Convergence to self replicating
Posted by PMCG
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Re: Convergence to self replicating January 06, 2013 05:29PM |
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PMCG
Has anyone yet built a reprap that (besides the electronics) was 100% reproducible by the reprap.
No.
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VDX
as long, as we can't print linear drives
I think Viktor's assertion that "we can't print linear drives" is incorrect. We can print rotary motors (Printable solenoid motor, Printable flat coil motor). We can print gears and racks. So I think printing a linear drive is feasible.
I am not sure what Viktor means by "multiple grade solid-state bearings" by maybe it is similar to compliant mechanisms and living hinges? If so, then I agree heartily that this is a good way to make a reprap that does not rely on precision rods and bearings.
A number of people have worked on the building blocks of a printable reprap, and many of their projects are well documented on the wiki. The concept of using a family of tools that *collectively* self-replicate has also come up on occasion. I like to call these collectively self-replicating families of tools Cyclic Fabrication Systems, but that's just me.
Projects related to 100% printability and/or cyclic fabrication systems include: printable motors, printable circuit boards, Sarrus linkages, compliant and/or printed mechanisms for linear motion, printable lathes, printable extruder nozzles, paste and ceramic extruders, metal extruders, and others. Here is a small sampling:
Actuator Fabrication
Automated Circuitry Making
Printable Sarrus Linkage
Compliant Linear Motion Mechanism
Printable X/Y Linear Rail
Printable Lathe
Electroformed Nozzle
Printable Paste Extruder
Reprap Metal Deposition Experiments
Even though there is some interest in this area, not a lot of people around here actually care about converging to self-replicating. Most of the development energy in RepRap currently follows this model:
1. Build your first RepRap.
2. Think up a printer that looks different from the one you just made, but basically does the exact same thing.
3. Put it on Kickstarter/Indiegogo/Whatever
4. ???
5. Profit!
Take a look at the evolution of the popular low cost 3D printers out there, and you will see that they are actually moving *away* from self-replicating, in that they use more machined parts, more lasercut parts, and so on. Certainly there is little effort to eliminate things like motors and precision rods and bearings.
The reason for this is simple: There is no economic incentive to do so. And if you are a hobbyist who just wants to print things for other projects, why would you settle for a sub-standard machine just because it happens to be a little more "replicatable"? The (apparent) complete lack of interest in the Gada Prize is another indicator of this mindset. So, the self-replication research effort is left to passionate individuals who pursue it just because they think it is a cool idea.
Now, before people start writing angry responses defending their favorite machines, please understand I am not trying to disparage the excellent new printers that people here are developing. They are wonderful, they work better, I like them. They just don't have a lot to do with self-replication.
EDIT: Victor -> Viktor. Sorry Viktor!
Edited 1 time(s). Last edit at 01/06/2013 05:50PM by MattMoses.
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Re: Convergence to self replicating January 06, 2013 06:25PM |
Thanks MatMoses and VDX you've given me a lot to read and think about.
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Re: Convergence to self replicating January 07, 2013 06:45PM |
... yes, you can print linear drives, but I think, the accuracy and rigidity isn't sufficient for common 'serious' working with the versions I've seen until now 
In the last 15 years I was working in the micro-/nanotech business (actually industrial CAD-software development) and then we develped some really interesting parts regarding handling/assembly, accuracy and such.
It's possible to make most of the parts needed for a RepRap (even a big count of the 'vitamins' and some new/superior techniques and materials) with alternative microtech-methods, that can be redefined as 'self-replicating', but the complexity and cost of the resources is actually out of the DIY-range.
One of my goals is 'homebrew-nanotech' in maybe ten years ... have some of the needed tools, methodes and materials/chemistry already there, but it's a really complex area for DIY/homebrew ...
Viktor
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Aufruf zum Projekt "Müll-freie Meere" - [reprap.org] -- Deutsche Facebook-Gruppe - [www.facebook.com]
Call for the project "garbage-free seas" - [reprap.org]
In the last 15 years I was working in the micro-/nanotech business (actually industrial CAD-software development) and then we develped some really interesting parts regarding handling/assembly, accuracy and such.
