Here is the latest AR4 robot: • AR4 MK2 6 DOF ROBOT AR... www.anninrobotics.com/ All gear drive motors and drivers available at www.omc-stepperonline.com/?tr...
Yeah, then in a few months you will see them on eBay for at least 3k..free shipping from China. This is a fully working and well made project, much respect for that, and also for allowing the whole project open source. Sad though that this kindness and generosity will be stolen and sold commercially as someone else's work. I have nothing against giving this sort of knowledge and work away, some people do. It shows good character and something more people should have. If I ever decide to use this project then a worthy gift in return would be offered.
I started writing the software probably a year maybe a little longer ago when I did the first robot, it's been a work in progress. this robot took me 3 or 4 months to design picking away at it in the evenings.
I'm only 2 minutes into this video and I gotta stop and tell you how impressed I am by this. Amazing. As an industrial programmer myself, this is awesome. I'm gonna watch the rest now.
Beautiful work on so many aspects. I was a fan of the old Radio Shack "Armatron" back in the day, your project shows how far we've come. The availability of 3D printing, online learning & collaboration, Arduino, etc is really the beginning of a new era.
Absolutely awesome! I've built a couple robot arms in past years, with 3D printers, neither anywhere as good as this one. So I totally appreciate and salute this accomplishment. Hats off to Chris Annin!
Hi robert i want to learn this thing i use Arduino for simple project but this its loking hard to mee programing by paython with Arduino chipset if there is a Chaîne or vidéos on UA-cam to explain the relation with paython and thanx bro
Yea I wonder sometimes... I thought it was kind of a cool project to share. I suppose people run across it who aren't into stuff like this but you would think they would just keep scrolling rather than go to the dark side.... trolls? Nothing better to do? Got me.
The video of the new aluminum version is here ua-cam.com/video/AeCLbhPHltw/v-deo.html - You can find all the software, instructions and print files here: github.com/Chris-Annin/AR2
Hello chris. I download the files and i just started to review. IS there any possibility to build it aluminium instead of power abs. What you think about the stepper power is enough?
We have the first half of the robot built out of aluminum - there are some minor differneces using aluminum so we are working out the bugs on the part drawings. If it all works and testing goes well I may make an aluminum parts kit available. It will take some time but im working on it.
What an exceptional project. I instantly subscribed! Thankyou for posting this. Now I'm on the edge of my seat waiting for news of any progress! Absolutely a brilliant effort! Well done.
I'm 15 and have been searching for 3D printed arms. This is by far the most precise and low cost quality thing I've seen. thanks! I can't wait for the parts list to come out.
Just found myself watching this again for the nth time. Regarding your comments here about moving the kinematic calculation into the arduino, that sounds like quite a hassle. Isn't the arduino just there to relay step/direction info to the motors (and listen to the limit switches of course)? The kinematic calculation strikes me as being perfectly suited to a computer with some proper processing power, and more easily modifiable setup and tweaking and potentially also graphical visualization, especially if you intend to release this for others to use on their own builds.
I believe you are correct on all accounts - I think its current form is the simplest and has a lot of value for others to use and modify which of course was my goal to keep it as simple as possible - also considering this was a learning process for me as well so it started simple and I built it to a point where it is now. There are probably multiple ways to do this but my thinking is that if I wanted to get into complex path interpolation like perfectly straight lines, arcs or other 3d generated paths I would need the arduino to execute a series of positions along the arc or line seamlessly with zero delay between moves - it would be needing to read ahead and be headed to the next point as it finishes the last with no delay. Currently the computer sends serial commands to the arduino and there is a limit as to the string length that can be sent. Im sending one move at a time and there is a delay between serial commands. unless there is a way to establish real time communication between the PC and the arduino you would end up with a choppy line or arc movement. as it is now the PC sends 6 joint positions to the arduino - I think I need to be able to send Cartesian position to the arduino so that it could then do the kinamatics and figure out joint angles and calculate multiple points along the line or arc path from its current position to its destination position so that it could execute many 10's or 100's of positions along that line or arc seamlessly with no delay. Im not certain but I think being able to send the arduino coordinate positions instead of joint angles would open alot of doors for CNC, printing or other types of applications. but as it is now its simple, easy to use and it fulfills its intended purpose of a simple material handling robot that can move from point A to point B - Its also good for education and hobby purposes. I dont think its best suited for material application or CNC applications but maybe thats something I can work on in the next version - perhaps a servo driven version. Let me know what you think or if you have any ideas. Im learning as I go here.....
My main concern was that the robot definition (number and orientation of axes, limb segment lengths etc) would be on the arduino, which would be a nuisance to have to keep flashing a new sketch to set up and tweak. You could perhaps store the definition in EEPROM and update it from the PC instead of re-flashing the sketch every time, but that would have its own complications. Interpolations will produce quite a lot of info to deal with and developing them with the primitive debugger-less feedback from the arduino doesn't sound like fun. I also suspect that the kind of memory needed to store a decent straight line interpolation would be beyond the spec of the arduino - sure you could limit it to whatever movement distance it can actually handle, but this is just another hassle that the PC would not have. Other than that, from an open-sourcing point of view it would be advantageous to break down the calculation stages into more discrete 'modules' that flow from higher to lower levels of control. For example, somebody might like to use their own path interpolation algorithm, which would be a lot easier if there was a clearly defined communication interface for their stage to issue commands to the next lower level (ie. which motors move where). Taking it a step further in the other direction, you might have an even higher-level stage (eg. computer vision to identify parts on a table) that would give commands to the path interpolator. I think the easier each stage can be swapped out or worked on without knowledge of other stages, the more takers you'll have for collaboration. It sounds like your main concern at this point is the speed of communication between the PC and the arduino? I wasn't suggesting that the PC would issue step pulses directly, just in case you got that impression. The arduino would still be given the desired joint positions and be required to figure out the necessary steps on its own, but it would be given those many 10's or 100's of interpolated positions you mentioned. This I think is an achievable data rate, especially if you make the communication interface a little more efficient. I looked over your sketch and I don't see any obvious reason it would be particularly slow, especially at faster baud rates. But using binary data instead of strings would help to decrease the data volume and time spent parsing strings. To have seamless movement with no delay you'll want to buffer some points on the arduino, which means you'll need to have the arduino acknowledge completed points so that the PC knows when to send more. I guess it would be helpful if acknowledgments like that worked their way back to the other higher level stages too, so that none would get too far ahead of the others, although buffering is less of a problem on the PC side. In any case, I'm pretty sure the PC to arduino connection would be able to send positions faster than the arm can physically carry out the movement. As a rough estimate, a 'packet' with 6 joint positions of 16 bit integers each, plus a few bytes for desired speed, some flags, packet ids, and other housekeeping might come to around 140 bytes. A 115200 baud hardware UART should transfer about 100 such packets per second. So the resolution of the interpolation for that case would be the distance moved per second divided by 100, eg. moving 20cm per second would be done with a resolution of around 2mm. I'm starting to get together some parts to build a little robot arm myself. I have plenty of programming experience but only just started with steppers and actuation recently when I built a little CNC machine. The inverse kinematic calculation stuff gives me a headache just to look at, so I am thinking to fudge it with a 2D physics library for games (eg. Angry Birds, Hill Climb Racing). It supports joints with limits and would allow setting the position of the two arm ends and simply reading off the angles of the joints. That would handle the main arm joints in their 2D plane, for a typical arm the other degree of freedom is cylindrical rotation which should not be too hard. Since this library is normally used in games with dozens of joints and constraints and typically running at 60 frames per second I have no doubt it would be able to keep up speed-wise. I'm not sure how the accuracy of this method would be though.
oops, just noticed my packet size calculation was using 16 byte integers, not 16 bit, I was thinking that number came out a little too large heheh. So a typical packet (with 32 bit integers this time) would be more like 56 bytes or 250 packets per second, ie. about 1mm resolution at 25cm/s
THIS was the reason I purchased a 3D printer. I'm fiddling for small stepper motors and micro servos at the moment. I printer a my arm and I'm just assembling it using an old PC power supply. Thanks for the video and the time it took! Now I'm excited all over again. :)
Amazing work! The dedication to see a project like this from concept to actually making it work is incredible. Not to mention producing a Bill of Materials and an Assembly Manual and sharing all this for free. Not to mention all the skill sets needed, mechanical engineering, electrical engineering, computer programming, CAD modeling, 3D printing, then playing mechanic, electrician, robotics, to assemble the components. I hope you get paid very well for whatever you do for living because not many folks are capable of this. - Thanks for sharing Chris
Chris, every once in a while someone comes along to give you an ooh-ahh day. Congratulations, you're it for this week! Looking forward to making my own 3 axis bed CNC and cutting a robotic arm to go on the cross slide to replace the single axis up /down cutter head movement. Put a collet chuck where your grab arm is and with router bits / drills / milling cutters we have an inexpensive 3d subtractive workstation. Put a 90 degree gear on the end and with a spindle in, place a saw blade and you have a grooving station for sheet goods. Put a grinding wheel on the shaft and you have a surface grinder. Wow, a whole workshop in one tool. Can't wait!
