I would love to get the action makers response to some of the large torque numbers suggested.
Ern
They won't suggest torque that high as I'm sure they want to avoid their phones blowing up with people asking to return/exchange their damaged or marred up actions and barrels after trying to get things that tight with the incorrect tooling for the job, lol
Just some quick math here since I have a few free minutes and I'm bored...
Typical barrel material is 416 stainless, so assume fully annealed condition for the lowest possible yield strength, that's 40ksi.
Let's go with 1.0625" diameter tenon threads.
Target 75% of the 40ksi yield strength for the tensile load on the threaded joint so you're still safely in the zone of good preload but only elastically deforming the threads and not yielding the material, that works out to 26600lbs desired tensile load with a 1.0625" fastener/tenon diameter.
Using a K factor of 0.12 for lubricated fine pitch threads, 1.0625 major diameter, and a target tensile load of 75% of the 40ksi yield strength with a 1.0625 diameter fastener for a desired 26600lb of preload, plug it into T = KDF and that is suggesting a 275 ft/lb torque to achieve 75% of 40ksi yield strength of annealed 416 stainless with 1-1/16" diameter lubricated fine threads.
The math doesn't care what the use case is for the threads, it only cares about the desired preload and material, frictional, and dimensional properties of the threaded joint. (Keep in mind the specific use case may allow a lower amount of preload, or require a higher amount of preload... that's a different subject.)
Again, 100-150 ft-lb is rather low in regards to torque for threads the size of a typical barrel tenon even assuming a fully annealed 416 stainless barrel with threads slathered in anti-seize. At 100-150 ft/lbs things are still well under the yield strength of annealed 416 stainless and you not going to hurt the action or barrel going that tight, and if anything, it might not be enough preload in the joint for maximum cold bore / zero stability in all use conditions.
As far as what is appropriate torque as far as what you consider to be "tight enough" for repeatable accuracy and what your workholding and fixturing is capable of handling without slipping/gouging/marring/breaking anything, that's up to you. I shoot for 125 ft-lb on my own stuff as much tighter than that the barrels can be a pain in the ass to pop free after being installed for a while; I'd rather not mar up the external surfaces or twist or damage the action/raceways/lugs with an internal action wrench. 125 ft-lb is what I consider the "reasonable" number for my tooling and fixturing, but if I had tooling that would handle 200-300 ft-lb without any worries about marring or damaging the action or barrel that's the range I would be more satisfied using based on the thread diameter and material properties involved.
Better yet would be to use the lowest torque that the data says is needed to minimize or eliminate cold bore POI deviation and POI deviation after a significant impact event on the barrel, but I do not have adequate test data to make that determination.
Disclaimer: I did the above calcs quickly on my phone and may have messed up, so keep that in mind, lol. However, for a rough sanity check of my math, looking up suggested torque charts for an M27 fine thread bolt (M27 = 1.063", so very close to my example) in grade 4.6 (4.6 = 400 MPA tensile strength, 0.6 * 400 = 240 MPA yield strength, and 240 MPA = 34.8ksi yield strength, so weaker but somewhat close to the 40ksi of annealed 416 stainless I used) shows a suggested lubricated torque value of 360 Nm / 250 ft-lbs on several bolt manufacturers data charts.
go closer to 800 I'll be happier,)
