Making a PRECISION Machinist Jack || INHERITANCE MACHINING

1.06M views4215 WordsCopy TextShare
Inheritance Machining
Welcome back to the manual machine shop! In this video I’ll be prototyping a machinist jack with a f...
Video Transcript:
rigidity it's the name of the game in Machining setups a lot of different tools can help make sure your part doesn't deflect under load and one of the most common supports is a machinist Jack now machinist Jacks come in all shapes and sizes but their Precision usually leaves a lot to be desired they are typically simple quick designs intended to just get the job done and while there's nothing wrong with that even in the slightest I seem to be fundamentally incapable of making either simple or quick projects in this case I'm looking to make a
more precise and easier to use alternative to the traditional designs so that's exactly what I'm going to make a better machinist Jack [Music] [Music] before I get started I need to give credit where credit is due the initial concept of this design comes from Mr art McKay of Washington state what started as a discussion in the comment section soon evolved into a lengthy back and forth over email as we bounce ideas around it's a pretty clever but still fairly simple concept that should solve a lot of the problems with typical machinist jacks and if I
remember correctly he's not yet attempted this design himself so thank you art let's see if I can do it justice now these problems with traditional machinist Jacks what are they well the biggest one is that typical Jam that designs like this have a tendency to lift out a position as the nut is tightened which can be a real pain when you're trying to support material accurately secondly there always seems to be a compromise on the thread pitch selected fine threads are good for precision but take an eternity to adjust into position and coarse threads are
good for Speed but not as precise but Arts idea combines The Best of Both Worlds a couple other wishlist items for this build are one they must be short enough to match my vice height since this is probably the most common use for these jacks and two they need to be mountable with the Mills t-slot Hardware with a set of requirements and a few basic measurements in hand it's time to start Machining ha just kidding you didn't think I would just jump right into making chips did you there's way too much going on here for
me to just be winging it I'll spare you the part where I erratically sketched out different geometries while I roughed out the dimensions and bring you along for the final design the Jack will be a three-piece mechanism and I'll start with the top piece which I'll call the Anvil the Anvil is what engages with whatever material the jack is supporting and will have just a simple round face I'll add knurling to this bit to make it adjustable by hand but I'm also going to add a couple wrench Flats just so I can make adjustments that
way if I need to the shaft is threaded and while a half inch 20 fine thread would work here I'm taking it to the next level and making this a half 40 thread this will allow for the super fine adjustments I'm looking for in this build the next piece of the Jack mechanism is what I'm calling the sleeve the top end of the sleeve will have a knurled knob and there's a matching half or defined thread to the Anvil shaft on the inside the outside is also threaded but at a much coarser pitch actually I'm
going to use the courses pitch available on my Lei the four threads per inch the only issue with this is that the thread height is just too deep for this part so to get around this I'm going to cut what's called a multi-start thread meaning there will be multiple sets of threads running parallel to one another around the outside this in effect lets me maintain the four TPI pitch while having a much lower profile howl machine though should also be pretty interesting so I'm looking forward to giving that a try now if you thought this
part couldn't get any cooler let me tell you we're just getting to the good stuff the top end of the sleeve with the knurled grip will actually form an integrated locking collar this is one of the core design elements that comes from art and should have a couple huge advantages number one the tooling required to make the adjustments is minimal just an allen wrench and two when the locking collar is tightened in theory the Anvil height should stay exactly the same without lifting as would happen with a jam nut design making it far easier for
setting precise Heights the final piece of the puzzle is the base this will have a combination of knurled grip sections on the top and bottom as well as a set of wrench Flats in the middle in case they are needed the unique locking collar design is used once again on the top side where the sleeve will be inserted and most of the length of the internal bore will get a matching multi-start thread to the sleeve OD the last bit will be a half 13 threaded hole in the bottom making it compatible with my Mills t-slot
Hardware and then that's it that's the whole design and I think it's actually going to work I'll finish dropping all the dimensions on here and we can get to making of course like most projects order of operations is going to be critical here so I'll start with the part I have the least control over but also the most risk of screwing up the sleeve also I'll be making these parts from some A2 tool steel slugs that were donated to the channel by another very generous viewer gnarling is somewhat of a black art so anytime I