Amazing Work!! I will definitely be following your progress & hopefully building one for myself, once the details are released. Thanks for sharing your work. i believe this is the best 6 axis 3D printed robot arm I have seen on UA-cam.
Very exciting stuff! I can't wait to see more. What are you planing to do with the mechanical design and software? A side from releasing it on get hub, which is a very nice thing for you to do. But, do you have an application you are working toward? Welding bot or machine tending?? Best Matt
thank you. I would say the project has a couple goals - primarily just something Ive wanted to do for a while, I work with industrial robot systems for a living - the discounted integrator pricing for most of the smaller robots is $25K up to $100K for larger ones (the price is higher if your the end user). Even the small lab grade servo robots are around $15k which is out of reach for most. Ive always thought it would be cool if there was something affordable that the small business or garage shop could have for small, low complexity machine tending applications. I was hoping to come up with something people could make themselves. This robot is not a finshed - polished product but its a start or at least a feasible concept.... and its a fun project either way. I was hoping to come up with something that would only cost someone a few thousand dollars to make - at this point im at $1080 in materials for the robot in the video. I have a colleague who owns a machine shop and we are working on an aluminum version, hoping to put it to work in his shop doing machine tending. Im hoping we can continue to refine the quality and programming and perhaps at some point have a polished build your own robot package that is useful. we'll see how it goes - right now im swamped at work and trying to find the time to get all the files finished up so I can post it and there are still a few bugs im working on. future steps on this project might be closed loop steppers or servos, moving the path calculations from the PC into the arduino and develop path planning (arcs, lines ect), tool frame kinamatics and a few other offset functions. thanks for the feedback. I'll get it posted as soon as I can find some time away from work.
I agree. You have a wonderful dream to chase. And a noble one. Robots are expensive and very useful if that issue is solved it would change a lot of lives. I will continue to follow your progress and I might extend some of my manufacturing expertise in casting to aid you with your project if you wish. I will be in touch. Best Matt
Figuring out the kinamatics have been the most difficult part for me. When I made the video I had the robot jogging in XYZ and reorienting the wrist ok with a few minor issues but I found later when I had J4 and J6 at certain positions it would make unexpected changes in orientation which is no good. Long story short im still working on figuring out where I screwed up. Id like to have it figured out before I post all the files but the program will always be a work in progress. hopefully something thats always improving and adding functionality. I think making a video on the kinamatics is a good idea - all the information ive gone through so far to get where im at has been difficult to follow given that its always written from the perspective of someone who already understands linear algebra and frame transformations and most of it is geared toward a variety of types of robots and not alot of examples of this configuration. Once I get it finished up I will make a video for the rest of us thats easy to understand. good idea thank you.
That is called a singularity, you cant move lineary with the 4, 5 and 6 axis aligned. You should move with a axis movement instead to avoid that. I work with industrial robots and they have the same problem.
holy shit. your giving all this away? your a good person and embody the spirit of the internet. I'm just nerding out on robotics videos with only a yearning of actually doing it. but thank you.
Approximate cost, at the time he compiled the materials list is 935 USD (plus some screws and nuts). Cheapest printer that would be suitable for this is roughly 500 USD, plus the plastic thread, soldering kit, computer and multimeter.
Awesome Project This by far is the most detailed description of how too, I've ever seen. You Sir! are amazing! Thank you for not only putting this together, but also sharing this with everyone! OUTSTANDING!.. CONGRATS!...
awesome work! I've been playing the software a bit. I've got it to run on a Raspberry Pi and it seems to do just fine. Had to workshop the GUI a bit to get it to play nice, but looks good now and it ticks like a clock! I think an "While...if...break" generator based on Inputs would be an amazing improvement. Can't wait to see the kinematics addition to this! You are the man!
This looks awesome, keep up the good work. Watching this makes me want to build one of my own robot arm. Definitely putting this on my to-do projects list :)
Hi Chris, Thanks for your great videos. Thanks to you I used same stepper motors for my project and they worked just great. (videos of the build on my channel) I keep following your channel; the progress you have made is just amazing !
Great work - I too am thinking about machining a robot arm out of aluminium/aluminum once I've got a couple of other projects out of the way. As a few other commentators said, it will be interesting to see/hear details of your inverse kinematics implementation.
Wow, that is awesome dude. I'm so pleasantly pleased that there are people like you out there. Smart people(s); Gets my faith in humanity back. Nicely done!
This is extremely impressive. I've seen a few of the other openbuilds of 6-axis robots and this one is probably at the top. Really interested in your timeline on this project and ballpark how long it took you? Very well done, and thank you for eventually putting this into the wild.
thank you. I thought id have it posted sooner but had some delays and been busy at work. probably a few more weeks depending on work. ive been at it on this 2nd version for about 6 months.
I'm doing it! The documentation is awesome! I've ordered parts and printed the base and J1 parts, had to split the base! And I'm terribly lazy, wish there had been an aluminum kit for under $3k, but what the heck! Thanks!
Chris, mine is done to the point of J5! J6 is giving me wiring problems, but other than that it's working great! Still waiting on the 3mm rods, tomorrow maybe.
You're doing tinkerers, hobbyists, and students such an amazing service here. We are all INCREDIBLY thankful. Dont forget how incredible this is.
MrGuyCali thank you, I’m happy to help out.
This is top drawer. I admire your mindset especially that you are going totally open source for users. well done.
thank you.
Holy cow you set the bar high!
SUBSCRIBED!!!!!
Chris Annin No thank you! Great work and thanks for sharing!
Yeah, then in a few months you will see them on eBay for at least 3k..free shipping from China.
This is a fully working and well made project, much respect for that, and also for allowing the whole project open source. Sad though that this kindness and generosity will be stolen and sold commercially as someone else's work.
I have nothing against giving this sort of knowledge and work away, some people do. It shows good character and something more people should have.
If I ever decide to use this project then a worthy gift in return would be offered.
This is the best 3d printed 6 axis robot arm I've seen on youtube, mad props. Subbed!
thank you
how long did it take you to design the robot and write software?
I started writing the software probably a year maybe a little longer ago when I did the first robot, it's been a work in progress. this robot took me 3 or 4 months to design picking away at it in the evenings.
Hats down.... incredible! This is simply awesome!
Thank you
I'm only 2 minutes into this video and I gotta stop and tell you how impressed I am by this. Amazing. As an industrial programmer myself, this is awesome. I'm gonna watch the rest now.
Was you classed as a keyworker during the quarantines?
Beautiful work on so many aspects. I was a fan of the old Radio Shack "Armatron" back in the day, your project shows how far we've come. The availability of 3D printing, online learning & collaboration, Arduino, etc is really the beginning of a new era.
Thank you
Absolutely awesome! I've built a couple robot arms in past years, with 3D printers, neither anywhere as good as this one. So I totally appreciate and salute this accomplishment. Hats off to Chris Annin!
Awesome job! Also that is perhaps the best demo on capabilities for a diy job i have seen yet. keep up the great work!!!
thank you.
Wow - this is impressive - I've spent 15 years programming Fanuc Robots and to see what you've built is amazing. You are quite the engineer 👍🏻
Thank you very much
Hi robert i want to learn this thing i use Arduino for simple project but this its loking hard to mee programing by paython with Arduino chipset if there is a Chaîne or vidéos on UA-cam to explain the relation with paython and thanx bro
With all the work put into the arm, the video, the links etc.
How can so many people have disliked this video?
Yea I wonder sometimes... I thought it was kind of a cool project to share. I suppose people run across it who aren't into stuff like this but you would think they would just keep scrolling rather than go to the dark side.... trolls? Nothing better to do? Got me.
This is an excellent project Chris, thanks for the effort, appreciate it.
The video of the new aluminum version is here ua-cam.com/video/AeCLbhPHltw/v-deo.html - You can find all the software, instructions and print files here: github.com/Chris-Annin/AR2
Hello chris. I download the files and i just started to review. IS there any possibility to build it aluminium instead of power abs. What you think about the stepper power is enough?
im working on an aluminum version now. I'll post videos when its up and running.
can you publsih 3d model or 2d drawings for machining the aluminum.
We have the first half of the robot built out of aluminum - there are some minor differneces using aluminum so we are working out the bugs on the part drawings. If it all works and testing goes well I may make an aluminum parts kit available. It will take some time but im working on it.
you are awesome, thanks for posting these!
What an exceptional project. I instantly subscribed! Thankyou for posting this. Now I'm on the edge of my seat waiting for news of any progress! Absolutely a brilliant effort! Well done.
I'm 15 and have been searching for 3D printed arms. This is by far the most precise and low cost quality thing I've seen. thanks! I can't wait for the parts list to come out.
Thank you. i will get it posted - probably 2 -3 more weeks depending how things are going at work.
Chris Annin awesome
Very nice. Can't wait to see the aluminium one!
thank you
Just found myself watching this again for the nth time. Regarding your comments here about moving the kinematic calculation into the arduino, that sounds like quite a hassle. Isn't the arduino just there to relay step/direction info to the motors (and listen to the limit switches of course)? The kinematic calculation strikes me as being perfectly suited to a computer with some proper processing power, and more easily modifiable setup and tweaking and potentially also graphical visualization, especially if you intend to release this for others to use on their own builds.
I believe you are correct on all accounts - I think its current form is the simplest and has a lot of value for others to use and modify which of course was my goal to keep it as simple as possible - also considering this was a learning process for me as well so it started simple and I built it to a point where it is now. There are probably multiple ways to do this but my thinking is that if I wanted to get into complex path interpolation like perfectly straight lines, arcs or other 3d generated paths I would need the arduino to execute a series of positions along the arc or line seamlessly with zero delay between moves - it would be needing to read ahead and be headed to the next point as it finishes the last with no delay. Currently the computer sends serial commands to the arduino and there is a limit as to the string length that can be sent. Im sending one move at a time and there is a delay between serial commands. unless there is a way to establish real time communication between the PC and the arduino you would end up with a choppy line or arc movement. as it is now the PC sends 6 joint positions to the arduino - I think I need to be able to send Cartesian position to the arduino so that it could then do the kinamatics and figure out joint angles and calculate multiple points along the line or arc path from its current position to its destination position so that it could execute many 10's or 100's of positions along that line or arc seamlessly with no delay. Im not certain but I think being able to send the arduino coordinate positions instead of joint angles would open alot of doors for CNC, printing or other types of applications. but as it is now its simple, easy to use and it fulfills its intended purpose of a simple material handling robot that can move from point A to point B - Its also good for education and hobby purposes. I dont think its best suited for material application or CNC applications but maybe thats something I can work on in the next version - perhaps a servo driven version. Let me know what you think or if you have any ideas. Im learning as I go here.....
My main concern was that the robot definition (number and orientation of axes, limb segment lengths etc) would be on the arduino, which would be a nuisance to have to keep flashing a new sketch to set up and tweak. You could perhaps store the definition in EEPROM and update it from the PC instead of re-flashing the sketch every time, but that would have its own complications. Interpolations will produce quite a lot of info to deal with and developing them with the primitive debugger-less feedback from the arduino doesn't sound like fun. I also suspect that the kind of memory needed to store a decent straight line interpolation would be beyond the spec of the arduino - sure you could limit it to whatever movement distance it can actually handle, but this is just another hassle that the PC would not have. Other than that, from an open-sourcing point of view it would be advantageous to break down the calculation stages into more discrete 'modules' that flow from higher to lower levels of control. For example, somebody might like to use their own path interpolation algorithm, which would be a lot easier if there was a clearly defined communication interface for their stage to issue commands to the next lower level (ie. which motors move where). Taking it a step further in the other direction, you might have an even higher-level stage (eg. computer vision to identify parts on a table) that would give commands to the path interpolator. I think the easier each stage can be swapped out or worked on without knowledge of other stages, the more takers you'll have for collaboration.
It sounds like your main concern at this point is the speed of communication between the PC and the arduino? I wasn't suggesting that the PC would issue step pulses directly, just in case you got that impression. The arduino would still be given the desired joint positions and be required to figure out the necessary steps on its own, but it would be given those many 10's or 100's of interpolated positions you mentioned. This I think is an achievable data rate, especially if you make the communication interface a little more efficient. I looked over your sketch and I don't see any obvious reason it would be particularly slow, especially at faster baud rates. But using binary data instead of strings would help to decrease the data volume and time spent parsing strings. To have seamless movement with no delay you'll want to buffer some points on the arduino, which means you'll need to have the arduino acknowledge completed points so that the PC knows when to send more. I guess it would be helpful if acknowledgments like that worked their way back to the other higher level stages too, so that none would get too far ahead of the others, although buffering is less of a problem on the PC side. In any case, I'm pretty sure the PC to arduino connection would be able to send positions faster than the arm can physically carry out the movement. As a rough estimate, a 'packet' with 6 joint positions of 16 bit integers each, plus a few bytes for desired speed, some flags, packet ids, and other housekeeping might come to around 140 bytes. A 115200 baud hardware UART should transfer about 100 such packets per second. So the resolution of the interpolation for that case would be the distance moved per second divided by 100, eg. moving 20cm per second would be done with a resolution of around 2mm.
I'm starting to get together some parts to build a little robot arm myself. I have plenty of programming experience but only just started with steppers and actuation recently when I built a little CNC machine. The inverse kinematic calculation stuff gives me a headache just to look at, so I am thinking to fudge it with a 2D physics library for games (eg. Angry Birds, Hill Climb Racing). It supports joints with limits and would allow setting the position of the two arm ends and simply reading off the angles of the joints. That would handle the main arm joints in their 2D plane, for a typical arm the other degree of freedom is cylindrical rotation which should not be too hard. Since this library is normally used in games with dozens of joints and constraints and typically running at 60 frames per second I have no doubt it would be able to keep up speed-wise. I'm not sure how the accuracy of this method would be though.
oops, just noticed my packet size calculation was using 16 byte integers, not 16 bit, I was thinking that number came out a little too large heheh. So a typical packet (with 32 bit integers this time) would be more like 56 bytes or 250 packets per second, ie. about 1mm resolution at 25cm/s
Fantastic work! Thanks for sharing.
THIS was the reason I purchased a 3D printer. I'm fiddling for small stepper motors and micro servos at the moment. I printer a my arm and I'm just assembling it using an old PC power supply. Thanks for the video and the time it took! Now I'm excited all over again. :)
hi garry i am strugling with couple of parts.....can you help me ??
Amazing work! The dedication to see a project like this from concept to actually making it work is incredible. Not to mention producing a Bill of Materials and an Assembly Manual and sharing all this for free. Not to mention all the skill sets needed, mechanical engineering, electrical engineering, computer programming, CAD modeling, 3D printing, then playing mechanic, electrician, robotics, to assemble the components. I hope you get paid very well for whatever you do for living because not many folks are capable of this. - Thanks for sharing Chris
Thank you very much I appreciate your compliment and I hope this project becomes more and more useful in the future.
Wow, Great job, very impressive!!
Thank you
Oh man! This is awesome! Just came across this. I want to build one👍
Chris, every once in a while someone comes along to give you an ooh-ahh day. Congratulations, you're it for this week! Looking forward to making my own 3 axis bed CNC and cutting a robotic arm to go on the cross slide to replace the single axis up /down cutter head movement. Put a collet chuck where your grab arm is and with router bits / drills / milling cutters we have an inexpensive 3d subtractive workstation. Put a 90 degree gear on the end and with a spindle in, place a saw blade and you have a grooving station for sheet goods. Put a grinding wheel on the shaft and you have a surface grinder. Wow, a whole workshop in one tool. Can't wait!
Amazing Work!! I will definitely be following your progress & hopefully building one for myself, once the details are released. Thanks for sharing your work. i believe this is the best 6 axis 3D printed robot arm I have seen on UA-cam.
thank you. just posted all the files a couple mins ago. link in the description.
Very exciting stuff! I can't wait to see more. What are you planing to do with the mechanical design and software? A side from releasing it on get hub, which is a very nice thing for you to do. But, do you have an application you are working toward? Welding bot or machine tending??
Best Matt
thank you. I would say the project has a couple goals - primarily just something Ive wanted to do for a while, I work with industrial robot systems for a living - the discounted integrator pricing for most of the smaller robots is $25K up to $100K for larger ones (the price is higher if your the end user). Even the small lab grade servo robots are around $15k which is out of reach for most. Ive always thought it would be cool if there was something affordable that the small business or garage shop could have for small, low complexity machine tending applications. I was hoping to come up with something people could make themselves. This robot is not a finshed - polished product but its a start or at least a feasible concept.... and its a fun project either way. I was hoping to come up with something that would only cost someone a few thousand dollars to make - at this point im at $1080 in materials for the robot in the video. I have a colleague who owns a machine shop and we are working on an aluminum version, hoping to put it to work in his shop doing machine tending. Im hoping we can continue to refine the quality and programming and perhaps at some point have a polished build your own robot package that is useful. we'll see how it goes - right now im swamped at work and trying to find the time to get all the files finished up so I can post it and there are still a few bugs im working on. future steps on this project might be closed loop steppers or servos, moving the path calculations from the PC into the arduino and develop path planning (arcs, lines ect), tool frame kinamatics and a few other offset functions. thanks for the feedback. I'll get it posted as soon as I can find some time away from work.
