So: jouncing over the larg(er) potholes / pavement discontinuities / debris on the roads around here wobbulates the front fender enough to pull the stays out of those tidy 18 mm = 6 diameter deep sockets on the fender clip.

Perhaps a generous application of heatshrink tubing will help:

Tour Easy Front Fender Clip – heatshrink hack

Waving a heat gun around a 3D printed part seems fraught with peril, even with PETG’s glass transition temperature around 80 °C = 175 °F, as ordinary polyolefin tubing shrinks at 140-ish °C. Aiming the hot air stream more-or-less away from the clip (and the tire!) carried the day. PLA would surely have gotten bendy.

The proper solution surely involves screw clamps and suchlike. I really dislike fiddly hardware: I hope this hack survives.

We rode the Feeder Canal trail during a recent bike vacation in exotic Glens Falls NY:

Feeder Canal Park Trail – Branches

The numerous downed branches along the trail and countless twigs on the trail came from a brush-clearing operation:

Feeder Canal Park Trail – Brush Clearing

As luck would have it, a twig snagged between my front tire and fender, snapping the clips holding the fender in place:

Tour Easy front fender mount breakage

Should it not be obvious, each ferrule formerly had two parallel jaws (on the left) gripping the fender, with the tiny screw digging into the fender. I affixed the fender to the broken clips with copious amounts of duct tape and we continued the mission.

It should be obvious why those ferrules are not suitable for 3D printing.

However, with the recent rear fender clip serving as inspiration, this didn’t take long:

Tour Easy – Front Fender Clip – Slic3r

The front fender fits a 20 inch wheel and is somewhat wider and flatter than the rear fender (I think they bent the same plastic strip around a smaller mandrel), so I did a quick copy-and-paste hack job on the OpenSCAD source code, rather than trying to parameterize the daylights out of the previous model.

The posts around the wire stays are 6 diameters deep and reamed to fit; the stays won’t be flopping around even without fiddly mechanical hardware retaining them. The holes extend about halfway into those posts to mimic the dimensions of the original ferrules.

All of us can predict where the next break will occur, right? That’s OK: I want this to break, instead of wrecking the fender, so the only question is how much abuse those simple joints can withstand. The printing orientation wraps the perimeter threads from the posts around the clip, making it about a strong as it can be.

The ferrules should splay outward by a few degrees to match the angle from the fender to the fork eyelets, but that’s in the nature of fine tuning.

The arch accommodates a strip of double-sided foam tape holding the clip in place along the fender curve, with those cute little hooks capturing the fender to keep the tape in compression:

Tour Easy Front Fender Clip – installed

I really must get some black foam tape …

The picture shows the fender sitting well away from the tire, due to the upper fender mount bending in response to the splash flap snagging on curbs and random debris; the wire stays didn’t seat completely into the posts.

The extender I made during the cracked fork episode remained perfectly straight, though:

Tour Easy – new fork – fender extender

So I re-bent the upper fender mount (not the extender!) to its original angle, thereby moving the bottom of the fender much closer to the tire. Now the stays seat fully, the clip holds the fender firmly in place with no rattles, and it’s all good.

The OpenSCAD source code as a GitHub Gist: