A car phone mount has to do three jobs at once: hold the phone firmly over every pothole, let the driver take it off one-handed without fumbling, and seat it the same way every time so the charging coil and the view line up. The conventional way to get all three is to stack up parts.
The conventional approach — and why it's a pain
Most mounts solve this with three separate mechanisms:
- A spring clamp or arms for holding force,
- A detent or latch so it doesn't rattle loose,
- An alignment feature — a cradle, ribs, or a keyed shape — so it seats consistently.
Every one of those is more parts, more tolerance stack, more cost, and more to go wrong. And the "feel" — how hard it grabs, how it lets go — is whatever the springs happen to give you, not something you actually tuned.
The one-part version
A twist-release programmable magnet does all three jobs by itself. Instead of a single North face and South face, a programmable magnet (a "Polymagnet") has many small poles — maxels — printed onto one face in a coded pattern. When two matching faces meet, their fields add up when the codes align and cancel when they don't.
So you get this behavior from a passive part with no moving pieces:
- Seated (0°): the codes line up, the fields reinforce, and the phone is held firmly.
- Self-aligning: the same pattern pulls the phone into that one seated orientation — it clicks to the right spot on its own.
- Twist to release (~20°): rotate the phone a small amount and the codes go out of correlation, the holding force collapses, and it comes off cleanly in one hand.
Three mechanisms — hold, align, release — collapse into one component you can drop into the design.
Two properties that make it better, not just simpler
It's stronger where it counts. Because the North and South maxels sit next to each other on the same face, the flux takes short loops right at the surface instead of arcing out to a far pole. That concentrates the field in the near gap — on sheet metal, holding force can reach up to about 4× a conventional magnet of the same size (the exact multiplier depends on the design and test).
Its field is short-range — and that's a feature. The concentrated flux also falls off fast: it's near zero within about a quarter inch. For a phone mount that means far less stray field to interfere with the phone's compass, wireless charging, or a credit card in the same pocket — a real problem with strong conventional magnets.
What to specify
| Function family | Twist-Release (with optional detent at the seated position) |
| Pattern | Coded so force peaks at 0° and releases near ~20° rotation |
| Pairing | A matched pair — one on the mount, one on the phone plate |
| Air gap | Tune holding force vs. gap for your case thickness |
| Material | NdFeB (e.g. N50), Ni-Cu-Ni plated; standard grade to 60°C |
| Stray field | Near-zero beyond ~¼″ — safe near electronics |
Note: force ratings in lb/N are design-specific — request the force curve for your chosen pattern rather than assuming a fixed number.
How to prototype it in an afternoon
- Feel it first. A demo kit has the twist-release behavior in your hand — it's the fastest way to convince yourself and your team it's real.
- Pick or tune the pattern. Start from a standard twist-release part, or place the maxels yourself in the design software to dial in the hold force and release angle.
- Print and test. A patterned magnet is produced by re-magnetizing standard magnet stock — a prototype in days, then straight to volume.
This is the same class of behavior — a self-aligning magnet with a tuned release — that engineers reach for in magnetic latch design, connector alignment, and 2-in-1 laptop hinges. The phone mount is just the clearest place to see all three jobs done by one part.
Try the twist-release yourself
The behavior is hard to believe until it's in your hand. Order a demo kit, design your pattern, or talk to an application engineer about a custom force curve for your project.
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