Stefan Roschi reveals how motors are playing a critical role in the current Mars mission
Mars once had liquid water and an atmosphere – was there life too? To answer this fundamental question, NASA is sending the Perseverance rover, a robot of unparalleled complexity. The world will be watching live.
Mars missions may seem to be routine now, yet it’s still the case that only a few craft make it to the planet’s surface intact. The European Space Agency (ESA) had a painful demonstration of that in 2016 when its lander Schiaparelli smashed into pieces on the Red Planet. Nevertheless, US space agency NASA has already successfully brought four robotic vehicles to Mars in the past. And with the fifth rover Perseverance, which landed on Mars on February 18, 2021, history was made once again. For the first time, we on Earth were able to see live images of a Mars landing, supplied by high-resolution video cameras.
It will still take a while, however, before people land on Mars. This is why robots need to do the work for now, and Perseverance has quite a lot of it in store. She landed in the Jezero Crater, which was once filled with water, with the task of investigating whether the area was once habitable. At the same time, the rover will search for signs of earlier life, known as biosignatures. She is equipped with a variety of measuring instruments for this purpose.
Its third task is to pave the way for human missions with a technology demonstration: An instrument named MOXIE will extract oxygen from the small amount present in the Martian atmosphere. This technology would be crucial for human missions, as oxygen is not only required for breathing, but can also be used for making fuel.
The systems making the Perseverance rover’s mission possible
We now come to the fourth mission, the most spectacular and most technically demanding: Perseverance will take up to 30 soil samples, place them in individual vessels, seal the vessels and then finally deposit them at a suitable location so a later mission can collect the samples and bring them back to Earth. For scientists, it doesn’t get much better than this: getting clean samples from Mars and being able to investigate them here, with all the latest techniques available. As NASA puts it, these samples have the potential to tell us more about the basis and origin of life in our solar system.
Three systems have to work together seamlessly for the sampling to succeed. First, the big robotic arm at the front of the rover drills into the Martian rock and takes a core sample, which is then inserted into a carousel. The carousel takes the sample inside the rover. There, the third system takes over. It is another robotic arm, a much smaller one called SHA. This arm takes the sample from the carousel, moves it to the volume assessment and scanning stations, then to the sealing station, and finally into temporary storage – all autonomously.
This is where maxon comes in. Several BLDC motors are being used to handle the samples. Some of them are installed in the SHA robotic arm, which transports the samples from station to station; others are used when sealing the sample tubes and positioning them.
What else makes the Perseverance Rover?
Just like the more than 100 maxon drives that have previously done work on Mars, the Perseverance motors are based on standard catalogue products: specifically, nine brushless DC motors of the EC 32 flat type and one of the EC 20 flat type, in combination with a GP 22 UP planetary gearhead. Of course, modifications were required so that the drives could meet the high demands of the mission. Nevertheless, the basis of the drives is no different from the models that are used in all kinds of applications on Earth.
maxon’s engineers have modified and repeatedly tested the motors and gearheads for three years, working closely with the specialists at the Jet Propulsion Laboratory (JPL), which handles all unmanned missions for NASA. The space experts from Pasadena were frequent visitors at the Swiss headquarters of the electric motor experts. “We’ve learned a lot from this collaboration,” said Robin Phillips, head of the maxon SpaceLab. This can be seen specifically in higher quality standards and new test procedures and processes. “Customers from other industries, such as the medical sector, where requirements are often similar, also benefit from this know-how.”
Orders for space applications still only make up a small part, but they help to improve the quality of the products. And they naturally exert a special fascination on the employees involved. Or as Kathrin Tschersich, Head of Assembly Project Samples at maxon, puts it: “It makes me very proud to know that products that have passed through my hands are being used on Mars.”
Stefan Roschi is with maxon
