DF.01
Dual Flux Topology
A radial machine architecture that channels two coupled flux paths to deliver torque density beyond conventional PMSMs, without sacrificing thermal headroom.
Technology
A new flux geometry for the modern electric motor.
Our architecture re-thinks the relationship between flux paths, mass and thermal capacity — delivering powertrains engineered for real-world performance, not bench specifications.
Architecture
Two flux paths. One coherent machine.
The Talos dual-flux radial topology decouples the conventional torque-mass-temperature trilemma. By splitting flux contributions across complementary paths, we extract more usable torque from the same envelope, with thermal headroom retained for sustained duty.
- Higher continuous torque density
- Improved efficiency at part-load
- Better fault-tolerance modes
- Reduced rare-earth dependency
Section · A-AScale · 1:2
Pillars
Engineered across the full discipline stack.
DF.02
Thermal Strategy
Oil-cooled rotors, optimised slot fill and CFD-validated jackets sustain peak performance through full-cycle duty without derating.
DF.03
Mechanical Integrity
High-speed rotor design validated for motorsport and aerospace duty cycles, with margin engineered against safety-critical envelopes.
DF.04
Manufacturability
Designed for repeatable production. Tolerancing, lamination and winding strategies tuned for cost-effective scale.
Software · NeurotorQ
Design exploration, compressed.
NeurotorQ is our in-house design platform — a multi-physics environment that fuses electromagnetic, thermal and mechanical models with a multi-objective optimiser. It compresses what was previously weeks of iteration into hours, surfacing the Pareto front of viable machines for any programme.
Request a demoNeurotorQ · Pareto Explorer
Iterations
12,480
Front size
34
Δ Mass
−18%
Run · 0xA4F1Status · Converged
Reference
QRM-2 reference specification.
- Peak power
- 380kW
- Peak torque
- 520Nm
- Max speed
- 24krpm
- Active mass
- 38kg
The QRM-2 demonstrator is a reference design, not a product. Programme-specific machines are derived through NeurotorQ against the targets, envelope and duty cycle of each engagement.