⚡ The Future of Power is Guided, Not Gated.
For a century, magnetic systems have treated flux as something to resist, contain, or bleed away. FluxWorx takes the opposite view: magnetic energy is a resource—a medium that can be guided, shaped, and routed with intent.
Differential Flux Steering (DFS) is our "inventive step." Rather than using brute-force saturation to block magnetic fields—which generates massive heat and waste—we utilize the Magnetic Transistor effect. By applying a subtle "nudge" at the physics layer, we provide flux with a path of least reluctance, allowing it to move forward with zero "magnetic rebound".
💡 The Four Pillars of DFS
The Magnetic Transistor is the first practical device that steers magnetic flux with minimal loss. Instead of forcing the core toward saturation, the geometry guides flux along controlled, low-stress paths that reduce hysteresis and heating.
🧬 A Platform Technology:
The Magnetic Transistor & Diode The first practical device for proportional, linear control of magnetic flux. Like its electronic counterpart, our transistor manages flux with a "volume knob" effect, requiring only ~ 10% of the energy typically needed to control a field. It provides a smooth, cool, and undistorted magnetic response for any system.
4️⃣ The Four "Now" Applications for DFS
Data Center & Telecom Power (Low-Heat PSUs) As AI racks push toward hundreds of kilowatts, heat becomes the ultimate enemy. DFS integrates into the DC-DC stage as a controllable magnetic transfer element. By providing a "knob" to manage power stress, we reduce heat generation at the source, targeting up to a 30% reduction in cooling energy for hyperscale facilities.
Switched Reluctance Motor (SRM) Wave-Shaping We are turning the robust, "no rare earth" Switched Reluctance Motor into a true "Permanent Magnet Motor killer". By using DFS to actively shape the flux wave during phase transitions, we eliminate the torque ripple and acoustic noise that have historically held SR motors back. The result: peak efficiency without the cost or supply-chain risk of magnets.
"FluxOnic" Magnetic Computing A post-silicon logic paradigm where flux pathways—not electron charges—represent binary states. Flux-Onic logic is inherently immune to radiation and EMPs, making it the gold standard for aerospace and defense. Because there is no charge flow to probe, it offers a hardware-level security that is virtually unhackable.
Industrial motor drives (VFDs) in heavy industry are often pushed to their limits by harsh transients and the massive inductive "kickback" of large loads. By integrating Differential Flux Steering into the drive's output stage, we create a "magnetic buffer" that absorbs destructive voltage spikes and reduces the dV/dt stress that prematurely ages motor insulation. This results in ruggedized industrial drives that generate significantly less EMI and operate with higher reliability in the most demanding environments, such as mining and marine applications.
Validated by Physics Our architecture is not theoretical. Advanced FEA (Finite Element Analysis) modelling, and validation by 3 of the latest A.I. models, has confirmed the operational efficiency of DFS across multiple scales—from kilowatt-scale power cores to on-chip logic tracks.
Download our White Paper HERE