Forwarded from Doomsday Fitness (Brandon)
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💪💥✍ #doomsdayfitness
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Forwarded from Doomsday Fitness (Brandon)
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🏋️♀️💥 #doomsdayfitness
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Standby for ⚡ Electromagnetic Railgun Technology
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https://t.me/AzazelNews/975426
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https://t.me/AzazelNews/975426
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This class focuses on real-world railgun research, how the technology works, current programs, and limitations. It’s one of the most advanced electromagnetic weapon systems being studied today.
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This video explains the physics behind railguns and compares them with coilguns and other electromagnetic launch systems.
This video discusses experimental naval railguns and the enormous power systems needed to operate them.
What a Railgun Is
A railgun is an electromagnetic launcher that accelerates a metal projectile using electricity instead of gunpowder.
Basic concept:
1. Two parallel metal rails
2. A conductive projectile (armature) bridges them
3. A massive electric current flows through the rails
4. Magnetic force accelerates the projectile down the rails
Because of the extremely high current, railguns can launch projectiles at over 3 km/s, much faster than conventional artillery.
Instead of explosives, damage comes from pure kinetic energy.
A railgun is an electromagnetic launcher that accelerates a metal projectile using electricity instead of gunpowder.
Basic concept:
1. Two parallel metal rails
2. A conductive projectile (armature) bridges them
3. A massive electric current flows through the rails
4. Magnetic force accelerates the projectile down the rails
Because of the extremely high current, railguns can launch projectiles at over 3 km/s, much faster than conventional artillery.
Instead of explosives, damage comes from pure kinetic energy.
Where Railguns Are Currently Used
Railguns are not widely deployed yet. They exist mainly as experimental military systems.
Current Research / Testing
Countries experimenting with them include:
• United States
• Japan
• China
• European research labs
Example:
• Japan tested a 20-foot, ~8-ton naval railgun capable of hypersonic projectiles around Mach 6+.
Primary research uses:
• Naval artillery replacement
• Hypersonic projectile launch
• Missile interception experiments
• Experimental electromagnetic propulsion
Most programs remain prototype or experimental oroff world
Railguns are not widely deployed yet. They exist mainly as experimental military systems.
Current Research / Testing
Countries experimenting with them include:
• United States
• Japan
• China
• European research labs
Example:
• Japan tested a 20-foot, ~8-ton naval railgun capable of hypersonic projectiles around Mach 6+.
Primary research uses:
• Naval artillery replacement
• Hypersonic projectile launch
• Missile interception experiments
• Experimental electromagnetic propulsion
Most programs remain prototype or experimental or
Sizes of Railguns
Railguns vary dramatically in scale depending on purpose.
Small Laboratory Railguns
Typical size:
• 1–3 meters long
• used for physics experiments
• powered by large capacitor banks
Example research devices can accelerate small projectiles to ~2-2500 m/s.
Railguns vary dramatically in scale depending on purpose.
Small Laboratory Railguns
Typical size:
• 1–3 meters long
• used for physics experiments
• powered by large capacitor banks
Example research devices can accelerate small projectiles to ~2-2500 m/s.
Medium Research Railguns
Examples:
• University or military lab systems
• 3–6 meters long
• multi-megajoule energy systems
• projectile mass ~100–300 g
Examples:
• University or military lab systems
• 3–6 meters long
• multi-megajoule energy systems
• projectile mass ~100–300 g
Large Naval Railguns
Prototype naval systems:
• 6–20+ meter barrels
• projectile speeds Mach 6–7
• energy per shot ~20–30 megajoules
They require ship-scale electrical power systems.
Prototype naval systems:
• 6–20+ meter barrels
• projectile speeds Mach 6–7
• energy per shot ~20–30 megajoules
They require ship-scale electrical power systems.