With more fuel, fail-safe measures, Chandrayaan-3 to leap towards moon on July 14 – NSP NEWS

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 The Launch Vehicle Mark-III (LVM3) M4 vehicle with Chandrayaan-3 being moved to the launch pad at Satish Dhawan Space Centre, in Sriharikota. File.

The Launch Vehicle Mark-III (LVM3) M4 vehicle with Chandrayaan-3 being moved to the launch pad at Satish Dhawan Space Centre, in Sriharikota. File.
| Photo Credit: PTI

India’s third lunar mission, set for launch on July 14, is loaded with more fuel, a slew of safety measures and a bigger landing site, with ISRO saying it has opted for a “failure-based design” for the second attempt to ensure that the rover successfully lands on the moon even if some things go wrong.

Chandrayaan-3, set for lift-off at 2:35 pm on July 14, will be a follow-up mission after the crash-landing of Chandrayaan-2 in September 2019 due to a software glitch.

Indian Space Research Organisation (ISRO) Chairman S. Somanath on Monday said instead of a success-based design in Chandrayaan-2, the space agency opted for a failure-based design in Chandrayaan-3, focused on what all can fail and how to protect it and ensure a successful landing.

“We looked at very many failures — sensor failure, engine failure, algorithm failure, calculation failure. So, whatever the failure we want it to land at the required speed and rate.

“So, there are different failure scenarios calculated and programmed inside,” he said.

The ISRO chief shared minute details about what went wrong with the Vikram lander of Chandrayaan-2 as it went hurtling down towards the identified 500m x 500 m landing spot on the lunar surface with the engines designed to reduce its velocity developing higher thrust than expected.

“The primary issues were, one we had five engines which were used to give the reduction of the velocity, which is called the retardation. These engines developed higher thrust than what was expected,” he told reporters here on the sidelines of India Space Congress organised by SIA India.

Somanath said that when such a higher thrust was happening, the errors on account of this differential were accumulated over some period.

“All the errors got accumulated, which was on the higher side than what we had expected. The craft had to make very fast turns. When it started to turn very fast, its ability to turn was limited by the software because we never expected such high rates to come. This was the second issue,” the ISRO chief said.

He said the third reason for failure was the small 500m x 500m site identified for landing the spacecraft.

“The craft was trying to reach there by increasing the velocity. It was almost close to the ground and kept on increasing the velocity,” Mr. Somanath said.

In a nutshell, the problem in Chandrayaan -2 was that the ability to handle parameter dispersion was very limited, he said.

“So, what we did this time was to simply expand that further, look at what are things that can go wrong. So, instead of a success-based design in Chandrayaan-2, we are doing a failure-based design in Chandrayaan-3. What all can fail, and how to protect it. This is the approach we have taken,” Mr. Somanath said.

“We expanded the area of landing from 500m x 500m to four km by 2.5 km. It can land anywhere, so it doesn’t limit you to target a specific point. It will target a specific point only in nominal conditions. So, if the performance is poor, it can land anywhere within that area,” Mr. Somanath said.

He said the Chandrayaan-3 also has more fuel so it has more capability to travel or handle dispersion or move to an alternate landing site.

The ISRO chief said the Vikram lander now has additional solar panels on other surfaces to ensure that it generates power no matter how it lands.

“We asked if it lands with higher velocity, what will happen? Can it not land? Then we increased the vertical velocity component from 2 m/s to 3 m/s and tested it totally,” he said.

The spacecraft was also tested for the ability to withstand vibrations by flying it over different terrains using a helicopter, while cranes were used to test the landing processes, he said.

“We did new test beds for simulation, which was not there last time. This was to look at failure scenarios,” Mr. Somanath said.


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