Maybe it will help if I explain why I am really so fixated on this. The example with the tire was actually a secondary realization but more easily conveyed so I used it to start the discussion. The real issue is when extruding the material. I have been working on designing a new hotend which is better for super flexible filaments. I have been testing ordinary 95A TPU, as well as 30D (~78A), 75A, and 60A filaments.
I am using an OmniaDrop extruder which is renowned for its performance with flexible filaments and spent most of my efforts on optimizing the hotend. I have gone through at least a dozen hotends, some of the most highly rated commercially available ones but mostly those of my own design. Among the commercially available ones, the "serious" hotends and nozzles have a Ra roughness spec. The smoother the bore, the better, supposedly. So among those I have designed, I was initially trying to polish the bore as sooth as possible. I even went so far as to build a hotend which was entirely lined with PTFE all the way from the bottom of the extruder gears to the tip of the nozzle. I bought high quality precision reamers and produced barrels with mirror finish inside. It seemed there was not much that could be done to improve the flow through the hotend.
I had one barrel which I had made from scratch early in the process, drilled through solid rod with a poor quality 2mm drill bit, and the interior surface was not very smooth. It was a fly in the data ointment as it outperformed everything I had tested by 5%. I bought some needle eye barrel laps and lapping compound and lapped another barrel. I did something wrong when lapping, not sure what, but the result was a barrel bore that had a finish like micro-scale "orange peel" in a bad automotive paint job. I almost didn't even test it because it was a "failure" but decided "what the heck, if I can't get numbers to stand out positively, I'll make them stand out negatively. At least that will tell me if I'm barking up the right tree with regards to barrel finish." So I tested it and the results were very counterintuitive. It outperformed all previous tests by 20%. So I tested a barrel in which I had intentionally destroyed the surface finish by running through it with a drill holding a bristle I made from fine stainless wire. It had deep scratches all through it from one end to the other and it performed about the same as the orange peel barrel. So now the trend indicates that a rough barrel, not a smooth one, improves flow through the hotend.
I have entertained several theories about why this is, and the two I feel best about are:
1. that the rough barrel creates turbulent flow which mixes hotter material with cooler material, pulling cooler material from the center out to the walls, and results in a more evenly heated fluid at the nozzle. And,
2. that there is some microscopic tractive interaction between a smooth filament and a smooth bore, which is not present (or less present) with a rough bore.
I think it likely that there are multiple reasons, including the two above, but I am almost entirely convinced that #2 IS happening, and is one of the greatest contributing factors, because I was able to squeeze a bit more performance out of the system by ditching my PTFE-lined heatbreak for an all-metal one whose bore I had scratched up with carbide. So this is not just a fluid flow phenomenon, it applies to the unmelted filament prior to entering the melt zone.
I want to understand what is going on here so that I can further optimize the design. Is there maybe a specific pattern which would give better results? A certain depth of scratches? Understanding why I hope would lead to how to do it intentionally.
Also I would like to know why PTFE-lined heatbreaks and smooth bore nozzles are the default suggestions to anyone wanting to print flexible filaments. Is this all born from a bad assumption and reinforced by monkey see, monkey do? Has nobody actually tried going against conventional wisdom? I mean, yeah it seems totally intuitive that "smoother the better" but I have a wealth of data proving that false.
I am using an OmniaDrop extruder which is renowned for its performance with flexible filaments and spent most of my efforts on optimizing the hotend. I have gone through at least a dozen hotends, some of the most highly rated commercially available ones but mostly those of my own design. Among the commercially available ones, the "serious" hotends and nozzles have a Ra roughness spec. The smoother the bore, the better, supposedly. So among those I have designed, I was initially trying to polish the bore as sooth as possible. I even went so far as to build a hotend which was entirely lined with PTFE all the way from the bottom of the extruder gears to the tip of the nozzle. I bought high quality precision reamers and produced barrels with mirror finish inside. It seemed there was not much that could be done to improve the flow through the hotend.
I had one barrel which I had made from scratch early in the process, drilled through solid rod with a poor quality 2mm drill bit, and the interior surface was not very smooth. It was a fly in the data ointment as it outperformed everything I had tested by 5%. I bought some needle eye barrel laps and lapping compound and lapped another barrel. I did something wrong when lapping, not sure what, but the result was a barrel bore that had a finish like micro-scale "orange peel" in a bad automotive paint job. I almost didn't even test it because it was a "failure" but decided "what the heck, if I can't get numbers to stand out positively, I'll make them stand out negatively. At least that will tell me if I'm barking up the right tree with regards to barrel finish." So I tested it and the results were very counterintuitive. It outperformed all previous tests by 20%. So I tested a barrel in which I had intentionally destroyed the surface finish by running through it with a drill holding a bristle I made from fine stainless wire. It had deep scratches all through it from one end to the other and it performed about the same as the orange peel barrel. So now the trend indicates that a rough barrel, not a smooth one, improves flow through the hotend.
I have entertained several theories about why this is, and the two I feel best about are:
1. that the rough barrel creates turbulent flow which mixes hotter material with cooler material, pulling cooler material from the center out to the walls, and results in a more evenly heated fluid at the nozzle. And,
2. that there is some microscopic tractive interaction between a smooth filament and a smooth bore, which is not present (or less present) with a rough bore.
I think it likely that there are multiple reasons, including the two above, but I am almost entirely convinced that #2 IS happening, and is one of the greatest contributing factors, because I was able to squeeze a bit more performance out of the system by ditching my PTFE-lined heatbreak for an all-metal one whose bore I had scratched up with carbide. So this is not just a fluid flow phenomenon, it applies to the unmelted filament prior to entering the melt zone.
I want to understand what is going on here so that I can further optimize the design. Is there maybe a specific pattern which would give better results? A certain depth of scratches? Understanding why I hope would lead to how to do it intentionally.
Also I would like to know why PTFE-lined heatbreaks and smooth bore nozzles are the default suggestions to anyone wanting to print flexible filaments. Is this all born from a bad assumption and reinforced by monkey see, monkey do? Has nobody actually tried going against conventional wisdom? I mean, yeah it seems totally intuitive that "smoother the better" but I have a wealth of data proving that false.