have a part that includes this I always try to knock this out first just in case it doesn't go as planned I'll face the end of the stock then turn down the OD to my starting diameter after ensuring the knurling tool is going to produce the pattern I'm after I'll proceed across the rest of the area until I have a nice grippy knurl the challenging part will be to get the rest of the knurled parts to match but I'll cross that bridge when I get to it thank you next I'll turn down the end section
that will make up the external threads and also clear our little starting spot near the knob for the thread cutting tool now you might recall from before that these threads will be multi-start threads and there are a couple ways to do this if I were cutting double or quadruple start threads there are some specific scenarios where I can make clever use of the threading dial but I won't be getting into that since I'm Making triple start threads to achieve this I have to set the compound rest to exactly zero degrees this in effect gives me
an additional z-axis which I can then use to set the thread lead or rather the distance between the three separate pitches the only downside of this is that I'll have to feed the thread cutter in straight rather than at 60 degrees which is my preferred method and it usually results in a better finish but we'll see how it goes I'll also point out that I'm cutting these threads in Reverse with an inverted thread cutting tool which will greatly reduce my risk of crashing into the part I'll set the lead on the compound to zero coat
the part in some layout fluid and take the first scratch pass and here you can see just how coarse of a pitch this really is I'll adjust the lead to one third of the pitch so .0833 inches intake the second pass and finally adjust the lead one last time to 0.1667 and take the final scratch pass I'd say that looks about right so I'm going to go ahead and start making the real cuts I know roughly how deep I need to go but rather than just adjust the lead between each pass I'll do this one
thread course at a time and only adjust the lead between the courses of all the things that have to go exactly right the adjustment of the lead is the one I have the least Precision over since there's no Dro on this axis I'm limited to the accuracy of the hand wheel which only shows increments down to the thousandth but I'm still trying my best to aim in the neighborhood of a couple ten thousands by splitting the increments it might be wishful thinking but I at least have to try since I don't have a matching female
threaded piece to check the fit on I'll have to resort to using thread wires placing two on the threads on one side and one on the opposite side I can get a reading with a micrometer then compare this with the results of an online threadwire calculator taking into account the wire diameter and the thread spec this is technically a 7 8 by 4 thread but since this is a triple start I'll use the values for a 7 8 12 instead and find that I still have a fair amount to go it wasn't until these deeper
passes that I started getting some rather crunchy sounding cuts [Music] this is likely due to feeding the cutter straight in and also running a bit slower for the diameter both of which I'm limited on the one thing I definitely had control over however was just how far out the cutting tool was sticking from the tool holder why on Earth I didn't reel that in a bit before getting started is beyond me so to try and smooth out the final finish I'll take three to four spring passes on each of the thread courses and also use
a triangular file to remove any errant Burrs before measuring that looks pretty good once at the correct thread Dimension I can move on to the bore I'll pilot drill for a half 40 tap and also use the boring bar to cut the bottom clearance hole for the teslot hardware that will protrude into this area it wasn't until I had this half 40 tap in hand that I realized just how fine thread this actually is here's a common half 13 for reference bananas I'll get this set up with a guided t-handle tap wrench then start the
many many revolutions to get it all the way to the bottom of the bore turning both the inside and outside threads in the same setup like this ensures that all the adjustment axes remain parallel which will be key for getting the Precision I'm hoping for from this Jack with the fine threads tap the last feature I can take care of from this side is the bottom chamfer of the knob then I can part this off nice catch in addition to cleaning up the opposite face I still need to add the features that will turn this
knurled knob into a locking collar but I have a little trick up my sleeve for these that I'm not quite ready to reveal so in the meantime I'll get started on the Anvil again I'll start the same way as before by facing and turning down the diameter in preparation for the knurling and then cross my fingers that the pattern comes out the same as the sleeve two out of three this must be my lucky day with the tricky part sorted I Can Begin turning down the rest of the shaft in preparation for the 40 TPI
threads to match the bore of the sleeve but not without a little side project first while most of this lays thread fees can be achieved with correct lever selection a 40 TPI thread is not one of them so I'm going to have to make a change to the change gears that is I currently have the a set of Gears installed but I need to swap to the B set of gears which are conveniently located at the bottom of this awkward and nearly falling apart crate on the lowest shelf on the back of my workbench I
