Noyron — a foundational
Large Computational Engineering Model

Noyron is LEAP 71’s foundational computational model for engineering. It encodes expert domain knowledge and logic, physics, such as thermal models, rules about manufacturing processes, and related data in one coherent framework for general engineering.

Noyron is proprietary software, developed by LEAP 71. It constantly grows in capability with every insight gained from designing and manufacturing highly elaborate machinery.

Noyron relies on PicoGK our open-source kernel for the robust creation of complex geometry.

Noyron forms the basis of several more specialized Computational Engineering Models (CEM) created by LEAP 71, among them, Noyron RP for rocket motors, Noyron EA for electromagnetic actuation and locomotion, and Noyron HX for heat exchanger design.

PicoGK screenshot of a heat exchanger (CC BY-SA)

Beyond geometry

One of the key outputs of a Computational Engineering Model (CEM), is the geometry of the generated object.

Noyron, however, also attempts to comprehensively predict the performance of the result.

Given a set of input parameters, Noyron will build a design expected to perform correctly. To achieve this, the Computational Engineering Model attempts to accurately infer physical interactions, including mechanical movements, thermal behavior, and other performance parameters.

Like a human engineer, Noyron aims to build an object that closely matches the desired functionality, based on distilled expert knowledge. The observed behavior, whether from real-world tests or simulations, is then fed back into Noyron to continuously improve the system for future iterations, thus aligning the Computational Engineering Model more closely with reality.

Noyron generates output geometry, manufacturing process parameters and files (such as post processing paths and guide geometry), a summary of predicted performance parameters, numerical fields and physical data for direct transfer to simulation systems.

Noyron is under constant development and training.

Explore

Rocket engines are powerful - this small thruster can lift the weight of a horse into the air by the sheer power of its exhaust - producing the power of 20,000 horses in the process.

#cnn today

Proud parents before the test fire. @josefinelissner is holding up the connector end of the coaxial swirl injector head. @lin_kayser is holding the @noyron.ai TKL-5 copper combustion chamber. Together they form the entire thruster.

Big thank you to @eos3dprinting sister company #AMCM for the excellent #3dprint in #copper (CuCrZr). The thruster withstood everything we threw at it.

Before the storm. @noyron.ai TKL-5 thruster.

Looking at the coaxial swirlers which mix the liquid oxygen and kerosene before combustion.

#coaxialswirl injector head of our @noyron.ai thruster before assembly.

#startmeup

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

Frozen engine before our hot fire.

Nothing more satisfying than seeing things coming together.

#ComputationalEngineering allows us to build better electric motors with complex coil shapes and internal cooling channels which support higher currents.

Taking some inspiration from Gerald O’Neill’s classic book.

This transparent view of a helix heat exchanger created through #ComputationalEngineering shows the intricate internal structures. The @picogk source code for the generation of this model is available on our GitHub.

Multimaterial #3dprinting allows us to build #electricmotors with complex coil geometries, shaping the magnetic field for higher efficiency. This one was printed using the @fraunhofer.igcv dual metal process on a @nikonslmsolutions machine

We just added a downloadable models section to our website. Download an STL and #3dprint it. leap71.com/downloads - more models coming soon!

1 kN vacuum thruster designed with Noyron RP, our #ComputationalEngineering Model for space propulsion systems. Built on @picogk, our #opensource geometry kernel.

Detail of an injector head designed using Noyron RP on @picogk

@aconity3d printed one of our heat exchangers in #copper. Here it is in all its glory. #ComputationalEngineering

Test #3dprint of a #multimaterial stator for an #axialflux #electricmotor. Designed through our #ComputationalEngineering Model @noyron.ai and built on @picogk our #opensource geometry kernel.

Regeneratively cooled nozzle extension for a vacuum-optimized #rocket #thruster designed with Noyron RP, our #ComputationalEngineering Model for space propulsion.

Introducing Noyron - our Large Computational Engineering Model, which distills all the knowledge we have codified into rules and algorithms over the past year. Noyron allows us to build complex products, rooted in engineering logic, physics, and manufacturing experience. Noyron lies at the root of all our bespoke customer projects and forms the basis of more specialized #ComputationalEngineering Models for fields like space propulsion and electric mobility.

#ctscan of one of our #3dprinted #rocket injector heads, designed through #ComputationalEngineering. Printed by @aconity3d and analyzed by @visiconsult

Family picture of a 1kN and 5kN rocket thruster generated through our #ComputationalEngineering Model for space propulsion.