Thomas, Thank you for building the AR4 and highlighting some of its features. I did want to touch on a few of the comments you made. In the overview section of the manual I do mention pre-applying solder to wires being joined together - I find it easier to pre-apply solder or tinning the ends - and then bring them together with the iron rather than trying to hold the wire ends together and hold the solder and hold iron at the same time, not having 3 hands - it helps to pre apply the solder. None of the wires going to the breakout board call for tinning so I'm not sure about your comments on that? On page 143 I do have some groups of wires soldered together to help group them going to the 3 screw terminals as its a tight fit and difficult to maneuver them into position without them being connected but you could certainly use ferrules in this step if needed. At one point in the past the design did utilize plug connectors and building a wiring harness. Given different applications, motions and articulations all the low cost plugs I sampled proved to fail over time. With this small arm and the limited cable routing and cable arc lengths, direct solder with the solder joints in strategic locations using heat shrink proved to be more reliable, less bulky, less costly and not as time consuming as crimping and inserting numerous plug pins. The primary goal of this project from day one has been to realize a usable robot and at a very particular price point. I've worked with industrial robots my entire career and its always been a frustration that any usable robot was out of reach. There is an absolute threshold on the price as most educators have a budgetary limit so I have made it priority number one to stay under that limit. This drives many of the design aspects, The motors for example are off the shelf variants and cannot be fully customized without adversely affecting the price. There is a limit as to what OMC can customize on these coming from the factory. The machined components are kept to an absolute minimum and as many as possible are cut from flat sheet material. This also drives the bearing designs and tensioning designs as custom machined threads and spindles for locknuts for example is not in the cards at this price point. It also drives some of the belt selections. I did notice the belt tension on your build was far too loose resulting in a good amount of play. Here is a quick video of the forced deflection on my build. (well it looks like I cant post a link in comments but I will post in on my channel or the forum) - Making the statement that "This robot arm is neither accurate nor precise, rigid or smooth" seems a bit harsh considering. The AR4 project is always under improvement, its not perfect but like I mentioned to you in an earlier email the robot is designed for pick and place, welding and handling operations. A great deal of effort has gone into this project, I know you have a great deal of experience and a wealth of knowledge in all manner of machines and mechatronics and your design suggestions are certainly well founded but I wanted to explain these aspects of the project, and hope you will convey these points to your audience. Thank you, Chris
I had tried many different robot arms, but no one beats AR4. Another big advantage is that you can discuss problems directly with Chris Annin. His manual is the best and most detailed I have ever seen for such a product in this price class. I got manufactured custom-made motors at StepperOnline, and I know how many motors needed to order to get them to a fair price. I don't find some of your criticism fair compared to the price for an AR4. Last .. sorry for my bad English, I'm from Denmark 🇩🇰 😊
Thanks, now I understand why there is no plug connectors: Quote: "At one point in the past the design did utilize plug connectors and building a wiring harness. Given different applications, motions and articulations all the low cost plugs I sampled proved to fail over time. "
This is the first I’ve heard of this arm, its incredible! I’m setting up a workstation for my robotics projects later next month, I wish I could set up the arm to keep my tools organized! It’d be a fun project
4:29 The reason why a tinned stranded wire will fail in a screw terminal is twofold: 1. Tinning a stranded wire will introduce a weak point where the solder wicks into the wire. If the wire doesn't move, this isn't a problem. But if it's part of a moving system, that wire is now much more likely to break where the solder wicked up. Now, I'm told you _can_ get away with tinning as little of the wire as possible, but I've never seen anyone pull that off. 2. Solder is prone to "creeping" under pressure, it's not really meant to hold its shape when it's squeezed. Over time, the soldered wire will slowly deform, loosening the connection with the wire, meaning you have to go back and tighten the screws. I've actually encountered this after about 2 months, and it is a huge pain. Better to crimp on a ferrule to each of those wires and never have to worry about them until something happens on the other end.
Instead of ferrules I like to solder male breadboard headers to the end of wires if they're going to be screwed into terminals. I think ferrules are probably the better solution for most cases but I don't have a crimp tool and many ferrules are way too thick to fit into very small terminals
@@catdisc5304 ferrules are sized based on the wire diameter, if a wire with ferrule is too large to fit in a screw terminal there is probably a good chance the wire is too thick anyway and the wire can handle much more current than the screw terminal. Ferrule crimping tools are very cheap and simple to use, much simpler than other connector types.
I was surprised to see that is the official way to do it, it is well known now with 3D printer failures that you do not tin wires that go into screw terminals.
@@conorstewart2214 also there are 2 types of screw terminals. One have additional sheet metal inside terminal to spread force over whole connector, it also acts as a spring so this connector have harder time becoming loose. And there is a second one, where wire is kept in place by screw directly. Second one can be used only with solid wires and ferrules, as stranded wires are simply getting crushed and cut inside by rotating screw.
I find it's more secure to just ditch the ferrule personally, if you don't use the right one and it's not properly crimped, the wire can slide out while the ferrule is left behind in the screw terminal... Ferrules aren't used for 230V wiring in houses and stuff either, and they will never budge
@@PureRushXevusyou do not use ferrules on solid wire. Their main purpose is to hold the ends of stranded wire together so the current flows through all strands not just those few the screw terminal caught. For the very small wire made of delicate strands the ferrules provide protection from the screw damaging and literally cutting off some strands. Thick solid wire doesn’t need ferrules. They also provide some strain relief for thin wires.
Not sure if I missed the price, but a quick look at the link says its about $1200 for the kit, and $800 for the motors. Not bad all things considering, could certainly help a mom & pop shop get some basic automation going
what kind of automatization can you achieve with this accuracy and stability? Plus all the effort of building it, which is almost impossible for a normal person who is not a tinkerer.
Ive been looking at cobots for my shop, and was quoted about 4K for one with the full setup and service. I keep looking at these projects, and almost every one of them ends up on github, and that to me is like water skiing on the moon.
Having been a developer for a big robot company in my past, that rail design was awesome game changer for us. There are still zero locations, but yes, they are reduced. Next big change for us was 6 DOF Force sensor with a 3D Laser camera...Best job EVER!
Axis 2 and 6 are designed OK. Other axes makes me say "what was he thinking?". Trapezoidal belt for axis 1, 3 and 4. Leadscrew on axis 5... Yes, it moves center of masses down and reduces required torque, but it would be much better to grab beafier gearboxes with higher reduction rate and drive joints directly. As for electronics, he could install TMC5160-BOB in the back of each motor, connect all of them via SPI, and control everything directly from RaspberryPi.
@@ferriswhitehouse1476 Not much. TMC5160 costs as much as DM542, but much more advanced and can correct step loss. And cost could be cut with other changes like dirt cheap magnetic encoders instead of expensive optical ones and only one very simple and cheap MCU would be required. Also wiring would be simplified - TMC5160 can be daisy-chained via UART, so only 1 UART wire and 2 Power wires would be required.
@@TheNamelessOne12357 okay sure for the electronics ill agree. It was released a few years ago so maybe those options weren't available, I'm not sure. Maybe a user could do those upgrades on their own. For the mechanical aspect though I would imagine its a pretty big cost jump. If you put more weight up on the ends of the arm then everything below it needs to be beefier as well. So upgrading all gearboxes and motors and frame components.
@TheNamelessOne12357 Chis is a Robotics Engineer by day job. The AR robots he designed for free basically, to be as cheap as possible. I asked him about the gear ratios and he said he made it this way so its speed is useful. If you look at the arduino/teensy code, it's quite advanced now. The windows app is just a UI to interface with the microcontroller that does all the IK calculations like ATAN2 etc, and synchronisation of joint moves. The serial on the microcontroller is agnostic to the UI platform. It could be Android, pi, windows. It's just the UI was designed for windows. -Ken
Nope, not one. You probably need multiple. For example to make "helicopterview" shots of parts while they are almost breaking in your tensile stress machine. And also one for your promo shots. One to feed your filament recycler and most importantly one for pooring a cup of coffee or tea during your recordings.
Hi, robotic engineer here. I made this robot a while ago when he was at the AR3 version, this made me learn how important precision machining and zero backlash gearbox is important for robots. Also his kinematic his questionable. While it does work, you need to develop your kinematic with singularities in mind and all the possible configurations of the robot for that position. Instead he limited the joint limit values to avoid having more than one configuration, but this is not optimal, dangerous even.
@@tec4303 I'm no expert, but I would assume either failure of a joint from higher force loading than anticipated or risk of toolpath collisions from having to work around over-constrained IK paths.
@@tec4303 even with limited joints range, its possible to have multiples configuration in certain positions which can lead to the robot changing configuration mid-path. A linear movement (MoveL) is usually made from multiple targets very close to each other along a line, if the robot calculate that there is more than one solution to reach these targets, it has to choose which one to use and stick to it for every targets following that line, or else the robot might twist its wrist 360 degree suddently at maximum speed to keep the linear speed and that is dangerous.
I've been watching Chris's channel for a few years. I love that his work is getting more mainstream traction! I've been wanting to make an arm for myself since I've seen his channel. His videos are amazing to help understand how things work!
They could, especially if they are machining all those parts anyway, even just small engravings on the surface, like a line on each part, just match the lines, would be good. However this likely isn’t a priority, the machine has a lot of other mechanical issues that would be more important to solve than making it easier to assemble.
Oh boy that backlash. I guess I'll wait for AR5. Feedback: Hall effect sensors are more accurate than limit switches. There are even hall effect encoders to check the actuall position.
Good "review" of this kit. Even with restrictions I think for this money you get an awsome kit. @12:33 you say the motors don't meet the backlash of 0.25 degrees but you measure the complete robot, not just the motor, so that means you also measure any play in the bearings. I use a Kuka KR180 and with that one, motions are also not always smooth. Depending on the load (I have a 30 kg spindle motor mounted as end effector) I can see some jitter during moves and expecially when the brakes are released from the motors there is some movement to compensate for changing load on the motors. The AR4 is still an amazing development and it does have some nice uses for parts picking applications
Take a look at the Parol 6. It’s more expensive at around $2300 in kit form but the movement repeatability tests I’ve seen look impressive and it’s open source.
Hello! I really enjoyed watching your intriguing video. I hope this doesn’t come across as presumptuous, but I’d like to point out one area for potential improvement. I noticed that the stepper motor drivers inside the control box were mounted very close to each other. If you leave some space between these drivers, you could potentially reduce mysterious issues caused by heat, EMI, or EMC. Wishing you all the best and keep up the great work!
did watch all the videos from the creator.. awesome guy, awesome robot! not an easy task to get a kit out for 2k$ and write the software and give it for free... great guy!!!
I've been thinking about building a robot arm. Basically a "3rd hand" setup. Push a button puts it in free move mode. Then push the button again and it locks in place. The most generic example is soldering. Position the arm to hold the wire in place and then I can solder it together.
This is a cool idea. I could see something like this but severely simplified. The switch could be on the tool holder which would dis/engage three (potentially one) servo which locks the arm in place. A hefty servo, like the 25kg in this video, could provide the force to prevent a ball joint from slipping. A momentary button could be used for a squeeze, move, release operation.
Me too! I have also been trying to come up with a simple work light. As soon as you touch the light the brakes release... move it to a new location, release it... the brakes lock. Yeah... I know... just use an anglepoise lamp, and get over it! 😜
You made some errors during the building phase, man. Also, don't forget how much a real robotic arm costs, even a used one. I have one, and I can assure you that 99% of electronics enthusiasts couldn't even get near it or handle the thousands of pages in the manual. Chris @anninrobotics has done an incredible job at this price point, especially considering he did it alone, as you pointed out. There will definitely be some backlash due to the gearboxes. A single strain wave with zero backlash and brakes costs more than this entire kit. The software still has a lot of room for improvement, but what he's achieved, especially not being a software or embedded systems developer, is admirable. I say that as an electronics engineer who works with all this stuff as well. I'd love to help him if he's interested, particularly with the drives/motors part, to simplify the building process.
For those rising screw terminations, I've had _much_ success wrapping strand conductor around the insulation and treating the conductor as a ferrule. Torque it down until you can't anymore - and then some depending on hand strength, you'll have long-lasting connections. Works damn fine and all it costs is time.
A point on the software, what you are provided with looks to be on pair with a pretty standard industrial robot arm controller system. Which is great, and it gives all the function you need to make it move. However, what you need to learn is less about specifically this software, or any industrial robot's software, but the systematic knowledge of robot. More specifically to the problems you get at the end where robot doesn't move in the right way, it will all make so much sense after you learn the basics of robot kinematics and trajectory planning.
Very, very interesting at a reasonable price. I hope this is successful enough to lead to a major revision that can address the issues you noted with repeatability, precision and rigidity because I'd be quite interested even at a slightly higher price.
This is the only usable DIY robot as far as i could see on the net, and the designer is very good at it. Being open source is just a bonus, and the reasonable part prices are the cherry on top. No, i do not have anything to do with it/them, and i have not built one yet but i will. I work with KUKA robots...
The Ender 3 of robot arms! Been following the project a while but can’t quite dedicate the studio space to it yet. I’d love to see if you could make it sort and inventory small parts in your studio with the vision capabilities (or barcodes)
Awesome, I've been following Chris Annin for around seven years already. Still never got into making the arm since budgetwise I don't have a reason to buy it, but I love his work and this robot arm should really become more popular so maybe it will develop further and further into a really good and solid product. I think this is the best robot arm you can get as a hobbyist. Maybe one day, when I have a disposable income, I will definitely get one. Very happy to see you build one Thomas! :)
I found this project some years ago, and have been interested in printing it for a while. but there are some things that's been in the way (except cost), and one is that i would love to see it using Slip Ring connectors instead to be able to move freely without risking any cables getting tangled. But awesome build and nice to see the process!
Oooh I'd love to see Jeremy Fielding build one of these and see what his opinion is vs the one he built from surplus parts. Granted, Jeremy's is massive in comparison, probably weighs as much as a small milling machine, and probably cost 10x as much but still, I'm curious what he would think.
Great Video about a very lovely Project! I 've built a BCN3D Moveo back in 2018 and used Chris' Wiring diagram and software to get it to move. He helped me getting the Arm set up in the software and i had real fun building and playing around with this thing... That was my first big project which lead to me taking off in the DIY/Maker kind of stuff.
I’d love to see you try and do some welding with this! (Background: I took a year of welding at a local community college but my hands are too shakey (damn essential tremor!) to get clean welds. I have all sorts of project ideas though, and it would be great to see how well this robot fairs in the task!)
Great video. I am too apprehensive to buy this kit until I build my skill sets. However, I appreciate the detailed walk through of the build. I am interested in the kit and can see that years of thought and skill went into building it.
I don't know if I missed it in the video but does the tapered roller bearings not get any preload? I'm pretty sure tapered roller bearings are always supposed to have a preload applied to them.
I think that was what Tom was referring to at 12:55, when he pointed out the tapered roller bearings being preloaded by a flat thrust bearing. I took it that he thought there should be opposed tapered roller bearings, with preload, which would give better axial control.
for use as a camera robot: You could use a camera with manual focus and control the focus ring with a servo. That would add some cool depth of field effects in your camera movements. Also how fast is the arm? Because in film studios they use these kind of tools for fast movement during slomo shots
You know, for the price point, and being a one-man operation, this isn't too shabby. It also makes a good starting point. All the parts are there, even if they aren't the best for function. You could probably retrofit some more precise motors, better gears and belts, and rebuilt joint bearings, to get a more precise machine.
It's actually exceptional what he's pulled off. To reduce deflection and backlash to the degree people would want it would easily push this build north of 10k. Even industrial 6 axis robots have these same issues that sometimes have to be worked around especially in vision guided applications.
You could try addingfriction to the axes to damp out vibration. Either using a much thicker grease, or 3d printed brake pads against the cylindrical parts
very interesting, as it happens I'm currently building a large custom robot arm for my camera setup as an upgrade to my previous. Still a ways to go before I find out if I've made it nearly rigid enough. But I'm actually glad to see that these small kits are not perfect, at least I can tell myself it might be worth the effort ;-)
I wonder whether you could add some type of physical damper between the arm and the camera. Two examples which come to mind are the suspended shock mount for microphones and sorbothane washers.
A pair of opposed Angular Contact Bearings - the kind used in bicycle necks would still be overkill, but could replace those massive conical roller bearings in each joint. Cheaper, lighter, easier to design for. Fit for purpose.
Me: I have a busy day job and I just started a 3D printing side business. I don't have the budget, shop space, or the time for any distractions. Tomas: Want to build a kit robot? Me: Yes!
Excited to see if this inspires other designers or companies to make a competitor I think there's too many caveats for me personally to put $2k into AR4 but maybe AR5. I'd really love to slap something like this on rails or maybe even treads and have it do part removal or build plate swaps for print farm automation. The off the shelf print farm automation like Mosaic Array are way outside my price range.
Looks very nice. Metal is just better than plastic for mechanics. If we could get low cost metal 3D printers I think they would be great for robot parts and both laser light and iron powder can be very inexpensive. There really is no reason for robots to be expensive.
I can solve your wire extension issues; Wago. They make inline splices for their 221-style lever nuts and I am _certain_ there are plugs you can just fasten on without soldering meant for industrial applications, _also_ in the 221-style.
Yes, but if you read the pinned comment at the top here, the designer states that TS's belt tensions were way too low and that contributed significantly to the observed overall wobble. Would be nice to see a followup showing the change, if any, after increasing belt tension as the designer suggested in his comment.
As a D&D gamer, I would love to see a robot arm capable of moving miniatures on a map, that is linked somehow to a mapping software, and having figurine movements correspond to token movement on the D&D map.
for camera moves, could you make the shot take twice as long, hopefully reducing shake, hopefully providing more data for stabilization to work with, and then play it back at double speed?
Seeing it all assembled and tested it doesn’t look as impressive as it initially did. That is a huge amount of wobble and flex in it. That 2 kg payload rating is very generous, if it wobbles that much lifting a small camera how is it going to handle 2 kg? 2 kg may be the theoretical maximum based on motor torque but usable payload capacity seems to be much lower. It is still impressive being the work of one guy but in terms of functionality and practicality it isn’t as impressive. The motors having encoders but not being able to recover from skipped steps is odd, why isn’t even basic closed loop control added? Based on the capabilities of the robot the teensy likely isn’t being stressed much, it should be more than capable of running closed loop control on the motors. Maybe this is planned for a future update?
I always wanted a robotic arm for camera shots - I still do, but the footage you got is still too shaky. I am glad you acknowledged it. I am using a MUCH simpler rig for circular shots and even mine has some shakiness too. Nice project, Thomas! Loved watching it! EDIT: 15:24 GEEEZ! Ha ha ha, I thought what I was seeing BEFORE was the raw footage! Naahhhh, too expensive, too shaky. I need to figure out something different 🤣
You could mount some really long rods to the back of your table top for the robot arm to move all the way back and forth on for some killer shots...like face tracking for instance.
I would love to see a smooth camera arm (this but more refined) and a buildplate shelf system where the arm gets commands to put in a finished buildplate in a shelf system and it knows how tall you're prints are in order to avoid crashing in to already placed buildplates.
Needed thing is Need to Stir the Pan or Vessel which contains some liquid or solid food items that is under semi or full flame so need the below action plans via customisable programming via app as 1. Stir, 2.Turn to Full flame / Semi or off the flame, 3. Take the pan out of the Stove. This is one action from this Arm. Is it possible sir? So this can be purchased by the Cook or in confectionery to complete the massive amount of time and work.
Cool project. Really interested in what uses besides camera movement you can up with. I've felt like doing a project like that myself, but space is limited and i struggle to justify it aside from the fun of building it.
Tom. You can get smooth video out of this arm if you let the camera stabilise between each shot. Then stitch the pictures back out like a Timelapse! Edit: Nevermind I realised how slow this would be and the tolerance/backlash would still make the video wobble..
haven't built mine yet, but now it looks more complicated than I've imageined. In my application, the repeatability and shaking is not that big of a deal. WOuld love to see more videos about the Arm from you
Love the idea of this, but as the video shows and a lot of the comments talk about, this one project only introduces more projects to do, such as trying to fix or mitigate the backlash, making the whole arm more rigid, software improvements, etc.
it would be interesting to get the robotic arm to print something. How about something simple, like an object in vase mode? it's obvious that at the amplitude of the backlash, there's no way you can produce decent prints, but I think in vase mode, the robot could manage.
This is very cool. Not the best use case, but as a demonstration of its motion control, could you fit a hot end and print a benchy? Would require post-processing to convert the GCODE to whatever this runs.
The software can also read gcode now. One could wire the extruder motor as J7. The nozzle should better be as large as possible to accomodate for the comparatively low accuracy.
Um die Druckplatten aus dem Drucker zu holen könntest du QR sticker bei der Grifffläche platzieren, dann muss der Roboter Arm nicht so genau sein, weil er seine Reale Position im Verhältnis zu der Platte bestimmen kann 👌 Sorry that i wrote that in german 😅
having a robotic arm is one thing, it's very rare to see the common man do anything useful with it, programming the desired movements is the difficult part. Ive done it for some applications, linear tracks on the base def makes many tasks much easier. Think hard about what you would actually need a robotic arm for, before you go spend time on it.Random repetative tasks around the shop are much more difficult to make worthwhile than very long production runs. (vs set up time)
I use my AR4 constantly and find that crimping on a ferrule is less reliable then properly tinning and then soldering the wires. However, in the robot's electrical box, it is better to crimp the wires to a ring connecter, then attach and secure around the screw on the terminal block. TLDR: use tin and solder around moving parts, crimp wires around non moving areas
@@Estop117 I test the robot in commercial kitchens. The robot is good for small automation. Take that and upgrade the smaller motors to high torque steppers and you have a robot that can move fry baskets and other heavy objects
Forgot which channel, but there was someone who used an old German car manufacturer robot arm and got to work in a woodworking place and they had put an router on it. They did some cool stuff with that, though that has been some years ago. ( maybe they did some metal work as well)
Heh... 😏 I always thought these DIY Robot Arms could only really serve as Camera Dollys but apparently even that isn't a viable Project 🤣 So, in the end it leaves them only suitable as a physical Training Platform? How much use could one get out of them for that purpose considering the real Deals usually run on proprietary Hard / Software? 🤔
Thanks for the video of this awesome project! 👌🏼 So if the motors got encoders is it possible then to make a manual (by pushing the arm) movement and let the robot repeat it? Or even edit the spline to make it smoother? 🤔
Not really. The robot mechanics attached to the gearbox would be overloaded and fail before sufficient torque is achieved to back drive those gearboxes.
Yo Tom doing actual mechatronic engineering on the channel would be way cool. Yes camera arm is perfect because the cameras aren't nearly heavy enough to justify nearly this much finely machined alu in construction, and we can all 3D print, right, and there's any number of uses for a smooth and repeatable light-duty arm.
Thomas,
Thank you for building the AR4 and highlighting some of its features. I did want to touch on a few of the comments you made. In the overview section of the manual I do mention pre-applying solder to wires being joined together - I find it easier to pre-apply solder or tinning the ends - and then bring them together with the iron rather than trying to hold the wire ends together and hold the solder and hold iron at the same time, not having 3 hands - it helps to pre apply the solder. None of the wires going to the breakout board call for tinning so I'm not sure about your comments on that?
On page 143 I do have some groups of wires soldered together to help group them going to the 3 screw terminals as its a tight fit and difficult to maneuver them into position without them being connected but you could certainly use ferrules in this step if needed.
At one point in the past the design did utilize plug connectors and building a wiring harness. Given different applications, motions and articulations all the low cost plugs I sampled proved to fail over time. With this small arm and the limited cable routing and cable arc lengths, direct solder with the solder joints in strategic locations using heat shrink proved to be more reliable, less bulky, less costly and not as time consuming as crimping and inserting numerous plug pins. The primary goal of this project from day one has been to realize a usable robot and at a very particular price point. I've worked with industrial robots my entire career and its always been a frustration that any usable robot was out of reach. There is an absolute threshold on the price as most educators have a budgetary limit so I have made it priority number one to stay under that limit. This drives many of the design aspects, The motors for example are off the shelf variants and cannot be fully customized without adversely affecting the price. There is a limit as to what OMC can customize on these coming from the factory. The machined components are kept to an absolute minimum and as many as possible are cut from flat sheet material. This also drives the bearing designs and tensioning designs as custom machined threads and spindles for locknuts for example is not in the cards at this price point. It also drives some of the belt selections.
I did notice the belt tension on your build was far too loose resulting in a good amount of play. Here is a quick video of the forced deflection on my build. (well it looks like I cant post a link in comments but I will post in on my channel or the forum) - Making the statement that "This robot arm is neither accurate nor precise, rigid or smooth" seems a bit harsh considering. The AR4 project is always under improvement, its not perfect but like I mentioned to you in an earlier email the robot is designed for pick and place, welding and handling operations. A great deal of effort has gone into this project, I know you have a great deal of experience and a wealth of knowledge in all manner of machines and mechatronics and your design suggestions are certainly well founded but I wanted to explain these aspects of the project, and hope you will convey these points to your audience.
Thank you,
Chris
I had tried many different robot arms, but no one beats AR4.
Another big advantage is that you can discuss problems directly with Chris Annin.
His manual is the best and most detailed I have ever seen for such a product in this price class.
I got manufactured custom-made motors at StepperOnline, and I know how many motors needed to order to get them to a fair price.
I don't find some of your criticism fair compared to the price for an AR4.
Last .. sorry for my bad English, I'm from Denmark 🇩🇰 😊
Thanks for your work over the years Chris!
Thanks for the educations and making robotic arm accessible.
Thanks, now I understand why there is no plug connectors:
Quote: "At one point in the past the design did utilize plug connectors and building a wiring harness. Given different applications, motions and articulations all the low cost plugs I sampled proved to fail over time. "
This is the first I’ve heard of this arm, its incredible! I’m setting up a workstation for my robotics projects later next month, I wish I could set up the arm to keep my tools organized! It’d be a fun project
4:29 The reason why a tinned stranded wire will fail in a screw terminal is twofold:
1. Tinning a stranded wire will introduce a weak point where the solder wicks into the wire. If the wire doesn't move, this isn't a problem. But if it's part of a moving system, that wire is now much more likely to break where the solder wicked up. Now, I'm told you _can_ get away with tinning as little of the wire as possible, but I've never seen anyone pull that off.
2. Solder is prone to "creeping" under pressure, it's not really meant to hold its shape when it's squeezed. Over time, the soldered wire will slowly deform, loosening the connection with the wire, meaning you have to go back and tighten the screws. I've actually encountered this after about 2 months, and it is a huge pain.
Better to crimp on a ferrule to each of those wires and never have to worry about them until something happens on the other end.
Instead of ferrules I like to solder male breadboard headers to the end of wires if they're going to be screwed into terminals. I think ferrules are probably the better solution for most cases but I don't have a crimp tool and many ferrules are way too thick to fit into very small terminals
@@catdisc5304 ferrules are sized based on the wire diameter, if a wire with ferrule is too large to fit in a screw terminal there is probably a good chance the wire is too thick anyway and the wire can handle much more current than the screw terminal.
Ferrule crimping tools are very cheap and simple to use, much simpler than other connector types.
Heck yea, ferrules! Crimp once and never worry about a lose contact again!
@@conorstewart2214 yes, but you do want a good one, cheap crimping tools can be awful
If you're spending 2K on a robot you might as well spend a tiny bit more to get reliable and properly crimped connectors
Hats off 👏 to Chris for managing such a massive product / project. Even writing the guide must have taken weeks.
its been take years and its fine. sold some lol
Instead of tinning wires it is better to use ferrules. Cheap and reliable
I was surprised to see that is the official way to do it, it is well known now with 3D printer failures that you do not tin wires that go into screw terminals.
@@conorstewart2214 also there are 2 types of screw terminals. One have additional sheet metal inside terminal to spread force over whole connector, it also acts as a spring so this connector have harder time becoming loose. And there is a second one, where wire is kept in place by screw directly. Second one can be used only with solid wires and ferrules, as stranded wires are simply getting crushed and cut inside by rotating screw.
@@conorstewart2214i thought Thomas covered this before too. Either way good to mention this as always.
I find it's more secure to just ditch the ferrule personally, if you don't use the right one and it's not properly crimped, the wire can slide out while the ferrule is left behind in the screw terminal...
Ferrules aren't used for 230V wiring in houses and stuff either, and they will never budge
@@PureRushXevusyou do not use ferrules on solid wire.
Their main purpose is to hold the ends of stranded wire together so the current flows through all strands not just those few the screw terminal caught.
For the very small wire made of delicate strands the ferrules provide protection from the screw damaging and literally cutting off some strands.
Thick solid wire doesn’t need ferrules.
They also provide some strain relief for thin wires.
Not sure if I missed the price, but a quick look at the link says its about $1200 for the kit, and $800 for the motors. Not bad all things considering, could certainly help a mom & pop shop get some basic automation going
I saw such on aliexpress for 400...but quality can be anywhere from excellent to shit
0:21 You did but it is good to have it written too.
Shockingly cheap with precision machined metal parts
what kind of automatization can you achieve with this accuracy and stability? Plus all the effort of building it, which is almost impossible for a normal person who is not a tinkerer.
Ive been looking at cobots for my shop, and was quoted about 4K for one with the full setup and service. I keep looking at these projects, and almost every one of them ends up on github, and that to me is like water skiing on the moon.
Having been a developer for a big robot company in my past, that rail design was awesome game changer for us. There are still zero locations, but yes, they are reduced. Next big change for us was 6 DOF Force sensor with a 3D Laser camera...Best job EVER!
shim the bearings with some foil. when splicing, stagger the lengths to avoid a lump in your cable wrap.
Axis 2 and 6 are designed OK. Other axes makes me say "what was he thinking?". Trapezoidal belt for axis 1, 3 and 4. Leadscrew on axis 5... Yes, it moves center of masses down and reduces required torque, but it would be much better to grab beafier gearboxes with higher reduction rate and drive joints directly.
As for electronics, he could install TMC5160-BOB in the back of each motor, connect all of them via SPI, and control everything directly from RaspberryPi.
but your suggestions would all increase the cost, no?
@@ferriswhitehouse1476 Not much. TMC5160 costs as much as DM542, but much more advanced and can correct step loss. And cost could be cut with other changes like dirt cheap magnetic encoders instead of expensive optical ones and only one very simple and cheap MCU would be required. Also wiring would be simplified - TMC5160 can be daisy-chained via UART, so only 1 UART wire and 2 Power wires would be required.
@@TheNamelessOne12357 okay sure for the electronics ill agree. It was released a few years ago so maybe those options weren't available, I'm not sure. Maybe a user could do those upgrades on their own. For the mechanical aspect though I would imagine its a pretty big cost jump. If you put more weight up on the ends of the arm then everything below it needs to be beefier as well. So upgrading all gearboxes and motors and frame components.
@TheNamelessOne12357 Chis is a Robotics Engineer by day job. The AR robots he designed for free basically, to be as cheap as possible. I asked him about the gear ratios and he said he made it this way so its speed is useful. If you look at the arduino/teensy code, it's quite advanced now. The windows app is just a UI to interface with the microcontroller that does all the IK calculations like ATAN2 etc, and synchronisation of joint moves.
The serial on the microcontroller is agnostic to the UI platform. It could be Android, pi, windows. It's just the UI was designed for windows.
-Ken
14:57 is the money shot 😅 Does that mean I need to build one myself now for awesome promo shots?
Stefan: I wonder how easy it is to steal a six axis robot....
please do, it would be nice to get your opinion and use cases on it :)
Please build one as well, this needs more perspectives.
Nope, not one. You probably need multiple.
For example to make "helicopterview" shots of parts while they are almost breaking in your tensile stress machine.
And also one for your promo shots.
One to feed your filament recycler and most importantly one for pooring a cup of coffee or tea during your recordings.
Hi, robotic engineer here. I made this robot a while ago when he was at the AR3 version, this made me learn how important precision machining and zero backlash gearbox is important for robots. Also his kinematic his questionable. While it does work, you need to develop your kinematic with singularities in mind and all the possible configurations of the robot for that position. Instead he limited the joint limit values to avoid having more than one configuration, but this is not optimal, dangerous even.
Would you recommend another kit then?
What is dangerous about limiting the joint limits?
@@tec4303 I'm no expert, but I would assume either failure of a joint from higher force loading than anticipated or risk of toolpath collisions from having to work around over-constrained IK paths.
@@tec4303 even with limited joints range, its possible to have multiples configuration in certain positions which can lead to the robot changing configuration mid-path. A linear movement (MoveL) is usually made from multiple targets very close to each other along a line, if the robot calculate that there is more than one solution to reach these targets, it has to choose which one to use and stick to it for every targets following that line, or else the robot might twist its wrist 360 degree suddently at maximum speed to keep the linear speed and that is dangerous.
@@Hazdazos What are some similar ones you know of? THOR, and BCN3D come to mind.
I've been watching Chris's channel for a few years. I love that his work is getting more mainstream traction! I've been wanting to make an arm for myself since I've seen his channel. His videos are amazing to help understand how things work!
For mating machined parts, I wonder if they could machine small lines that line-up to help prevent putting parts on backwards.
They could, especially if they are machining all those parts anyway, even just small engravings on the surface, like a line on each part, just match the lines, would be good.
However this likely isn’t a priority, the machine has a lot of other mechanical issues that would be more important to solve than making it easier to assemble.
Oh boy that backlash. I guess I'll wait for AR5. Feedback: Hall effect sensors are more accurate than limit switches. There are even hall effect encoders to check the actuall position.
Or even optical endstops. Hall sensor are unfortunately temperature affected, so depending on the use case optical might be the more repeatable option
I've followed Chris Annin's project since de AR2. He's done a beautiful work on that thing.
Good "review" of this kit. Even with restrictions I think for this money you get an awsome kit.
@12:33 you say the motors don't meet the backlash of 0.25 degrees but you measure the complete robot, not just the motor, so that means you also measure any play in the bearings.
I use a Kuka KR180 and with that one, motions are also not always smooth. Depending on the load (I have a 30 kg spindle motor mounted as end effector) I can see some jitter during moves and expecially when the brakes are released from the motors there is some movement to compensate for changing load on the motors.
The AR4 is still an amazing development and it does have some nice uses for parts picking applications
The manual for the AR4 is well worth a read. Love the details put into how all the control hardware is wired together.
I feel like we need to use the same motors that are in DJI gimbals and similar. They have almost zero backlash
Take a look at the Parol 6. It’s more expensive at around $2300 in kit form but the movement repeatability tests I’ve seen look impressive and it’s open source.
Hello! I really enjoyed watching your intriguing video. I hope this doesn’t come across as presumptuous, but I’d like to point out one area for potential improvement. I noticed that the stepper motor drivers inside the control box were mounted very close to each other. If you leave some space between these drivers, you could potentially reduce mysterious issues caused by heat, EMI, or EMC. Wishing you all the best and keep up the great work!
Robot: what is my purpose?
You're my robot buddy!
Robot: oh my god...
did watch all the videos from the creator.. awesome guy, awesome robot! not an easy task to get a kit out for 2k$ and write the software and give it for free... great guy!!!
Best Use: Accidently knocking your coffee cup over. Covered by joint slop / backlash and gives you a nice 'look' opp.
I've been thinking about building a robot arm. Basically a "3rd hand" setup.
Push a button puts it in free move mode. Then push the button again and it locks in place.
The most generic example is soldering. Position the arm to hold the wire in place and then I can solder it together.
This is a cool idea. I could see something like this but severely simplified. The switch could be on the tool holder which would dis/engage three (potentially one) servo which locks the arm in place. A hefty servo, like the 25kg in this video, could provide the force to prevent a ball joint from slipping. A momentary button could be used for a squeeze, move, release operation.
Me too! I have also been trying to come up with a simple work light. As soon as you touch the light the brakes release... move it to a new location, release it... the brakes lock.
Yeah... I know... just use an anglepoise lamp, and get over it! 😜
Omg I want it! I played with and programmed a fanuc when I was in college and loved the little training arms they had and always wanted my own.
You made some errors during the building phase, man. Also, don't forget how much a real robotic arm costs, even a used one. I have one, and I can assure you that 99% of electronics enthusiasts couldn't even get near it or handle the thousands of pages in the manual. Chris @anninrobotics has done an incredible job at this price point, especially considering he did it alone, as you pointed out. There will definitely be some backlash due to the gearboxes. A single strain wave with zero backlash and brakes costs more than this entire kit. The software still has a lot of room for improvement, but what he's achieved, especially not being a software or embedded systems developer, is admirable. I say that as an electronics engineer who works with all this stuff as well. I'd love to help him if he's interested, particularly with the drives/motors part, to simplify the building process.
For those rising screw terminations, I've had _much_ success wrapping strand conductor around the insulation and treating the conductor as a ferrule. Torque it down until you can't anymore - and then some depending on hand strength, you'll have long-lasting connections. Works damn fine and all it costs is time.
A point on the software, what you are provided with looks to be on pair with a pretty standard industrial robot arm controller system. Which is great, and it gives all the function you need to make it move. However, what you need to learn is less about specifically this software, or any industrial robot's software, but the systematic knowledge of robot. More specifically to the problems you get at the end where robot doesn't move in the right way, it will all make so much sense after you learn the basics of robot kinematics and trajectory planning.
Very, very interesting at a reasonable price. I hope this is successful enough to lead to a major revision that can address the issues you noted with repeatability, precision and rigidity because I'd be quite interested even at a slightly higher price.
The CNC parts look so good!
This is the only usable DIY robot as far as i could see on the net, and the designer is very good at it.
Being open source is just a bonus, and the reasonable part prices are the cherry on top.
No, i do not have anything to do with it/them, and i have not built one yet but i will. I work with KUKA robots...
The Ender 3 of robot arms! Been following the project a while but can’t quite dedicate the studio space to it yet. I’d love to see if you could make it sort and inventory small parts in your studio with the vision capabilities (or barcodes)
"The Ender 3 of robot arms!" that doesn't sound like a compliment lol
Awesome, I've been following Chris Annin for around seven years already. Still never got into making the arm since budgetwise I don't have a reason to buy it, but I love his work and this robot arm should really become more popular so maybe it will develop further and further into a really good and solid product. I think this is the best robot arm you can get as a hobbyist. Maybe one day, when I have a disposable income, I will definitely get one. Very happy to see you build one Thomas! :)
Chris Annin's robot arm is pretty cool. I would love to build one
I found this project some years ago, and have been interested in printing it for a while. but there are some things that's been in the way (except cost), and one is that i would love to see it using Slip Ring connectors instead to be able to move freely without risking any cables getting tangled. But awesome build and nice to see the process!
5:47 you need to pack those bearings with grease properly and it will take up some of the play, as well as protect the bearings from running dry...
Kudos on the edit of the video. Appreciate the cutting to match the music.
I dare you to put a supervolcano on it :)
Oooh I'd love to see Jeremy Fielding build one of these and see what his opinion is vs the one he built from surplus parts. Granted, Jeremy's is massive in comparison, probably weighs as much as a small milling machine, and probably cost 10x as much but still, I'm curious what he would think.
Great Video about a very lovely Project! I 've built a BCN3D Moveo back in 2018 and used Chris' Wiring diagram and software to get it to move. He helped me getting the Arm set up in the software and i had real fun building and playing around with this thing...
That was my first big project which lead to me taking off in the DIY/Maker kind of stuff.
I’d love to see you try and do some welding with this!
(Background: I took a year of welding at a local community college but my hands are too shakey (damn essential tremor!) to get clean welds. I have all sorts of project ideas though, and it would be great to see how well this robot fairs in the task!)
Theres videos on TH-cam with this working as welder on custom build
Great video. I am too apprehensive to buy this kit until I build my skill sets. However, I appreciate the detailed walk through of the build. I am interested in the kit and can see that years of thought and skill went into building it.
Great review.
And nice project. One guy came so far! Cheers to him🎉
Would totally build one if I had a use for it. I understand its use in repetitive manufacturing tasks, but at home?
I don't know if I missed it in the video but does the tapered roller bearings not get any preload? I'm pretty sure tapered roller bearings are always supposed to have a preload applied to them.
I think he mentioned preloading with grub screws in the beginning
I have a feeling a couple of grub screws aren't going to be preloading roller bearings that large an appropriate amount.
I think that was what Tom was referring to at 12:55, when he pointed out the tapered roller bearings being preloaded by a flat thrust bearing. I took it that he thought there should be opposed tapered roller bearings, with preload, which would give better axial control.
for use as a camera robot: You could use a camera with manual focus and control the focus ring with a servo. That would add some cool depth of field effects in your camera movements. Also how fast is the arm? Because in film studios they use these kind of tools for fast movement during slomo shots
Congratulations for this awesome project Thomas!
You know, for the price point, and being a one-man operation, this isn't too shabby.
It also makes a good starting point. All the parts are there, even if they aren't the best for function. You could probably retrofit some more precise motors, better gears and belts, and rebuilt joint bearings, to get a more precise machine.
It's actually exceptional what he's pulled off. To reduce deflection and backlash to the degree people would want it would easily push this build north of 10k. Even industrial 6 axis robots have these same issues that sometimes have to be worked around especially in vision guided applications.
I didn't expected you to build that thing lol.
It's a awesome project.
You could try addingfriction to the axes to damp out vibration. Either using a much thicker grease, or 3d printed brake pads against the cylindrical parts
very interesting, as it happens I'm currently building a large custom robot arm for my camera setup as an upgrade to my previous. Still a ways to go before I find out if I've made it nearly rigid enough. But I'm actually glad to see that these small kits are not perfect, at least I can tell myself it might be worth the effort ;-)
👀
Very cool kit, but the use-cases would involve way more precision in the end, imho.
Type in robot farmer annin robotics. You can get an in depth look at the robot and how its being used with precision.
Yeah but no one would be able to afford it then. Industrial robots of this scale can easily be more than 15k.
I've always found these interesting but having hard time finding a good use for these privately
I take it they're not the pleasure model then
I wonder whether you could add some type of physical damper between the arm and the camera. Two examples which come to mind are the suspended shock mount for microphones and sorbothane washers.
A pair of opposed Angular Contact Bearings - the kind used in bicycle necks would still be overkill, but could replace those massive conical roller bearings in each joint. Cheaper, lighter, easier to design for. Fit for purpose.
Me: I have a busy day job and I just started a 3D printing side business. I don't have the budget, shop space, or the time for any distractions.
Tomas: Want to build a kit robot?
Me: Yes!
Yeah I have no need for one but its just nagging at my brain now
Excited to see if this inspires other designers or companies to make a competitor I think there's too many caveats for me personally to put $2k into AR4 but maybe AR5. I'd really love to slap something like this on rails or maybe even treads and have it do part removal or build plate swaps for print farm automation. The off the shelf print farm automation like Mosaic Array are way outside my price range.
Looks very nice. Metal is just better than plastic for mechanics. If we could get low cost metal 3D printers I think they would be great for robot parts and both laser light and iron powder can be very inexpensive. There really is no reason for robots to be expensive.
Machined parts vs 3d printed? you must know that 3d printed metal parts are machined in cnc to get more prescision.
I can solve your wire extension issues; Wago. They make inline splices for their 221-style lever nuts and I am _certain_ there are plugs you can just fasten on without soldering meant for industrial applications, _also_ in the 221-style.
Great video! Thanks!
Nice toy - but still pretty expensive for that amount of wobble 😐
Yeah i'd definitely think something more accurate would be a better compromise than sheer load bearing capacity.
Vibration from the steppers is probably a main source of the wobble.
@@elHippieSupremo I don't think so.
Yes, but if you read the pinned comment at the top here, the designer states that TS's belt tensions were way too low and that contributed significantly to the observed overall wobble. Would be nice to see a followup showing the change, if any, after increasing belt tension as the designer suggested in his comment.
@@steveh8724 There is no pinned comment and designer's comment is much more recent than this discussion thread.
No doubt. You need to get a direct extruder hotend on that AR4 and make it print❤
As a D&D gamer, I would love to see a robot arm capable of moving miniatures on a map, that is linked somehow to a mapping software, and having figurine movements correspond to token movement on the D&D map.
for camera moves, could you make the shot take twice as long, hopefully reducing shake, hopefully providing more data for stabilization to work with, and then play it back at double speed?
Seeing it all assembled and tested it doesn’t look as impressive as it initially did. That is a huge amount of wobble and flex in it. That 2 kg payload rating is very generous, if it wobbles that much lifting a small camera how is it going to handle 2 kg? 2 kg may be the theoretical maximum based on motor torque but usable payload capacity seems to be much lower.
It is still impressive being the work of one guy but in terms of functionality and practicality it isn’t as impressive.
The motors having encoders but not being able to recover from skipped steps is odd, why isn’t even basic closed loop control added? Based on the capabilities of the robot the teensy likely isn’t being stressed much, it should be more than capable of running closed loop control on the motors. Maybe this is planned for a future update?
I like how the lights are flashing at 7:30 as if it's protesting all of the rough hammering. "ouch! ouch! ouch!"
Add a gyro to the camera head so you can use gyroflow for best results on stabilization!
I always wanted a robotic arm for camera shots - I still do, but the footage you got is still too shaky. I am glad you acknowledged it. I am using a MUCH simpler rig for circular shots and even mine has some shakiness too. Nice project, Thomas! Loved watching it! EDIT: 15:24 GEEEZ! Ha ha ha, I thought what I was seeing BEFORE was the raw footage! Naahhhh, too expensive, too shaky. I need to figure out something different 🤣
Type in robot farmer annin robotics. I interviewed Chris and you can see this robot used for camera footage and its not shaky.
Despite the limitations that's an incredible amount of robot for the price.
You could mount some really long rods to the back of your table top for the robot arm to move all the way back and forth on for some killer shots...like face tracking for instance.
I would love to see a smooth camera arm (this but more refined) and a buildplate shelf system where the arm gets commands to put in a finished buildplate in a shelf system and it knows how tall you're prints are in order to avoid crashing in to already placed buildplates.
Needed thing is Need to Stir the Pan or Vessel which contains some liquid or solid food items that is under semi or full flame so need the below action plans via customisable programming via app as
1. Stir,
2.Turn to Full flame / Semi or off the flame,
3. Take the pan out of the Stove.
This is one action from this Arm. Is it possible sir?
So this can be purchased by the Cook or in confectionery to complete the massive amount of time and work.
Totally wholesome. I feel the robot has a strong arm, bro will beat people a strong arm contest
I love that bots are finally becoming affordable.
Cool project. Really interested in what uses besides camera movement you can up with. I've felt like doing a project like that myself, but space is limited and i struggle to justify it aside from the fun of building it.
astorino robot is also 3d printed. It uses harmonic drives and closed loop steppers. Functionality like normal industrial robot :)
Tom. You can get smooth video out of this arm if you let the camera stabilise between each shot. Then stitch the pictures back out like a Timelapse!
Edit: Nevermind I realised how slow this would be and the tolerance/backlash would still make the video wobble..
haven't built mine yet, but now it looks more complicated than I've imageined. In my application, the repeatability and shaking is not that big of a deal.
WOuld love to see more videos about the Arm from you
Love the idea of this, but as the video shows and a lot of the comments talk about, this one project only introduces more projects to do, such as trying to fix or mitigate the backlash, making the whole arm more rigid, software improvements, etc.
it would be interesting to get the robotic arm to print something. How about something simple, like an object in vase mode? it's obvious that at the amplitude of the backlash, there's no way you can produce decent prints, but I think in vase mode, the robot could manage.
This is very cool.
Not the best use case, but as a demonstration of its motion control, could you fit a hot end and print a benchy?
Would require post-processing to convert the GCODE to whatever this runs.
Did you see how much it vibrated? Printing is a nope
The software can also read gcode now. One could wire the extruder motor as J7. The nozzle should better be as large as possible to accomodate for the comparatively low accuracy.
My dream proyect, greetings from Argentina
Finally robot arms coming to the house.
It would be nice to disable the steppers and use the encoders to record motion, might be heavy to wrestle it around thou. 😂
Cheap gearboxes usually have way too much friction to be back drivable. Robot arms that can do that are way more expensive usually.
Um die Druckplatten aus dem Drucker zu holen könntest du QR sticker bei der Grifffläche platzieren, dann muss der Roboter Arm nicht so genau sein, weil er seine Reale Position im Verhältnis zu der Platte bestimmen kann 👌
Sorry that i wrote that in german 😅
Danke, ich versteh dich sogar auf Deutsch 😅
@@MadeWithLayers Ja bei dir wusste ich das ja 😅 Das Sorry war an den restlichen Kommentar bereich gerichtet 😅
@@MadeWithLayers Please my dude can you make a raw footage of the wiring????? im so very lost
having a robotic arm is one thing, it's very rare to see the common man do anything useful with it, programming the desired movements is the difficult part. Ive done it for some applications, linear tracks on the base def makes many tasks much easier. Think hard about what you would actually need a robotic arm for, before you go spend time on it.Random repetative tasks around the shop are much more difficult to make worthwhile than very long production runs. (vs set up time)
What robot(s) did you use?
-Ken
Good use is: Same robot used to do diferent repetitive tasks when sitation changes and need fast adaptation.
Really like your videos.... keep them coming.
Nice electronic angle measuring device. I think I need one.
Do you know about PAROL6 robotic arm? It is an open source 6-axis 3d printed arm.
I want to build one but I have no idea what to do with it
Go for it! 🦾
I use my AR4 constantly and find that crimping on a ferrule is less reliable then properly tinning and then soldering the wires. However, in the robot's electrical box, it is better to crimp the wires to a ring connecter, then attach and secure around the screw on the terminal block.
TLDR: use tin and solder around moving parts, crimp wires around non moving areas
I'm genuinely curious. What is the use of this robot for a hobbist/small business? What do you do with yours?
@@Estop117 I test the robot in commercial kitchens. The robot is good for small automation. Take that and upgrade the smaller motors to high torque steppers and you have a robot that can move fry baskets and other heavy objects
Such a cool project
Alexandre Chapelle made a pretty neat camera rig that could probably be robotized, or the ideas, at least, could be used to design a new robot.
Forgot which channel, but there was someone who used an old German car manufacturer robot arm and got to work in a woodworking place and they had put an router on it.
They did some cool stuff with that, though that has been some years ago. ( maybe they did some metal work as well)
i think you need to incorporate a tool with a gimble mount to smooth your shots even further
Heh... 😏 I always thought these DIY Robot Arms could only really serve as Camera Dollys but apparently even that isn't a viable Project 🤣 So, in the end it leaves them only suitable as a physical Training Platform? How much use could one get out of them for that purpose considering the real Deals usually run on proprietary Hard / Software? 🤔
Thanks for the video of this awesome project! 👌🏼
So if the motors got encoders is it possible then to make a manual (by pushing the arm) movement and let the robot repeat it? Or even edit the spline to make it smoother? 🤔
Not really. The robot mechanics attached to the gearbox would be overloaded and fail before sufficient torque is achieved to back drive those gearboxes.
Will you give an update on how the Peopoly 3d printer is working for you? are you able to print abs on it with the enclosure and no issues?
Very impressive for the price tag.
Though you still have a long way to go before you can match Team Candiru camera control on their robot arm 🙂
I'm thinking the performance would probably be much better if he had actually followed the manual, tensioned the belts correctly etc..
I've always thought the perfect 3d printer would be a robot arm that can print anywhere it can reach. if it were precise and accurate enough.
Yo Tom doing actual mechatronic engineering on the channel would be way cool. Yes camera arm is perfect because the cameras aren't nearly heavy enough to justify nearly this much finely machined alu in construction, and we can all 3D print, right, and there's any number of uses for a smooth and repeatable light-duty arm.