Edge Precision

What an awesome guy!!

yamahaeleven And a shallow angle spot drill would compliment it well! A 140° spot drill would serve well to locate a 135° split point drill.

Also, I'd suggest pressing in a tooling ball near one of the corners so you could easily and repeatably locate your x-y datums

NYC CNC I learned on mainly Miller and Motoman Robots. However, the basics on every robot are the same... Once you're familiar with one, the next Make, is much easier... It's like spoken languages, they all do the same things, they just do it in different, but similar ways... Setting up a Robot to do a particular welding or plasma cutting job, via a terminal is essentially the same as one does to setup the parameters for a 3D Print... Set the print head temp, the filament speed, hotbed temp, movement seed of each axis... A 6 Axis Robot needs all of the parameters set... But beneath setting of parameters, there is a level of programming that the operator rarely sees... That's the software that translates the G-Code into movement according to the parameters... When setting up a 3D Printer, one starts with the base... The "board" one is going to use... Then they upload the Driver(like) software to the board... This is the software that converts the G-code into movement... Now, if one were to get right into the programming languages... Like writing the Drivers for 3D Printing boards or Robots, that's where it gets tricky... Many companies like Fanuc, Miller, etc. have spent years perfecting that software, but we can get similar software from Rep Rap for each board... and it's all public domain :-) The main difference between 3D Printers and Robots is the setup... Most Robots incorporate a handheld Input device and as an operator walks the robot through it's movements, he sets points where an action is recorded... Starts at the "Home" point and moves to a piece to be welded. Along the way he moves the robot and records points as not to harm the Weld piece or the robot... There are a few parameters to set during this process... but mainly the Path and Travel speed... Once the Robot head has reached the start point of a weld, the welding parameters are set... Voltage, Amperage, Wirefeed speed, weave (If any). All of those parameters are set in a 3D Printer by the software, with little room for adjustments... Unless one knows G-code Programming well enough to make the fine tuned adjustments... However, back to the Robots... Most of them do the same things with minor differences... Some newer machining Robots are capable of taking a Graphic rendering and machining an object via Graphic or 3D Photo and simply running a G-code like software... ABB and KUKA are just two manufacturers among many... Those robots are easily converted from Machining to Welding, Plasma Cutting and other operations... :-) I should mention... Robots have come a long way but still, they are mainly used to duplicate or replicate one specific item, hundreds or thousands of times... 3D Printers are essentially the same idea... When it comes to "One-offs" they are great at taking a 3D graphic and creating a duplicate, but the graphic must be precise... Then 10,000 can be made exactly the same... Prototyping has a lot more to it... I watched part of one of ABB's videos... They were Machining a statue from Marble... Not only did the Graphic have to be precise, but the parameters of the block of marble have to be incorporated... If they wanted to make 2 such statues, either the marble block had to have the exact, same dimensions or they had to input the New dimensions according to the New block... One-offs of that nature are very inefficient... In Robotic Machining the base material must also be exact or "Homing" must occur with every piece and homing may not be enough... Slight variations in Thickness, width, etc. can throw the whole process for a loop... I'm sure you understand... but precision requirements vary, depending on the operation... Welding is very forgiving, but machining is much less... Oh! I should add... ABB and KUKA Robots are just different, not better or worse... I learned on Miller and Motoman, but the same education could have be attained on either ABB or KUKA Robots... Many people, being familiar with one, tend to think that it's the best... Not so... Having no knowledge of Fanuc Robots, I was setting them up within a couple of days... and unless the parameters were all in Chinese or Japanese, I would have no difficulty with any robot... I'll shutup now :-)

Yes that was the viewpoint. The explanation of that further was they felt like it may be too complex for most operators and would generate more problems. A broken tap oft times may scrap a part whereas TM is the better choice.

NYC CNC Yes, arrived on Friday. Ran air to it last week, ran electricity to it today and hopefully next week I'll make the first cut.

NYC CNC No I havent. I don't think the HSMXpress comes with it? I wouldn't think it makes much of a difference other than being more wizard focused over setting the depths/pecking manually.

akromix I also spotted a bit of a goof there on the cleanup of the adaptive clearing on the bottom of the plate. Looks like the lead in and out was a bit much and it left some behind. :)

What I mean is the depth drilled before the partial retract. If that makes sense.

NYC CNC Nope! Just carbide with a diamond point drill (so you don't need to center drill)

NYC CNC www.guhring(dot)com/ProductsServices/Tools/?Type=18 its the bottom series. "732"

I'm assuming it's semi expendable anyway, would be easier to deck off every once in a while

An adaptive path will have a tendency to gouge when you're removing a good amount of material just due to the lack of rigidity in the machine (any machine), so I would highly recommend a floor finish if your dimensions are important. The adaptive path leaves a neat pattern, but you can feel it for sure.

I mean carbide drill of course ;)

NYC CNC That's great to hear, looking forward to a comparison video ;)

NYC CNC Carbide drills are the only way to go unless its an oddball size you don't use much. Presumably you have a few common size drills that get used frequently, generally this stuff is available on eBay cheap if you're willing to wait. Although the smaller ones are not very expensive new anyways, and you don't get much choice as to what brand and series you can get that way. Generally a carbide drill will allow you at least to skip a center drill op. Although getting the chips out is way more important, the carbides will snap easy if chips start loading up. Run a chip breaker peck, or most of the time if you tweak the feeds you can get the chips to break naturally and straight plunge if you get a good tool dialed right in. I'm thinking you're right on the MQL min retract pecking. Personally I wouldn't feel confident walking away from those drilling ops with that coolant. The full retracts here and there are great to get some coolant down into the hole where the cutting edges are. Otherwise the things running near dry, which can be really particular. I would want to dial things up for that deeper drilling. If thats a form tap, personally I would spray WD40 over all the holes before running it with your MQL system. The VAST majority of times I have problems, its coolant related. So getting the coolant right, typically gives me the confidence to walk away from those long ops.

Frank In addition I'd like to add that you should consider to buy carbide drills with a special coat for aluminium, since it seems that you're working quite alot with alu. quote: [Run a chip breaker peck, or most of the time if you tweak the feeds you can get the chips to break naturally and straight plunge if you get a good tool dialed right in.] Running a chip breaker peck will usually damage the carbide drill. Feeds and speeds should be high enough to break the chips without it (given the hole is not too deep).

***** On a VMC if the tool is run at the edge, yeah. I don't think John is going to have the confidence to run that close on his Tormach. I drilled thousands of holes on one carbide drill in a tiny little Taig, ~6D. No problems, didn't break the cheap drill, but it did almost melt the spindle motor. The only way it worked was with a TINY peck, then a retract before the motor stalled. The Taig just didn't have the power to run the drill hard enough to get the chips out properly that deep. Repeatedly smashing the carbide into the aluminum, and retracting when the spindle bogged worked fine. I wouldn't do it in a VMC, but the Tormach appears to be closer to a Taig than a VMC.

A screw machine drill would help because they are made with shorter flute lengths which makes them a bit more sturdy. Just make sure to get one with the TiN coating.

NYC CNC use it! it rocks..

Oh yeah! Learn Hole Wizard and you won't look back!

Hole wizard is the bees knees!

Phil B Not quite the same in HSM. Frankly the easiest way to do it IMO would have been to set up a SW Coordinate System as reference geometry wherever he wanted it and go from there. In Fusion I tend to default to stock all the time.

No way, unless you have a ton of time and endmills to destroy.

NYC CNC also, why don't you clamp onto your machinetable? as i see, there are many threaded and reamed (?) holes? too deep or weared out?

NYC CNC SolidWorks. I've never used HSMWorks, but I imagine that Sloidworkd would just pass the hole data right over. In any case you can keep holes separate and make the entire hole pattern right in sketch.

John Carlton Damn dyslexic fingers. I meant Solidworks of course.

Oh, ok. I thought maybe there was an issue with it and HSMWorks. Just now starting to play around with HSMWorks Express. So much easier than MasterCAM X2.

NYC CNC Nice! I might have to give one a try... As I have a little less HP in mine ~1.13.. it seems to have a lot better finish

HunterNugent because having a even pattern it easier to work with. you could do it that way but your holes won't be true to each other

***** In CAD you created a 3D model of your workpiece, which you then send over to you CAM programm. You use you 3D model then to create the toolpathes. There are probably programms which can do that automatically, though I believe those are quite expensive.

***** Thanks I will track down the name of the software but it is used through Aduino as the driver.

NYC CNC Always awesome videos. Thanks. Where do you get your aluminum from?

NYC CNC Yes the one that peck retracts and then peck some more .

Im in Finland. Hope we cross our paths one day

Or even better, why are you watching this video when you know better?

RoboCNC Frees- & Graveerwerk Even if you only have a drill stand you should be able to buy a tapping head to use on the spindle. Have a look at this Tapmatic self reversing one on ebay www.ebay.co.uk/itm/like/321759912984?limghlpsr=true&hlpv=2&ops=true&viphx=1&hlpht=true&lpid=108&chn=ps&device=c&rlsatarget=&adtype=pla&crdt=0&ff3=1&ff11=ICEP3.0.0-L&ff12=67&ff13=80&ff14=108

Thanks for the advise wordreet ! Ans indeed I have been looking at these several times... A project like this would indeed be a good excuse to invest in something like that.. I do have a CNC mill, but no spindle control, so I could pauze at each hole and tap with the tapmatic using the quill...

Yup. I believe the Tapmatic has some sort of friction drive inside, but it also has a neutral point where there is no drive at all, so it stops if you ease off the downwards pressure. Then if you move the drill arm upwards, Tapmatic will spin backwards and out of the thread you just created. 10 mins of practice and you'll know how easy it is to work with.