense thrust needed for liftoff and initial ascent into space. After its role is complete, it separates, returns to Earth, and lands upright for reuse. Equipped with nine powerful Merlin engines and tanks filled with liquid oxygen and rocket-grade kerosene, this stage provides the immense thrust needed for liftoff and initial ascent into space. After its role is complete, it separates, returns to Earth, and lands upright for reuse. Second Stage: This section features a single Merlin engine. Once the first stage separates, the second stage propels the spacecraft further into space. Upon achieving the correct altitude and speed, the Dragon capsule detaches and continues its journey autonomously. Dragon's Intricate Path to the ISS The International Space Station orbits Earth at an approximate altitude of 400 kilometers and a remarkable speed of around 28,000 kilometers per hour. Due to this high velocity, the Dragon spacecraft cannot simply travel directly to it. Instead, after reaching space, Dragon systematically raises its altitude and adjusts its trajectory to synchronize with that of the ISS. To achieve this, the spacecraft executes a series of 'phasing maneuvers.' These are minor, calculated changes in its orbit that help it align with the ISS. Dragon accomplishes this using 16 small engines called Draco thrusters, each generating approximately 0.4 kilonewtons of force, providing precise pushes to guide the spacecraft. The Timing Difference: Dragon vs. Soyuz The Dragon spacecraft typically takes around 28 hours to reach the ISS from launch. In contrast, Russia's Soyuz spacecraft can complete the same journey in a mere eight hours. This difference stems from their distinct flight plans, which are dictated by their design and capabilities. Dragon is a relatively newer spacecraft, having first launched in 2012, while Soyuz has been operational since the 1960s. As a newer vehicle, Dragon necessitates more testing and fine-tuning. SpaceX is continuously working to optimize its launch timing and orbital paths through complex mathematical models, with the aim of reducing the journey duration in the future. Why Dragon's Journey Takes Longer Given that Dragon is still undergoing refinement, astronauts on board spend additional time verifying its systems. They also gather crucial in-flight data, which is transmitted back to Earth for engineers to essential safety and performance checks are part of the detailed preparations that The Indian Express highlighted regarding the mission's comprehensive approach. These checks contribute to the longer travel time compared to older spacecraft like Soyuz, which no longer require such detailed scrutiny. The Precision of Docking As the Dragon capsule nears the ISS, it first establishes communication with the space station. It then performs a final positioning maneuver and enters an invisible 'keep-out sphere' around the ISS, approximately 200 meters wide. Within this safety zone, the spacecraft meticulously aligns itself with the docking port. At this stage, Dragon activates its autonomous docking system. Utilizing GPS, cameras, and imaging sensors like Lidar (which employs lasers to measure distance), the spacecraft feeds data to its onboard computer. The computer processes this information to precisely calculate how and when to fire the Draco thrusters, enabling the capsule to move slowly and accurately towards the ISS. Despite both Dragon and the ISS moving at extremely high speeds, their relative speed to each other is nearly zero, making docking feasible. While most docking is performed automatically, astronauts onboard Dragon can assume manual control if necessary. Types of Thrusters Used: Draco Thrusters (16): Used for changing direction, controlling movement, and docking. Used for changing direction, controlling movement, and docking. SuperDraco Thrusters (8): These are significantly more powerful and are reserved for emergencies, such as propelling the capsule away from the rocket in the event of a launch failure. Post-Docking: Entry to the ISS Once the Dragon capsule docks with the ISS, immediate entry for the crew is not possible. The spacecraft remains connected for one to two hours to allow for stabilization and safety checks. Engineers ensure that pressure levels are equalized and that there are no leaks between the two vehicles. Only after these comprehensive checks are completed do the astronauts open the transfer gates and move into the International Space Station to commence their mission. (Girish Linganna is an award-winning science communicator and a Defence, Aerospace & Geopolitical Analyst. He is the Managing Director of ADD Engineering Components India Pvt. Ltd., a subsidiary of ADD Engineering GmbH, Germany. Contact: girishlinganna@ For breaking news and live news updates, like us on Facebook or follow us on Twitter and Instagram. Read more on Latest India News on More Stories
