Incorrect extrusion amount on slow and/or small axis moves
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@deckingman said in Incorrect extrusion amount on slow and/or small axis moves:
@fcwilt Almost but not exactly. If you think about a 3 dimensional move from a point in space defined as Xa Ya Za and at the end of that move it ends up at a point in space defined as Xb Yb Zb. The we can draw a straight line between Xa Ya Za to Xb Yb Zb. The specified feed rate applies to that (diagonal) line. So unless there is a move purely in one direction with no other direction components, then the actual feed rate for all the individual axes will be lower than the specified feed rate (because the individual axis components would be shorter than the 3 dimensional, "diagonal" line).
Understand about the diagonal and how the feed rate F applies to it.
But the extruder needs to complete it's "move" at the same time as the moves of all the other axes.
Correct?
So wouldn't it's feed rate limit possibly limit all the other axes?
Frederick
Frederick
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@fcwilt said in Incorrect extrusion amount on slow and/or small axis moves:
Understand about the diagonal and how the feed rate F applies to it.
But the extruder needs to complete it's "move" at the same time as the moves of all the other axes.
Correct?
So wouldn't it's feed rate limit possibly limit all the other axes?
Yes - and I said as much a few posts further up. But what is the point you are trying to make?
In the example above, the OP is moving B by 2mm and the extruder by 50mm. The extruder speed is limited to 3600 mm/minute or 60mm/sec so (ignoring the acceleration and deceleration phases) 50mm at 60mm/sec will take 1.2 seconds. Yet we know that the specified feed rate is 480mm/minute or 8mm/sec. If we apply that 8mm/sec feedrate to the B axis then a 2mm move should take 0.25 seconds. But the move has to take 1.2 seconds in order to extrude 50mm at the limit of 3600 mm/minute or 60mm/sec (assuming the hot end is capable of achieving that sort of melt rate which I've have demonstrated is so improbable as to be unbelievable). So the B axis will have to be slowed down too, i.e the entire move will take longer than 0.25 seconds (about 1.2 seconds) which is what I said a few posts further up.
But none of that detracts from the fact that it is highly unlikely that a single input, single heat zone, hot end with a 0.4mm nozzle could extrude 10,800 mm^3/sec which is what it would have to do if the extruder feedrate was 3600 mm/minute. Hence the OP is getting under extrusion.
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@deckingman said in Incorrect extrusion amount on slow and/or small axis moves:
Yes - and I said as much a few posts further up. But what is the point you are trying to make?
Just trying to understand what is going on and how it all works.
Thanks.
Frederick
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I'm glad I'm not going crazy and that what goes on behind a G1 is actually more complex that it first seems, enough to provoke some discussion.
@tfjield I believe the G1 feedrate cap only applies to CNC mode doesn't it, i.e., if you have issued an
M453
to switch to CNC mode? That should not affect the Duet if in regular 3D printing mode.@deckingman to answer your question
G1 E50 F3600
will absolutely grind filament. However extruder feedrate maximums are often set much higher than the maximum printable feedrate so that a higher rate can be used during retraction, which isn't subject to the same pushing plastic limitations. I don't recall if there is a seperate retraction limit that can be set somewhere.8mm/s is doable on a Hemera with a 0.4mm nozzle, though probably not across a whole print, for priming into air it does fine though, much higher will have issues in my experience.
My (possibly incorrect) assumption was that in a G1 move, the movements of the axes would need to be slowed down to accommodate the slowest of any axis (including the extruder) and not just the movement axes. If this is not the case then it would explain why the short travel move forces the extruder to go faster, though I do not believe it is reaching 3600mm/m as that would make a huge honking noise and mess as it grinds away.
I think it comes down to the fundamental question, what is the expected behaviour of
G1
when the extruder is commanded to move a distance that is greater than the movement axes with such a feedrate that the axes move would complete prior to the extruder move if not slowed down.To my thinking this issue could come up when using a very wide extrusion width with a large nozzle as well, though I haven't looked at that. I guess in those cases you're probably printing more slowly (in movement speed, of course volumetric flow would be higher) anyway.
More testing to come though. I'll switch to pure tests in air over the bed and the X-axis just to remove some more variables.
Of course, in the end, for my use case I can just slow down, priming at 250mm/m instead of 480mm/m is going to make no real difference, however I do want to get to the bottom of what is happening just for my own understanding.
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@ardenpm The way I read it, it always applies, but it's especially important for CNC mode. But that's just my interpretation. I'll run a test when I get a chance.