It's possible to make most of the parts needed for a RepRap (even a big count of the 'vitamins' and some new/superior techniques and materials) with alternative microtech-methods, that can be redefined as 'self-replicating', but the complexity and cost of the resources is actually out of the DIY-range.
One of my goals is 'homebrew-nanotech' in maybe ten years ... have some of the needed tools, methodes and materials/chemistry already there, but it's a really complex area for DIY/homebrew ...
Viktor
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Aufruf zum Projekt "Müll-freie Meere" - [reprap.org] -- Deutsche Facebook-Gruppe - [www.facebook.com]
Call for the project "garbage-free seas" - [reprap.org]
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Re: Convergence to self replicating January 07, 2013 07:38PM |
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konwiddak
Someone made this: [www.youtube.com]
I don't know if its ever been made into a complete reprap.
That is fdavies's Printable Sarrus Linkage
He has a lot of work on thingiverse. I wonder if he is still working on this? Fdavies are you out there?
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VDX
It's possible to make most of the parts needed for a RepRap (even a big count of the 'vitamins' and some new/superior techniques and materials) with alternative microtech-methods, that can be redefined as 'self-replicating', but the complexity and cost of the resources is actually out of the DIY-range.
Can you elaborate on these alternative microtech-methods at all, Viktor? And can you tell us what you mean by a "multiple grade solid-state-hinge"? Is it like a living hinge? I am really interested in this stuff, and I know you are expert in all kinds of laser- and micro- fabrication methods.
Can you point us to any links or articles?
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Re: Convergence to self replicating January 08, 2013 04:48PM |
... attached are some samples for monolithic parallel kinematics and hinged structures 
We had some interesting discussions about tripods some years ago ( [forums.reprap.org] ) ... maybe "Rostok" is based on this threads and on my demo-setup: [builders.reprap.org]
In the previous link you can go down to my blog "LOM-fabbing with a CNC-repstrap" for another potentially interesting idea.
With 'new materials' I was referring to magnetic memory alloys based on NiMnGa, that changes shape/length similar to PZT-actuators (Piezo's), but not by applying HV, but with a strong magnetic field ... and not only around 0.3% as with PZT, but 5% to 10% contraction or elongation of a block structure! --- Unfortunately the company producing and selling this phantastic stuff isn't active anymore
... much more related infos are spread over the forums and years ...
Edited 1 time(s). Last edit at 01/08/2013 04:53PM by VDX.
Viktor
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Aufruf zum Projekt "Müll-freie Meere" - [reprap.org] -- Deutsche Facebook-Gruppe - [www.facebook.com]
Call for the project "garbage-free seas" - [reprap.org]
We had some interesting discussions about tripods some years ago ( [forums.reprap.org] ) ... maybe "Rostok" is based on this threads and on my demo-setup: [builders.reprap.org]
In the previous link you can go down to my blog "LOM-fabbing with a CNC-repstrap" for another potentially interesting idea.
With 'new materials' I was referring to magnetic memory alloys based on NiMnGa, that changes shape/length similar to PZT-actuators (Piezo's), but not by applying HV, but with a strong magnetic field ... and not only around 0.3% as with PZT, but 5% to 10% contraction or elongation of a block structure! --- Unfortunately the company producing and selling this phantastic stuff isn't active anymore
... much more related infos are spread over the forums and years ...
Edited 1 time(s). Last edit at 01/08/2013 04:53PM by VDX.
Viktor
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Aufruf zum Projekt "Müll-freie Meere" - [reprap.org] -- Deutsche Facebook-Gruppe - [www.facebook.com]
Call for the project "garbage-free seas" - [reprap.org]
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Re: Convergence to self replicating January 09, 2013 12:47AM |
Thanks, Viktor. That is great stuff!
Dr.-Ing. Uwe Jungnickel's dissertation (Tripod-2.jpg) seems to be currently living here, if anyone wants more info. There is some amazing stuff in there. I can tell it is amazing even though I can't read German.
Dr.-Ing. Uwe Jungnickel's dissertation (Tripod-2.jpg) seems to be currently living here, if anyone wants more info. There is some amazing stuff in there. I can tell it is amazing even though I can't read German.
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Re: Convergence to self replicating January 09, 2013 10:47AM |
... by the way, maybe interesting too - found a photo of my last two micro-/nano- handling- and assembly-stages now collecting dust in the basement:
The right one (aluminium base frame) is a combination of manual XY- and Z-sliders (from microscopy) and magnetically driven Ferrofluid-supported XY-actuator (the bigger blue plate) and a Z-actuator (smaller vertical blue box) with manual driving ranges of maybe 30mm and voltage-controlled fine-positioning with maybe 0.5mm in XYZ and nanometer resolution (the actuators) - controlled by the drivers in the base or by an extrenal 3-channel DAC.
The bigger black-blue device on the left is a converted SMD-pick-n-placer with a XYZ-actuator (the white box on the left) with 1mm positioning range and same nm-resolution but controlled by the '4D-joystick' under the blue hand-rest. Here you can see two microscope-cameras attached to the SMD-placer head (the two slanted aluminium cylinders).
With this stages I've assembled and glued together several micro-sensors, optical switches and the optics for fiberscopes with single parts of some ten to hundred micrometers size and positioning accuracies down to single microns (but could be nanometer-accuracy with proper measuring too).
Edited 1 time(s). Last edit at 01/09/2013 10:48AM by VDX.
Viktor
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Aufruf zum Projekt "Müll-freie Meere" - [reprap.org] -- Deutsche Facebook-Gruppe - [www.facebook.com]
Call for the project "garbage-free seas" - [reprap.org]
The right one (aluminium base frame) is a combination of manual XY- and Z-sliders (from microscopy) and magnetically driven Ferrofluid-supported XY-actuator (the bigger blue plate) and a Z-actuator (smaller vertical blue box) with manual driving ranges of maybe 30mm and voltage-controlled fine-positioning with maybe 0.5mm in XYZ and nanometer resolution (the actuators) - controlled by the drivers in the base or by an extrenal 3-channel DAC.
The bigger black-blue device on the left is a converted SMD-pick-n-placer with a XYZ-actuator (the white box on the left) with 1mm positioning range and same nm-resolution but controlled by the '4D-joystick' under the blue hand-rest. Here you can see two microscope-cameras attached to the SMD-placer head (the two slanted aluminium cylinders).
With this stages I've assembled and glued together several micro-sensors, optical switches and the optics for fiberscopes with single parts of some ten to hundred micrometers size and positioning accuracies down to single microns (but could be nanometer-accuracy with proper measuring too).
Edited 1 time(s). Last edit at 01/09/2013 10:48AM by VDX.
Viktor
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Aufruf zum Projekt "Müll-freie Meere" - [reprap.org] -- Deutsche Facebook-Gruppe - [www.facebook.com]
Call for the project "garbage-free seas" - [reprap.org]
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Re: Convergence to self replicating January 09, 2013 03:19PM |
That must be some basement!So the micro-grippers are attached to the motion stages, in order to pick things up and manipulate on the small scale?
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Re: Convergence to self replicating January 09, 2013 04:16PM |
... there were several different setups and gripper-types - mechanical, vacuum, icing, glue, magnetic, electrostatic, PZT and SMA (morphing alloys) ... depending on the object size and special requirements.
I've developed some special handling systems for nano-wires and CNT's or laserdiode-welding/brazing with 1 micron thick platinum wires and such ...
Some of this equipment and parts are 'remnants' from projects or developments I've made as freelancer or in my time for Gerwah Mikrotechnik ... others was made for my own needs or for testing some special 'home-brew-nanotech' concepts before going public
Viktor
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Aufruf zum Projekt "Müll-freie Meere" - [reprap.org] -- Deutsche Facebook-Gruppe - [www.facebook.com]
Call for the project "garbage-free seas" - [reprap.org]
I've developed some special handling systems for nano-wires and CNT's or laserdiode-welding/brazing with 1 micron thick platinum wires and such ...
Some of this equipment and parts are 'remnants' from projects or developments I've made as freelancer or in my time for Gerwah Mikrotechnik ... others was made for my own needs or for testing some special 'home-brew-nanotech' concepts before going public
Viktor
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Aufruf zum Projekt "Müll-freie Meere" - [reprap.org] -- Deutsche Facebook-Gruppe - [www.facebook.com]
Call for the project "garbage-free seas" - [reprap.org]
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Re: Convergence to self replicating January 11, 2013 03:05AM |
... I've used all sorts of materials and methodes:
- plastics: POM, PEEK, elastic polymers - solid blocks/sheets for milling, powders, pastes and chemistry for 3D-printing/curing/coating
- glass: - solid sheets for etching, powders for fusing/glass-soldering or 3D-printing with paste
- ceramics: - limestone and MACOR for milling, 'green' sheets for 3D-shaping and sintering, powders for pastes and SLS
- metals: - aluminium, brass, steel, titanium, platinum, gold - solids for milling, powders for brazing and micro-SLS
- complex materials: - ferrofluids, magnetorheological mixtures, shape-memory-alloys (thermal, electrostatic or magnetically activated)
- nanowires: - CNT's and metal nanowires
... and more - it's a really wide/complex field
Viktor
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Aufruf zum Projekt "Müll-freie Meere" - [reprap.org] -- Deutsche Facebook-Gruppe - [www.facebook.com]
Call for the project "garbage-free seas" - [reprap.org]
- plastics: POM, PEEK, elastic polymers - solid blocks/sheets for milling, powders, pastes and chemistry for 3D-printing/curing/coating
- glass: - solid sheets for etching, powders for fusing/glass-soldering or 3D-printing with paste
- ceramics: - limestone and MACOR for milling, 'green' sheets for 3D-shaping and sintering, powders for pastes and SLS
- metals: - aluminium, brass, steel, titanium, platinum, gold - solids for milling, powders for brazing and micro-SLS
- complex materials: - ferrofluids, magnetorheological mixtures, shape-memory-alloys (thermal, electrostatic or magnetically activated)
- nanowires: - CNT's and metal nanowires
... and more - it's a really wide/complex field
Viktor
--------
Aufruf zum Projekt "Müll-freie Meere" - [reprap.org] -- Deutsche Facebook-Gruppe - [www.facebook.com]
Call for the project "garbage-free seas" - [reprap.org]
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Re: Convergence to self replicating January 11, 2013 12:48PM |
martinprice2004's comment about the pantograph reminded me of Feynman's lecture "There's Plenty of Room at the Bottom". Everyone here already knows about this lecture, right?
Feynman suggested a recursive manufacturing system for making small things. He noted that "At each stage, it is necessary to improve the precision of the apparatus."
RepRap users do this by a few ways. First, a lot of the precision is already built into the raw materials - the precision rods and bearings, the tiny hole in the extruder nozzle, the stepper motors, and so on. Second, builders go through a calibration and adjustment process, where the output of the machine is measured, and then corrections are made to improve its performance. (David Gingery used metal scraping to improve the accuracy of his homemade lathe.)
Feynman discusses some of the problems with using pantographs, and he mentions a few ways to naturally increase the precision of mechanical components. Joseph Whitworth is famous for developing many of these processes, including metal scraping.
We all agree that a machine can make more precise parts than the parts it is made from, but some kind of calibration and adjustment process is essential for this to happen.
Here is the part of Feynman's lecture about the pantograph. (Sorry for so much text!) You can read more about the lecture and find the full text here and here.
EDIT: martinprince2004 -> martinprice2004. Spelling names is hard
Edited 1 time(s). Last edit at 01/11/2013 12:51PM by MattMoses.
Feynman suggested a recursive manufacturing system for making small things. He noted that "At each stage, it is necessary to improve the precision of the apparatus."
RepRap users do this by a few ways. First, a lot of the precision is already built into the raw materials - the precision rods and bearings, the tiny hole in the extruder nozzle, the stepper motors, and so on. Second, builders go through a calibration and adjustment process, where the output of the machine is measured, and then corrections are made to improve its performance. (David Gingery used metal scraping to improve the accuracy of his homemade lathe.)
Feynman discusses some of the problems with using pantographs, and he mentions a few ways to naturally increase the precision of mechanical components. Joseph Whitworth is famous for developing many of these processes, including metal scraping.
We all agree that a machine can make more precise parts than the parts it is made from, but some kind of calibration and adjustment process is essential for this to happen.
Here is the part of Feynman's lecture about the pantograph. (Sorry for so much text!) You can read more about the lecture and find the full text here and here.
Quote
Feynman
Now comes the interesting question: How do we make such a tiny mechanism? I leave that to you. However, let me suggest one weird possibility. You know, in the atomic energy plants they have materials and machines that they can't handle directly because they have become radioactive. To unscrew nuts and put on bolts and so on, they have a set of master and slave hands, so that by operating a set of levers here, you control the "hands" there, and can turn them this way and that so you can handle things quite nicely.
Most of these devices are actually made rather simply, in that there is a particular cable, like a marionette string, that goes directly from the controls to the "hands." But, of course, things also have been made using servo motors, so that the connection between the one thing and the other is electrical rather than mechanical. When you turn the levers, they turn a servo motor, and it changes the electrical currents in the wires, which repositions a motor at the other end.
Now, I want to build much the same device – a master-slave system which operates electrically. But I want the slaves to be made especially carefully by modern large-scale machinists so that they are one-fourth the scale of the "hands" that you ordinarily maneuver. So you have a scheme by which you can do things at one- quarter scale anyway – the little servo motors with little hands play with little nuts and bolts; they drill little holes; they are four times smaller. Aha! So I manufacture a quarter-size lathe; I manufacture quarter-size tools; and I make, at the one-quarter scale, still another set of hands again relatively one-quarter size! This is one-sixteenth size, from my point of view. And after I finish doing this I wire directly from my large-scale system, through transformers perhaps, to the one-sixteenth-size servo motors. Thus I can now manipulate the one-sixteenth size hands.
Well, you get the principle from there on. It is rather a difficult program, but it is a possibility. You might say that one can go much farther in one step than from one to four. Of course, this has all to be designed very carefully and it is not necessary simply to make it like hands. If you thought of it very carefully, you could probably arrive at a much better system for doing such things.
If you work through a pantograph, even today, you can get much more than a factor of four in even one step. But you can't work directly through a pantograph which makes a smaller pantograph which then makes a smaller pantograph – because of the looseness of the holes and the irregularities of construction. The end of the pantograph wiggles with a relatively greater irregularity than the irregularity with which you move your hands. In going down this scale, I would find the end of the pantograph on the end of the pantograph on the end of the pantograph shaking so badly that it wasn't doing anything sensible at all.
At each stage, it is necessary to improve the precision of the apparatus. If, for instance, having made a small lathe with a pantograph, we find its lead screw irregular – more irregular than the large-scale one – we could lap the lead screw against breakable nuts that you can reverse in the usual way back and forth until this lead screw is, at its scale, as accurate as our original lead screws, at our scale.
We can make flats by rubbing unflat surfaces in triplicates together – in three pairs – and the flats then become flatter than the thing you started with. Thus, it is not impossible to improve precision on a small scale by the correct operations. So, when we build this stuff, it is necessary at each step to improve the accuracy of the equipment by working for awhile down there, making accurate lead screws, Johansen blocks, and all the other materials which we use in accurate machine work at the higher level. We have to stop at each level and manufacture all the stuff to go to the next level – a very long and very difficult program. Perhaps you can figure a better way than that to get down to small scale more rapidly.
EDIT: martinprince2004 -> martinprice2004. Spelling names is hard
Edited 1 time(s). Last edit at 01/11/2013 12:51PM by MattMoses.
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