I'm probably going to open a can of worms here, but with the popularity of using torque wrenches to tighten action screws growing (with good reason, I might add), I'll pass along some food for thought. There have been many tests run over the years (my employer allowed me to fund a small group of them; they aren't cheap) and the end result is that the fastener to fastener preload variation on an adequate sample of fasteners tightened with a torque wrench to the same torque is on the order of 33% on the best day of your life, a situation which our tests verified, though it wasn't our primary goal. On a bad day (inexperienced technician, lack of structured tightening process) that variation can be 100%, that is, the highest preload in the bolt circle will be twice that of the lowest, all with the same applied torque. This is NOT the fault of the torque wrench once the technician learns a structured approach to the tightening process, it is almost totally due to fastener to fastener variations in friction coefficient, the main thrust of our tests. Torque wrenches themselves are in general quite accurate, some of them amazingly so, but the actual end result is thrown into a dither by fastener to fastener friction coefficient variation (and this with all fasteners from the same manufacurers lot
).
So while the use of a torque wrench is an improvement in preload consistency over mechanic's feel (less than you'd think with an experienced technician using the "feel" version of the structured torque wrench process), to improve fastener to fastener preload consistency, we need to eliminate the friction element as much as possible. The torque wrench gives you two important elements - prevention of overtightening, probably the biggest concern with action screws, and a recordable number that you can use for each screw time and again once the optimum number is determined through shooting. The way to eliminate friction if you wish to take preload consistancy to the next level is to use angular turn instead of a specific torque - no involvement of friction coefficient when angular turn is used. The fastener to fastener preload variation with angular is on the order of 15% on an average day.
Torque wrench method:
1.Determine the target torque.
2. Gently snug down fasteners with your weapon of choice to take up slack to initial contact.
3. Tighten the action screws alternately (with only two or three, the pattern isn't complicated, and what order to tighten them in is usually specified in the advice in these forums when it matters) in either three or four equal steps to the final desired value, applying 1/3 (or 1/4, depending on which number of steps you are using) to the first screw, then the second. After a brief pause, go back to #1 and take it to 2/3 of the specified/desired torque, and then do the same to #2, and so on until you reach full target torque. Three steps is good, 4 is better, beyond four doesn't really accomplish much. The brief pauses are to allow for load distribution and some short term preload loss, another contributor to fastener to fastener preload variation. After the final tightening wait at least 2 minutes and do a check pass or two, to finalize preload and check for short term preload loss, another animal that can be bigger than you would think.
To establish angular turn where the angular equivalent for a specific torque isn't available (some computer programs will calculate both)simply tighten a few with a torque wrench, measuring the rotational angle the bolt head is turned to reach final torque and average the results.
Angular turn method:
1. Tighten the fasteners to a repeatable snug - one good working definition of snug is 10% of the final value of the equivalent torque, though with the small size of action screws and the joint designed used, the feel method will work ok in a pinch. Using 10% means your torque wrench is still important.
2. Tighten the fasteners alternately, as in the torque wrench method, using three equal steps of 1/3 of the total angle. Skip the check passes.
For action screws, once you've broken the overtightening habit many of us developed in our younger days, you can skip the whole establishing the angular turn equivalent of a specific torque and just establish snug, apply a known angle, test fire, apply another known angle, and keep on test firing until you find the sweet spot angle just as you do looking for the sweet spot torque.
Again, just some food for thought, but even if you don't want to experiment with angular turn, do get in the habit of using three or four steps and a check pass or two, alternating between each fastener at each step, with your torque wrench. Just that action will help increase precision and eliminate things like prying loads that can mess up the precision what you are trying to accomplish bigtime.