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Good point about retractions.
however I do want to get to the bottom of what is happening just for my own understanding.
I thought I'd explained it. A G1 En Fn, there is no axis movement involved so the feed rate will apply only to the extruder. However, a G1 (Axis)n En Fn move will apply the feed rate to the axis. Because your extruder move length is 25 times greater than the axis move length, and because the extruder move must start and end at the same time as the axis move, then the feed rate for the extruder must necessarily be 25 times higher than that of the axis.
For info, I too use a purge and wipe system on my 6 input hot end (but without moving an axis concurrently). I purge 100mm at a feed rate of 300 (5mm/sec). In my case that's in the format G1 E100:0:0:0:0:0 F300. So with your 25:1 ratio of extruder to axis move length, if I used G1 B4 E100:0:0:0:0:0 I'd need to use a feed rate of 12 which would give me 300 for the extruder.
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@deckingman Yes I understand your description but my understanding was that is what you were assuming what is happening rather than what is intended to happen. To me it is surprising that the extruder limits are overridden by the axis limits, to me that is a fundamental property of G1 that should be describe somewhere (if it isn't already).
Testing just now I think what I am definitely seeing is the extruder racing up to its limits in order to try and match the movement axes, exactly as @deckingman describes. To me this seems counterintuitive and I would have expected the slowest axis to dictate the movement regardless of whether it is the extruder.
On review I am also seeing some skipping at 480mm/m which I didn't notice before so I'll probably cap that at 300mm/m, though even at that speed the axes are two far out of sync to stop the extruder racing away.
One option might be to reduce the maximum speed on the B axis temporarily in my prime Gcode to prevent this, I guess I can work out how much time the extruder needs to properly extrude the amount of filament I want then work out the fastest I can allow that axis to move while covering the distance needed.
@tfjield looks like you are correct, I just dropped minimum down with
M203 I1
and did a move of 1mm and that now takes around a minute as expected instead of 2 seconds. So ifG1
was working how I originally though (which it seems it is not) then it would have only been able to slow the axis to 30mm/m at the most, which is still pretty slow but no where near slow enough to extrude 50mm of filament. -
@ardenpm The way that fedrate is applied to moves that include extrusion is not very obvious (and a little confusing), see https://3dprinting.stackexchange.com/questions/14668/details-of-marlins-feedrate-calculation for another description of what is probably going on...
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@gloomyandy Mmm, this adds to the confusion for me since that description matches what my original assumption was:
Moves with a nonzero X, Y, or Z component: the feedrate is an ideal, desired speed in 3 dimensions, possibly limited by the max feedrates of each axis (including E) individually, as well as their acceleration profiles.
Specifically they say it is limited by the max feedrates of each axis, including the extruder. Though I guess since I am commanding it to move at a feedrate that is below all axes limits the moves are not limited at all, so the extruder is running up to its 3600mm/m limit. That lines up with what @deckingman was assuming as well.
In some testing now I can see if I artificially limit my movement axis speed limit the extruder can then keep up then I'm able to get a smooth axis movement over the length of the extrusion. However I need to calculate the expected time of the extrusion move, determine how slow to limit the movement axis to to make it take the same time and then limit its feedrate (then restore it afterwards). This does seem to work though.
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@ardenpm
To understand it fully, you need to be able to comprehend the concept of 4 (or more) dimensional space (something that I find hard to do)............my understanding was that is what you were assuming what is happening rather than what is intended to happen.
No, I'm not assuming anything. I had a similar query regarding the speeds of my UVA and B axis which run concurrently with X and Y but not necessarily over the same distances. This is how it was explained to me by @DC42 and he writes the firmware so he should know.
However I need to calculate the expected time of the extrusion move, determine how slow to limit the movement axis to to make it take the same time and then limit its feedrate (then restore it afterwards).
I've already told you how to that.
But hey, if you don't want to believe what I say, that's fine. I just wish I hadn't wasted so much of my time trying to help....
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No, I'm not assuming anything. I had a similar query regarding the speeds of my UVA and B axis which run concurrently with X and Y but not necessarily over the same distances. This is how it was explained to me by @DC42 and he writes the firmware so he should know.
Great, that is what I was trying to ask (perhaps clumsily), I wasn't sure if this was known expected behaviour of the firmware or what you were trying to deduce from my explanation of what I was seeing (which could have meant a bug). Obviously if David says that's how it works, then that's how it works.
However I need to calculate the expected time of the extrusion move, determine how slow to limit the movement axis to to make it take the same time and then limit its feedrate (then restore it afterwards).