I agree. You have a wonderful dream to chase. And a noble one. Robots are expensive and very useful if that issue is solved it would change a lot of lives. I will continue to follow your progress and I might extend some of my manufacturing expertise in casting to aid you with your project if you wish. I will be in touch.
Best Matt
very cool. Nice work
thank you
Andreas your robot also good
just wow! the amount of work into this is amazing! kudos for the great work!!
Thank you
A lot of work went into this. Your attention to detail shows. VERY Good job! VERY impressive!
Thank you
I love it's industrial sound
TheEnragedGamer the sweet sound of stepper ramping up and down
Very nice! Could you do a video on the kinematics? The joint to cartesian transformations must be hard!
Figuring out the kinamatics have been the most difficult part for me. When I made the video I had the robot jogging in XYZ and reorienting the wrist ok with a few minor issues but I found later when I had J4 and J6 at certain positions it would make unexpected changes in orientation which is no good. Long story short im still working on figuring out where I screwed up. Id like to have it figured out before I post all the files but the program will always be a work in progress. hopefully something thats always improving and adding functionality. I think making a video on the kinamatics is a good idea - all the information ive gone through so far to get where im at has been difficult to follow given that its always written from the perspective of someone who already understands linear algebra and frame transformations and most of it is geared toward a variety of types of robots and not alot of examples of this configuration. Once I get it finished up I will make a video for the rest of us thats easy to understand. good idea thank you.
Wonderful! Good luck with finding the bugs, I'm looking forward to your next videos!
That is called a singularity, you cant move lineary with the 4, 5 and 6 axis aligned. You should move with a axis movement instead to avoid that. I work with industrial robots and they have the same problem.
Just wanted to say congratulations on such a tremendous job! Very exciting work!
thank you
That is a hard work, good documentation and open source. Hats off to you.
Thank you
Thanks for sharing. Always wanted to 3D print an arm, and this might be just the push I needed to get it done! Cheers.
It is possible to obtain the stl parts of the robot, electronics and software.
Yes I will be posting all the files in a couple weeks.
Yea just make some sand molds from the plastic ones and cast some aluminium
Amazing 🤘 I'd attach a small spindle on it and turn it into a Robotic Milling Machine.😉
holy shit. your giving all this away? your a good person and embody the spirit of the internet. I'm just nerding out on robotics videos with only a yearning of actually doing it. but thank you.
It's more fun if it's a group effort, hopefully it's useful or turns into something people can have fun with. Thank you.
Great design, color, very noble from you to share everthing with us, ... awesome ! Big thank you!!!
But the real question is, can it choke the chicken?
Approximate cost, at the time he compiled the materials list is 935 USD (plus some screws and nuts). Cheapest printer that would be suitable for this is roughly 500 USD, plus the plastic thread, soldering kit, computer and multimeter.
Dude, nicely done! This thing is badass.
Awesome Project
This by far is the most detailed description of how too, I've ever seen.
You Sir! are amazing!
Thank you for not only putting this together, but also sharing this with everyone!
OUTSTANDING!..
CONGRATS!...
Seriously WTF! Are you for real!?!?!? Blown away, and truly amazed!
thank you very much
Wow, just checked the assembly manual illustrated with the aluminium version. This is an awesomely professional job! Congrats!
Thank you
This is awesome, I've loved robotic arms ever since I played with the Radio Shack Armatron when I was a kid.
OMG. this is the best 3d printed thing I have ever seen.
Beautiful, well designed & engineered Robot arm! Thankyou Chris!
Glad I can share it. Thanks for the compliment
awesome work! I've been playing the software a bit. I've got it to run on a Raspberry Pi and it seems to do just fine. Had to workshop the GUI a bit to get it to play nice, but looks good now and it ticks like a clock!
I think an "While...if...break" generator based on Inputs would be an amazing improvement.
Can't wait to see the kinematics addition to this! You are the man!
thank you
Amazing to have people like you thank you so much for sharing your knowledge. When I finish my robot I will post a video with all credits to you.
Thank you.
Pretty amazing Chris!
Thanks for sharing,
This looks awesome, keep up the good work. Watching this makes me want to build one of my own robot arm. Definitely putting this on my to-do projects list :)
thank you
Brilliant work!! This is really cool!
Thanks
I've always found robotics interesting. I def would like to build and experiment with something at home. Thanks for your videos.
