Differential Screws, 11 Lenses, Harmonic Gear (robot series)

JoergS5

@deckingman @mrehorstdmd thanks for feedback, I agree with both of you. There's still a lot to learn...

My father gave me his lathe as a gift and I produced the first threaded spindle. I wondered why I could not produce an even diameter for the whole length. Until I was aware that the shaft bent while turning, more at the beginning, then less.

deckingman

@joergs5 said in Differential Screws, 11 Lenses, Harmonic Gear (robot series):

@deckingman @mrehorstdmd thanks for feedback, I agree with both of you. There's still a lot to learn...

My father gave me his lathe as a gift and I produced the first threaded spindle. I wondered why I could not produce an even diameter for the whole length. Until I was aware that the shaft bent while turning, more at the beginning, then less.

You do have a lot to learn!. When I bought my lathe, I wondered how much I would remember from the last time I used one which was over 40 years ago. Fortunately, I remembered most of it

For turning shafts, a centre in the tails stock will give you support at both ends and prevent that bending. Do an internet search for "live centre" and you'll see what I mean. For especially long shafts or especially thin ones, another steady in the centre can be great help, because even with both ends supported, they can tend to bed away from the cutting tool in the centre. Either a fixed or travelling steady (Google "travelling lathe steady" and you'll see what I'm talking about).

JoergS5

@deckingman thank you for your hints. Using the lathe is a useful next step to DIY needed parts.

deckingman

@joergs5 said in Differential Screws, 11 Lenses, Harmonic Gear (robot series):

@deckingman thank you for your hints. Using the lathe is a useful next step to DIY needed parts.

I'm finding the same thing. For info, I've just made a set of 6 threaded heat breaks out of stainless steel, with the heat break section having a wall thickness of 0.3 - 0.4mm. That was a challenge.

JoergS5

@deckingman yes, I check your videos and blogs regularly, it's always interesting. I saw a video about Bondtech CHT today and thought, why not make my own nozzle in the future?

I tried thread cutting yesterday with M3 again and failed, it broke. I cannot remove the broken part. I have an impression what you have achieved!

tony73

@joergs5
bye! I follow you step by step on the work you are doing! I am waiting to see the differential screw reducer, to understand how it should be built! me to learn how to use a lathe, or watched the videos of (delfino brunelli) on you tube! he has a lathe from the early 1900s, rearranging by him with high precision is what he does with that lathe is amazing! I consider it the best I've seen among many!

JoergS5

@tony73 said in Differential Screws, 11 Lenses, Harmonic Gear (robot series):

delfino brunelli

hello Tony, the youtube channels are worth a lot, thanks for the hint. I discovered "Huygens Optics", "Applie Science", "CNC Kitchen" and many others, it's a real gold source. Especially Huygens Optics is really impressive!!

I am currently developing the forward kinematics for the robot, so I make a little pause for the differential screw. But I am training using the lathe, damaged some parts, but it's getting better!

Interestingly, the forward kinematics of the robot allows as many axes as one wishes, from 1 to 10 or more axes, without problem. The inverse kinematics is the problem... (but I have ideas).

zapta

@deckingman said in Differential Screws, 11 Lenses, Harmonic Gear (robot series):

So I learned to read a vernier scale.

Vernier calipers go well with a sliding rules and Rapidographs .

I often watch the youtube channel of Nero 3D (a Canadian in his thirties) and I found it interesting that he refers to his digital calipers as 'vernier'.

deckingman

@zapta said in Differential Screws, 11 Lenses, Harmonic Gear (robot series):

@deckingman said in Differential Screws, 11 Lenses, Harmonic Gear (robot series):

So I learned to read a vernier scale.

Vernier calipers go well with a sliding rules and Rapidographs .

Yes. I'm old enough to remember going to school before calculators were invented. As well as using books of log tables, we had slide rules. When I went to college, calculators were just coming on to the market but few people could afford to buy them. The first college exams I sat, calculators were banned but slide rules were permitted.

dc42

Slide rules? Luxury! (with a Yorkshire accent)

deckingman

@dc42 Yes - pure decadence. We even used paper and ink - none of this slate and chalk stuff (although the teachers used blackboards and chalk). I think it was mostly because chalk made good missiles to throw at wayward students (or in the case of one teacher it was a great big lump of wood in the form of a board rubber). I never did work out why giving a student concussion would make them pay more attention........

JoergS5

@tony73 I've managed to have a working kinematics and inverse kinematics code for 6 axis robot now, based on Jacobian matrix calculation. I need about 3 iterations to approach an exact inverse kinematics position and orientation, on the PC about 5 ms for 100 segments. I hope it's fast enough for running it on Duet.

I proceed with building differential screw / 1:1 lens / harmonic drive now to build a robot prototype.

tony73

@joergs5
Hello! how is the design of the six-axis robot progressing? I look every now and then if there is any news!

JoergS5

@tony73 I thought about I have to post news the next days how it's proceeding.

I went back to school in a figurative sense the last two months to learn more about robot kinematics, especially matrix calculations, so there was no development. I'll proceed with building soon.

Core elements are differential screws (I need them at multiple places), encoder support and diy harmonic drive, and finishing the RRF kinematics code. I'll use OpenCV for quality checks, it's a great program, I can recommend the book of Escriva/Laganiere about OpenCV 4.

I'll use OpenCV together with the cameras/lenses for

• check the quality of the harmonic drive teeth
• check printing result while printing
• CNC position checking, 3D printing object position checking, SMD placement
• homing position checking
• measure precision of the kinematics (joints, steppers, belts, pulleys)

The patents of harmonic drives are interesting, I follow inventor Aubin with US5456139, EP0640778, US5662008 and similar from Ishikawa to optimize teeth. I try 3D printed parts first (using PP for the flexspline), but if it's not sufficient change to drilling with CNC with spring steel.