think I should at least get a point for keeping all the lathe miscellanea in one spot I'll get these cleaned up real quick then loosen the change gear mechanisms behind the cover to make the Swap this change requires three out of the four gears be replaced and because the different gear sets have different diameters there's built-in flexibility to allow for the gears to properly mesh in each configuration with everything tightened down on the correct selections made on the front of the lathe I can take my first scratch pass to ensure I got everything installed correctly
looks like I did so it's time for the real thing since this is such a fine pitch thread I won't be cutting very deep but I am keeping the passes to a couple thou at a time just to reduce the deflection of this three to one stick out ratio once I start to get close I can use the internal thread from the sleeve as a gauge until the threads just barely fit keeping the play between the threads as low as possible will be another factor in making this Jack super precise then that's it from this
end like the sleeve I still have some work to do on the opposite end but again I'm going to put that on hold I know I know two unfinished Parts but bear with me because it's going to be awesome I'll swap the change gears back to the original set and then get started on the final part of this Trio the base again I'll face and turn this in preparation for knurling but this time I'm also bringing in some tail stock support since I need to narrow all the way out on the end I somehow missed
filming this but my first test of the knurling tool was producing the wrong pattern so I ended up turning another five thou off the diameter which helped in getting the knurling to match the other two parts to cut the narrow Center section I'll zero neutral angle cutter on the end of the stock with the old dichrometer and then hog the material away in the middle I'll also drop a chamfer on this end as well then change ears again and work on the bore well not the change gears you know what I mean the threads at
the back of this hole will be a half 13 so I'll first pilot drill deep enough to clear what would be the bottom of the jack then switch to a much larger diameter drill to start the shorter pilot hole for the internal multi-start threads I ended up using another online tab calculator to determine the ideal pilot hole diameter for this custom thread so to take it the rest of the way I'll use the boring par and then switch to the threading bar to clear the thread starting area at the bottom of this hole not the
preferred tool for this but it gets the job done while I've taken up the practice of threading in Reverse for external threads I haven't been properly equipped to do this for internal threads that is until now knowing I would be taking a ton of passes inside a blind bore I decided to treat myself and bought a left-handed threading insert bar while simply flipping a right-handed threading bar works for cutting external threads in reverse the only way to do this for internal threads is with a left-handed tool like this I'll get the thread feed and compound
dial set up just like I did before on the external multi-start threads then begin taking passes on each of the thread courses in sequence this time using the external threads of the sleeve I made as my gauge on how far I need to go like before as it starts to feel like it's going to go or reduce my passes to a couple thousands at a time and also take many spring passes until all of a sudden the sleeve fits this is a great sign considering all the things that could have gone wrong with aligning the
multiple pitches but I'm not super happy with the fit of the threads sure they're smooth but they're also way looser than I was hoping for I'm a little uneasy that this might affect my Precision in the end but I think I'll keep trucking Along on this one work out any bugs that might crop up and remake this part later on the next set of operations on the base require some Milling but rather than de-chucking the part I'm going to de-chuck the lathe entirely I'll Mount this whole thing on the rotary table with the Chuck adapter
I made a while back which already happens to be trammed to the mill for my last project so the only indicating needed is to zero the dro on the part how convenient now I can begin cutting the features for the integrated locking collar I'll start by Milling the tangential counter bore for the Locking screw then switch to the drill chuck and drill the through pilot hole for the 1032 tap and also the screw clearance hole in what will be the top half of the collar after tapping the hole and giving a test fit with a
screw I can swap to the slitting saw and cut the slit that makes this locking collar actually lockable note the direction that I'm cutting into the threads this prevents Burrs from forming on the inside of the thread which would be a real joy to remove alright with the slot cut we can actually see if this is all going to work while it does take a fair amount of gronking on the Locking screw it does eventually tighten down on the sleeve just like I hoped I imagine this will be even better with a closer thread fit
at this point you might have picked up on my clever plan to finish the final two parts one of the biggest advantages of this rotary Chuck adapter is that I can switch back and forth between the mill and the lathe without removing the parts from the Chuck and thus losing my reference axis pretty neat right with the Chuck mounted back on the lathe and the sleeve clamp tightly in the base I can put the final touches on the unfinished end of the sleeve it was at this point I noticed there's a quite concerning wobble in