I've already told you how to that.
Yes, and that's exactly what I used to do it, which was a very helpful idea (I just threw together a spreadsheet to do it by hand but should be able to put that into Gcode pretty easily as well). I only now had the opportunity to test it out. It also took me a few read throughs to fully grasp what was being proposed. I was just reiterating that what is needed is possible but requires some of the juggling you mentioned.
But hey, if you don't want to believe what I say, that's fine. I just wish I hadn't wasted so much of my time trying to help....
I'm not sure what gave that impression, your explanation and idea were definitely of help and appreciated.
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So putting this together now that it is clear what's going on, I'm using a small macro which takes the same
B
,E
andF
parameters as myG1
calls but computes the feedrate limit for me, changes it then sets it back to the original value. This seems to be working well and I can now do a nice smooth drop of my priming platform while extruding at the needed rate. Obviously fairly specific to my use case but in case it's helpful to anyone else here it is.var defaultSpeed = move.axes[4].speed var extrusionTimeMinutes = param.E / param.F var newSpeed = abs(param.B - move.axes[4].userPosition) / var.extrusionTimeMinutes echo {var.newSpeed},{move.axes[4].userPosition},{param.B} if var.newSpeed < var.defaultSpeed M203 B{var.newSpeed} G1 B{param.B} E{param.E} F{param.F} M203 B{var.defaultSpeed} else G1 B{param.B} E{param.E} F{param.F}
Thanks all for the lively discussion.
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@ardenpm Wouldn't it be easier just to compute a new feedrate and use it directly (as an F parameter) rather than setting a limit and relying on the firmware to apply it?
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@gloomyandy No, because I don't want to limit the E axis to that feedrate, I want it to run at the specified rate but the B axis much slower than normal. Without this the E axis will run up to its limit to try and sync with the short B axis move time. Without doing this I need to slow down the E axis too much.
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@ardenpm I see what you are doing but why not keep it simple and just set M203 E300 (to set say 5mm/sec), then do the G1 move and use M203 E3600 (to restore the feedrate value)?
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@deckingman Yes, that’s true I could also do that. I’ll need to use the object model to find the current tool to apply it to the right extruder motor so that should be possible. I haven’t confirmed that limiting the extruder instead of the movement axis has the same affect but I would assume it must. I would still set the limit of the extruder though to the feedrate I actually want since otherwise it would just always run at 300 (I have multiple steps at different feedrates in my case). But limiting the extruder is simpler and shouldn’t hit the other minimum speed issue. I’ll definitely give that a go.
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@ardenpm You could by-pass using the object model by setting the maximum extrusion rate for all extruders. So for example M203 E300:300:300:300 and then put them all back with M203 E3600:3600:3600:3600.
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@deckingman I prefer to restore the feedrates to their previous value rather than a hard coded value when done so if I change my configuration I don't need to hunt for values in my different macros. However that should be pretty straight forward, something like this.
var defaultSpeed0 = move.extruders[0].speed var defaultSpeed1 = move.extruders[1].speed var defaultSpeed2 = move.extruders[2].speed var defaultSpeed3 = move.extruders[3].speed M203 E{param.F} G1 B{param.B} E{param.B} F{param.F} M203 E{var.defaultSpeed0}:{var.defaultSpeed1}:{var.defaultSpeed2}:{var.defaultSpeed3}
Which is definitely still simpler than the first macro I had there. Definitely lots of ways to skin this particular cat.
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@ardenpm said in Incorrect extrusion amount on slow and/or small axis moves:
@gloomyandy No, because I don't want to limit the E axis to that feedrate, I want it to run at the specified rate but the B axis much slower than normal. Without this the E axis will run up to its limit to try and sync with the short B axis move time. Without doing this I need to slow down the E axis too much.
If B and E are not kept in sync how do you see that working? Would E just continue to run after B is done?
Thanks.
Frederick
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If B and E are not kept in sync how do you see that working? Would E just continue to run after B is done?
@fcwilt That's actually the issue, it does attempt to keep them in sync and it thinks on the extruder side it has enough headroom to run it all the way up to my configured maximum speed of 3600mm/m for extruders, where as my extruders can handle more like only 300mm/m without skipping.
The reason the extruders are configured to allow a speed much higher than they can actually extrude is because of retractions, which happen at a much faster speed than extrusions. So by limiting the extruder temporarily to the limit for practical extrusion it should force the movement axis to slow down further to say in sync.