#Copper Rocket Engine

This rocket engine wasn't designed by humans, but by AI. It was created using Noyron, a physics based engineering AI built by LEAP 71. Instead of learning from past designs, it uses real physics, thermodynamics, and manufacturing rules to generate engines directly from requirements. The aerospike engine was 3D printed as a single copper piece and hot fire tested with liquid oxygen and kerosene. Inside it burns at extreme temperatures, while the outside stays cold enough to form frost during operation. Each test feeds back into the system, making the next design better. 🎥: @integza What are your thoughts on this? 🤔💬

Chilling our 20 kN Aerospike rocket engine before the hot fire today. This engine runs on liquid methane and LOX and was generated entirely without human intervention by the Noyron Large Computational Engineering Model. We run these tests to collect important data that feed back into Noyron’s algorithms.

Meet NΞURON — an algorithm that designs rocket engines without training data. 🚀🧠 No datasets. No guesswork. Just physics, thermodynamics, and engineering laws. From blank space to a working engine. This aerospike was 3D-printed in one copper piece. Cooled by liquid oxygen and kerosene. 3,000°C inside — frost forming outside. Green flames? Copper learning the hard way. Built by Leap71. Where every test improves the next design. The future of engineering just ignited. #rocketscience #engineering #spacetech #aerospace #3dprinting futuretech innovation deeplearning aiengineering physics startuplife fyp1

AI Made A Rocket Engine In 2 Weeks. LEAP 71, a Dubai-based AI engineering company, successfully tested a liquid rocket engine designed autonomously using their Noyron computational model. The engine, 3D-printed in copper, achieved 5 kN of thrust and completed multiple tests, including a long-duration burn. It was hot-fired at a UK test stand, validating LEAP 71's computational engineering approach, which accelerates design timelines from months to under two weeks. Co-founders Josefine Lissner and Lin Kayser highlighted how this innovation could revolutionize space propulsion by reducing costs and increasing accessibility. The engine, fueled by cryogenic liquid oxygen and kerosene, remained fully functional after testing. LEAP 71 partnered with the University of Sheffield and AMCM for production and post-processing. Data from the test will enhance future engine designs, and the company aims to commercialize these rocket engines globally. Follow @gameoftomorrow for more innovation news. #futuretech #ainews #leap71 #noyon #innovation

This rocket engine wasn’t designed the traditional way. It was computed. Built using NEURON, a physics-based engineering system by LEAP 71 — no datasets, no templates, no guesswork. Just fluid dynamics, thermodynamics, and combustion physics encoded into math. 🚀 Aerospike engine 🟠 3D-printed in one piece of copper 🔥 ~3000°C combustion ❄️ Cryogenic cooling so cold it frosts while firing This isn’t AI “imagining” hardware. It’s deterministic physics doing engineering — faster and cleaner. Not designed. Computed.

Our contribution to #UAENationalDay fireworks - the Emirates’ first #MethaLOX rocket engine. 20 kN (2 tons), 50 bar chamber pressure. First test campaign just completed. Designed by the #Noyron Large Computational Engineering Model without human intervention.

Double Regen Cooling 20kN Aerospike Engine

Turn up the volume for the sound of 20,000 horsepowers. The first liquid rocket engine made in @dubai - test fired this weekend in the UK. Created through @noyron.ai , our Large Computational Engineering Model. The first #AI designed rocket engine. 5kN, cryogenic Liquid Oxygen and Kerosene as propellants. #3dprinted from #copper. #ComputationalEngineering

This isn’t AI assisting engineers. This is AI being the engineer. The rocket engine you’re seeing was autonomously designed by a computational system developed by LEAP 71, using pure physics, constraints, and performance goals - no traditional CAD workflows, no manual drafting. The result: a 20 kN aerospike rocket engine, 3D-printed in a single copper piece, that fired successfully during real-world tests. Once the system learns from a test, new design iterations can be generated in minutes - not months. Inside, temperatures reach nearly 3,000°C. Outside, liquid oxygen at –183°C keeps the engine so cold it forms frost while running at full power. Those green flames? That’s copper burning - a design side effect that taught the AI how to improve its next version. This is a glimpse of a future where machines don’t just simulate reality - they build it. Credit: Joel Gomes AI & Tech Used: • LEAP 71 “Noyron” computational engineering system • Physics-driven autonomous design • Metal 3D printing + hot-fire testing Follow @aimanipulation for daily breakthroughs in AI creativity and future tech. #AI #SpaceTech #RocketEngine #Aerospike #AIEngineering 3DPrinting LEAP71 Noyron FutureOfEngineering GenAI AIVideo AImanipulation

This rocket engine wasn’t sketched, tuned, or optimized by humans. It was designed by AI directly from the laws of physics. The engine is LEAP 71’s NEURON 20 kN aerospike, recently showcased by Intezga. Instead of engineers modeling parts in CAD, LEAP 71 uses a computational AI system that encodes thermodynamics, fluid dynamics, combustion physics, material limits, and manufacturing constraints. Given a performance target, the system generates a complete engine geometry on its own. The entire engine is 3D-printed as a single copper piece, enabling intricate internal cooling channels that traditional machining can’t produce. Inside the chamber, temperatures exceed 3,000 °C, while liquid oxygen at −183 °C flows through the walls for regenerative cooling, cold enough to form frost on the exterior during full-power firing. That green flame during tests isn’t for show. It’s burning copper vapor from localized erosion. The data feeds straight back into the AI, letting the next design iteration improve automatically. Once trained, the system can generate a new engine design in about 15 minutes, a process that normally takes months or years. This is a true aerospike engine, efficient across different altitudes, a concept long considered too complex to manufacture reliably. It fired successfully on its first real-world test. This isn’t AI assisting engineers. It’s AI becoming the engineer, learning from physics, manufacturing reality, and live test data, and redefining how rockets may be built. 🎥: @integza Follow @airesearches to stay updated on the world's most fascinating AI developments.

Meet NΞURON, an algorithm that uses physics and engineering rules (not training data) to design fully functional rocket engines from scratch. This aerospike engine was 3D-printed in ONE piece from copper Uses BOTH super-cold liquid oxygen (-183°C) AND kerosene for cooling Burns at 3,000°C - hot enough to melt steel So cold on the outside it creates frost while running Green flames = copper burning (oops, but that's how you learn!) Every test makes the next design better Created by Leap71 - a software engineer and aerospace engineer who fell in love and built an algorithm that's revolutionizing rocket design. The future of engineering is here! Credit: @integza 👉If you want more the freshest Tech/AI news and insights then please, follow for more! [email protected] 👉Subscribe for newsletter to stay ahead what's going on in AI world - starai.beehiiv.com Links in bio and stories!👆

AI designed LEAP 71’s NEURON aerospike rocket engine by itself. It was 3D-printed as one solid copper piece and worked on the very first test. After learning, new designs take only 15 minutes. Inside, it burns at 3,000°C while super-cold liquid oxygen at −183°C cools it. Frost forms while it fires. Green flames came from burning copper and taught the AI. This isn’t AI assisting engineers. It is the engineer. The future just fired. Follow aicontroled for more Tech related videos! Source: Joel Games