the setup the exact opposite of the intent of this approach I narrowed down the wobble to the deflection of the locking collar due to the oversized internal threads I should probably hold off on Machining the rest of these parts until I can remake this base but I'm going to go ahead and proceed with the rest anyway I'm a little impatient to see the whole Jack assembled and I can always refinish the end slightly out of spec later I'll pop this whole setup back over on the rotary table drill and tap the lock and collar screw
hole in the sleeve and again cut the slit with the slitting saw this time around testing with the Anvil inserted it takes significantly less torque on the screw to lock the Anvil in place no surprise as this thread has a much closer fit however it reaffirms the importance of fixing the fit on the multi-start threads of the base but again I'll keep going with this still mounted in the middle I'll go ahead and cut the wrench Flats on the Anvil as well as the Flats on the base then I can throw this back on the
lathe one last time where I can put the final touches on the Anvil face barring the slight wobble I had from before I think the advantage of never breaking down the base setup from the Chuck is pretty awesome at all points through the Machining I'm able to maintain concentricity through each of the parts and then the assembly as a whole that is until I part the base off for good this leaves one last face to clean up with no obvious way to grab it and ensure that the bottom will be square to the Jack's Center
axis but after some head scratching I think I've got something that'll work first I'll lightly grip this by the knurling just enough to tap the base for the half 13 T slot Hardware then I can actually thread one of the studs in the base like so grip that in the Chuck of the lathe and tighten the face against the Chuck Jaws this should guarantee that the base is machine parallel to the opposite face which we already know is square to the center axis then I can face The end square into length and add the last
and final features which are of course the chamfers and that's one Jack complete while this would certainly function just fine as a basic machinist Jack it's still lacking the Precision I came here for in the first place so now that I have all my setups figured out I can remake the base one final time well that didn't work I overshot the threads again I cut them a full 10 000 smaller than the first time but this feels just as Loose as before while I was cutting though I think I observed the problem with the cutter
height set exactly on Center Line the forces are pushing the bar down and causing the threads to cut a little bit deeper than I intend this may be a long shot but I'm going to try again but with the cutter height set about 20 thou above Center Line and that's more like it it's right at the verge of being too snug to turn freely which is exactly where I want this to be perfect I'll do the final touches on the mill then it's back to the lathe to reface the sleeve and Anvil to bring them
Square to the base after finishing the opposite side that's one Precision Jack complete and man does it looks slick the true test of precision however is still to be revealed I'll get this anchored to one of the Mills t-slots then bring over the surface gauge with a 10 000 indicator the triple start 4 TPI thread on the sleeve eats up the bulk of the distance then switching to the Fine thread of the Anvil and the resolution is phenomenal I can easily set this within a ten thousandth of an inch and then when I lock the
collar absolutely no movement off of its setting this is amazing I'm so pleased with how this turned out wait dude what did you do you were done well long story short I was attempting to correct some slight squareness problems I was seeing the head of the Anvil was reading about three thou variation across the surface which I knew I could fix with the surface grinder I ground the base successfully but then when I was going to set up the Anvil in place the silliest thing happened my brain confused my left hand from my right and
more catastrophically my right hand from my left driving the grinding wheel down into my machinist Jack way too hard which instantly sent my glorious Jack flying off the chuck taking a not so small piece of the grinding wheel with it and also leaving some other Carnage in its wake so now we're here with an awesome but battered machinist Jack I've run out of time to remake the whole anvil so to at least make this functional again I'll turn a steep taper on the face to clear the damage and also reduce the contact area to a
small narrow spot in the center not ideal but it will tide me over until I can make this Jack's counterpart and remake the Anvil correctly other than that little hiccup at the end I think this project has had a very successful outcome I got to try out some of my shop made tools as well as a few techniques which is always fun but more importantly I was able to prove out a Brand New Concept for a machinist Jack thanks to Art and his great idea and I might even venture to say this could be a
real game changer as always thanks for watching and see you next time [Music] [Music]
Related Videos
Making the KING of All Knurling Tools (Part 1) || INHERITANCE MACHINING
22:11
Making the KING of All Knurling Tools (Par...