Hi Chris,
Thanks for your great videos.
Thanks to you I used same stepper motors for my project and they worked just great. (videos of the build on my channel)
I keep following your channel; the progress you have made is just amazing !
thank you
Thank you for sharing all the knowledge, this is amazing!
Wow....outstanding work! Nice job
Thank you
Very impressive. As a coder the control code is a decent project on it's own. With the hardware as well, it's awesome.
Thank you
dude this is amazing. well done
This is a wonderful project, I will do my best to build it next summer!
Awesome job! Great project! Congratulations!
this is beautiful, great work and thanks for sharing it!
thanks.
This is awesome man. Well done.
Thanks for sharing man. Amazing amount of work.
thank you. Im glad you like it.
This is awesome! I was just telling my wife that there had to be a way to make robot arms simple and inexpensive. Good stuff man! 😃
Thank you
Really great work, Bravo , waiting for your next post :)
thank you.
wow. You are amazing Chris.
thank you. I'm glad you like it.
Simply put, Awesome work.
I had a really big smile while watching this. that certainly inspired me to keep working on my own robot xD . KEEP IT UP MAN ;)
Thank you very much. I appreciate it.
amazing job, thanks for sharing all this (again) amazing work
Hi Chris,Thanks for the rapid response. I've now managed to source the higher torque motor.First parts arrived today! Thanks again, Keith
Great work - I too am thinking about machining a robot arm out of aluminium/aluminum once I've got a couple of other projects out of the way. As a few other commentators said, it will be interesting to see/hear details of your inverse kinematics implementation.
thank you. im still working some bugs out - probably take a little while but im stilll working it. i'll post the info and models when I get there.
Incredible build, great job!
thank you
Best 3d printed roboter... It must have taken a lot of work and time... Respect...
Thank you.
That's some fantastic work. Inspiring really. Keep working hard!
Thank you
that looks awesome. thank you for your efforts. love the work.
Thanks
this is beyond 'hobby' level ! great stuff
maui waui thank you
What a superb project, well done. Really interesting.
Thank you
Very good work!!! Congratulations
Thanks
Excellent work and thank you for sharing the files with other users!!
you bet, glad to make it available. thank you.
Congratulation and thank you so much for making it public, it inspires me to do the same!
Wow, that is awesome dude. I'm so pleasantly pleased that there are people like you out there. Smart people(s); Gets my faith in humanity back. Nicely done!
Thank you very much.
I would love to take a vacation and assemble my kit along with you supervising me.
you are a legend! that is amazing work. Thank you for sharing
This is Super Cool! Thank you for sharing every thing :)
This is extremely impressive. I've seen a few of the other openbuilds of 6-axis robots and this one is probably at the top. Really interested in your timeline on this project and ballpark how long it took you? Very well done, and thank you for eventually putting this into the wild.
thank you. I thought id have it posted sooner but had some delays and been busy at work. probably a few more weeks depending on work. ive been at it on this 2nd version for about 6 months.
Very cool, Chris!
Thank you
It looks fantastic!
Imagine the precision of this robot awesome
thank you
Hey John Goodman is a maker!! Top notch work.
Super geniale Idee! Respekt!!! Danke fürs Zeigen.
I'm doing it! The documentation is awesome! I've ordered parts and printed the base and J1 parts, had to split the base! And I'm terribly lazy, wish there had been an aluminum kit for under $3k, but what the heck! Thanks!
Love it!! Wanna start my own one soon. Thanks for sharing!!
This is like the coolest thing i've ever seen on earth!!
Its been fun to make and taken a while, Once I get it walking and talking maybe it could be the coolest ;). thank you for the complement.
No problem :D
Very nice build!
impressive! u did all by yourself... awesome!
thank you
hell yah cant wait to see what you do with this
thanks
Great job Annin, it seems to me that it have taken a lot of effort, money and time. But you have made it
thank you
I'm really impressed. Kudos on giving to the community!,
Thank you
This Man has several brains.
ABSOLUTELY PHENOMENAL BUILD!!!! I love it!
thank you.
Chris, mine is done to the point of J5! J6 is giving me wiring problems, but other than that it's working great! Still waiting on the 3mm rods, tomorrow maybe.
Wow amazing development!
Thank you
Chris, we need to have a beer so I can cry in it, realizing I could never top something this cool!
Thank you
Superb work! Well done!
Thank you
Amazing! Buying the BOM next month!
Awesome job with this. Thanks for reminding me that I should go do something useful with my life :)