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How does one go about massaging the opposition between like magnetic fields
ChatGPT said:
Massaging the opposition between like magnetic fields—meaning two north poles or two south poles repelling each other—is less about overcoming the physical repulsion and more about managing or manipulating it through creative design or physics-informed engineering. Here’s how one can approach it, depending on the context:
1. Magnetic Shielding or Redirection
You can't cancel a magnetic field, but you can redirect it. Materials like mu-metal or other high-permeability alloys can help channel magnetic lines of force, allowing you to mitigate repulsion at specific points.
Use case: In magnetic levitation or containment systems.
Goal: To avoid direct face-to-face repulsion while maintaining proximity.
2. Angular Alignment (Tilted Interaction)
Instead of placing like poles directly facing each other, tilting the magnets can reduce the direct repulsive force and sometimes introduce a component of torque that can be managed or exploited (e.g., in magnetic bearings or motors).
Use case: In rotational devices or precision tools.
Goal: Harness side components of the field instead of frontal repulsion.
3. Distance Damping with Intermediate Media
Inserting non-magnetic but structural spacers can maintain a set distance between like poles and dampen the repulsion's effect while allowing the field interaction to persist in a controlled way.
Use case: In magnetic suspension systems or vibration damping.
Goal: Controlled repulsion for cushioning or stabilization.
4. Dynamic Control via Electromagnets
If you're using electromagnets rather than permanent magnets, you can adjust the field strength or even switch polarity dynamically, giving you full control over repulsion and attraction on demand.
Use case: Magnetic actuators, maglev systems.
Goal: Tunable repulsion for dynamic environments.
5. Superconducting Levitation (Meissner Effect)
Superconductors can "repel" magnetic fields in a different way, leading to quantum locking and stable levitation without the need to massage the opposition directly.
Use case: Quantum transport, frictionless bearings.
Goal: Harnessing repulsion as a stable, useful force.
Would you like help with a specific application, like magnetic levitation or energy storage?
You said:
How do I reproduce the redirection of magnetic fields in the Kunel patent?
ChatGPT said:
To reproduce the magnetic field redirection described in Heinrich Kunel's 1982 patent (DE3024814), you'll need to construct a system that manipulates the magnetic flux from permanent magnets without mechanical motion. Kunel's design utilizes a combination of permanent magnets, soft magnetic cores, and alternating current (AC) coils to induce a temporally variable magnetic flux, which in turn generates an electric current.
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Key Components and Setup
Permanent Magnet Block: A permanent magnet serves as the primary source of magnetic flux.
Soft Magnetic Core: An iron core (e.g., made of dynamo iron, pure iron, or amorphous iron) is connected to one or both poles of the permanent magnet. This core channels the magnetic flux.
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Induction Coil: A coil is wound around the core. The number of turns and the conductor's cross-sectional area should match those of the circuit breaker coil to ensure efficient induction.
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Circuit Breaker Coil: An AC coil is placed adjacent to the magnet block. The alternating current in this coil creates a time-varying magnetic field that modulates the flux through the core.
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Air Gap: An air gap is introduced between the core and the magnet block. This gap acts as a "gate" or "circuit breaker" for the magnetic flux, allowing for its temporal modification.
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Operational Principle
When the AC current flows through the circuit breaker coil, it alternately directs the induced magnetic flux toward and away from the core.
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This modulation of the magnetic flux induces a pulsating direct current in the induction coil.
The frequency of the AC current determines the rate of flux modulation, and consequently, the frequency of the induced current.
Practical Considerations
Core Material: Use materials with low core losses to minimize energy dissipation.
Coil Design: Ensure that the induction coil has a sufficient number of turns and appropriate wire gauge to handle the induced current.
Frequency Control: Adjust the frequency of the AC supply to control the characteristics of the induced current.
Safety: Implement proper insulation and safety measures to handle the generated currents and voltages.
For a detailed schematic and further insights into Kunel's design, refer to the translated patent document
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Topic: Kunel and ChatGPT (Read 3982 times)