Inheritance Machining
873,425 views
Making a Machinist Hammer (but TINY) || INHERITANCE MACHINING
15:16
Making a Machinist Hammer (but TINY) || IN...
Inheritance Machining
668,435 views
How to Drill Holes in Metal: Master the Drill Press
13:59
How to Drill Holes in Metal: Master the Dr...
TimWelds
118,712 views
Making a UNIVERSAL Tap Follower || INHERITANCE MACHINING
20:04
Making a UNIVERSAL Tap Follower || INHERIT...
Inheritance Machining
490,126 views
Customer GOES OFF on Me, Drives to My Shop to Confront Me
14:23
Customer GOES OFF on Me, Drives to My Shop...
TITANS of CNC MACHINING
1,454,449 views
Making a MASSIVE Fly Cutter || INHERITANCE MACHINING
24:14
Making a MASSIVE Fly Cutter || INHERITANCE...
Inheritance Machining
915,485 views
Let's Build a Rotary Table Fixture Plate!
28:08
Let's Build a Rotary Table Fixture Plate!
Blondihacks
78,489 views
Why Railroads Don't Need Expansion Joints
15:53
Why Railroads Don't Need Expansion Joints
Practical Engineering
3,453,178 views
Many Moving Magnets Melting Metal
20:21
Many Moving Magnets Melting Metal
Cody'sLab
2,926,617 views
Let's Make Machinist Jacks
25:11
Let's Make Machinist Jacks
Blondihacks
192,922 views
Live Free or DIE HOLDER
29:19
Live Free or DIE HOLDER
Inheritance Machining
1,271,479 views
Making a BOLT ACTION Pen || INHERITANCE MACHINING
17:58
Making a BOLT ACTION Pen || INHERITANCE MA...
Inheritance Machining
3,014,114 views
Making a VERSATILE Mini Pallet || INHERITANCE MACHINING
23:45
Making a VERSATILE Mini Pallet || INHERITA...
Inheritance Machining
783,115 views
Making a Better Machinist's Screw Jack
26:07
Making a Better Machinist's Screw Jack
Hersch_Tool
22,353 views
‘Bizarre performance’: Douglas Murray analyses Biden’s DNC address
16:46
‘Bizarre performance’: Douglas Murray anal...
Sky News Australia
510,886 views
I need a PRECISION straight-edge, so I made three
12:29
I need a PRECISION straight-edge, so I mad...
Not An Engineer
926,267 views
I made a bolt with MAZE threads - Don't strip these threads! - Can you solve the puzzle?
12:29
I made a bolt with MAZE threads - Don't st...
Robinson Foundry
3,501,198 views
$4000 Block of Wood
21:15
$4000 Block of Wood
Blacktail Studio
14,021,783 views
Making Spindles for a RACE CAR! || INHERITANCE MACHINING
22:00
Making Spindles for a RACE CAR! || INHERIT...
Inheritance Machining
465,275 views
How these impossibly thin cuts are made
9:37
How these impossibly thin cuts are made
Steve Mould
11,474,312 views
Copyright © 2024. Made with ♥ in London by YTScribe.com