Why Maglev Trains Don’t Touch the Tracks? @thescience71 How Maglev Hit 600 km/h? @thescience71

Why Maglev Trains Don't Touch the Tracks? How Maglev Trains Hit 600 km/h? @thescience71 How do Maglev trains run without touching the tracks? How do Maglev trains reach speeds of 600 km/h? 🚄⚡@thescience71 #Engineering #Science #Technology Learn how a 100-ton train, "flying" 10 millimeters above the ground, using only the power of magnets, achieves an incredible speed of 600 km/h—equivalent to almost half the speed of sound. In this in-depth engineering journey, we'll understand the science and logic behind high-speed Maglev trains. You'll see how these amazing trains eliminate conventional wheels altogether, reducing friction to almost zero and replacing them with superconducting magnets and a Null-Flux Coil System. We'll also learn about the extraordinary precision required to keep the track perfectly stable—from deep-piled foundations to hydraulic leveling systems that maintain micrometer-level accuracy. And finally, we'll answer that scary question: what would happen if the train lost all power at 600 km/h? Learn about the "Plan B" safety system, which generates its own emergency power using induction and activates the retractable landing gear, landing the train safely. In this video, you'll learn: ✅ How superconducting magnets create the powerful electromagnetic repulsion needed for levitation. ✅ The workings of a linear motor and its digital "push-pull" propulsion system. ✅ Why building high-speed rail guideways demands engineering similar to high-strength bridges. ✅ How a train generates its own emergency power in the event of a blackout, safely activating the landing wheels and carbon disc brakes. If you enjoy "Inside Explained"-style engineering videos like this and 3D breakdowns of the world's most complex machines, be sure to subscribe to the channel! Which aspect of maglev technology did you find most surprising—its speed of 600 km/h or its emergency landing system? Let us know in the comments below! 🚄✓ Discover how a 100-ton train can "fly" 10 millimeters above the ground at a staggering 600 km/h—nearly half the speed of sound—using nothing but the power of magnets. In this deep dive, we go Inside Engineering to break down the logic of high-speed Maglev trains. You’ll see how these wonders of magnetic levitation eliminate friction entirely, replacing traditional wheels with superconducting magnets and null-flux coil systems. We also explore the incredible precision required to keep the track stable, from deep-piled foundations to hydraulic leveling systems that maintain micrometer accuracy. Finally, we answer the terrifying question: what happens during a total power failure at top speed? Learn about the "Plan B" safety net that uses induction to power retractable landing gear, ensuring the train lands safely every time. In this video, you will learn: How superconducting magnets create the massive electromagnetic repulsion needed for levitation. The mechanics of the linear motor and its digital "push-pull" propulsion system. Why high-speed rail guideways require engineering similar to high-strength bridge construction. How the train generates its own emergency electricity to deploy landing wheels and carbon disc brakes during a blackout. If you're fascinated by this "Inside Explained" style of engineering and want to see more 3D breakdowns of the world's most complex machines, make sure to subscribe to the channel! Which part of Maglev technology surprised you the most—the speed or the emergency landing system? Let us know in the comments below! #Maglev #MaglevTrain #Engineering #Science #Technology #HighSpeedTrain #FutureTech #JapanMaglev #EngineeringExplained #InsideEngineering Maglev Train Magnetic Levitation 600 km/h train Japan Maglev High-Speed ​​Rail Superconducting Magnets Future Transportation Engineering Explained Science Documentary Technology Explained