Massachusetts Institute of Technology (MIT) has shared that a part of his modelers work on another thought: flying plate which would one day have the option to explore the moon, a couple of room rocks, and other dull surfaces. According to reports from the MIT news association, the flying saucer will utilize the natural substance of the moon to float on the ground. Further assessment on focuses can bring unprecedented benefits, since it can explore the moon and different space rocks without obsessing about the surface state may be much safer for Rover.
The MIT idea can be conceivable on account of a few variables, for example, the absence of air in the moon and other air bodies. On account of openness to daylight, just as plasma around it, months and space rocks can fabricate an electric field. On account of this electric field that Rover can have MIT.
The moon surface charge is sufficiently able to drift dust more than 1 meter over the ground. MIT reports look at this in a static manner can make your hair stand up. MIT engineers are not quick to think about utilizing the static charge of the month – the thought was first investigated by NASA.
How would MIT’s “flying saucer” work?
NASA’s ideas differ slightly from the concept of MIT engineers are currently exploring. It involves using wilt gliders with mylar wings. When Mylar has the same charge as the surface of the moon, scientists believe that the two materials will reject each other, allowing gliders to drift. Even though the concept is good, there is one main disadvantage in it: it will only work with smaller asteroids, thus limiting the use of gliders. Large planetary bodies create a much stronger gravitational pull that will make MYlar gliders useless, because it will not be able to float in such conditions.
MIT flying saucer called overcoming the limitations. The plan is to use ionic power to drift vehicles up to 2 pounds on the moon and large asteroids. By using a small ion thruster that MIT refers to the “Ion-Liquid ion source”, the vehicle will get extra levitation. The ion beam will charge the disk while also increasing the natural static load of the surface.
Research has proven that the “flying saucer” could be realistic
The engineer team, consisting of Oliver Jia-Richards, Paulo Lozano, and Sebastian Hampl, tried to simulate the real world scenario and test their concepts at Lozano’s Lab. To see if the calculation they check out, they produce a hexagon test vehicle. It was very small, weighing only 60 grams, but the engineers tried to create a semi-loyal replica of the flying disk they had done.
Hexagonal vehicles have one ion thruster pointing up and four points down. After being made, it is placed in a vacuum room, above the aluminum surface. It was suspended on the surface through the use of two springs calibrated next to the tungsten stem.