Yeah the last bit is by angle, but I was watching the beam indicator too. The ones that did not yield did not allow the angle turn... they were really stubborn and I didn't want to totally reef on em.
Going over 100lbs on a 12MM head is not abnormal.IMO, watching the torque is a waste of time, the bolts don't work that way,
Quote from: 745 turbogreasel on December 05, 2012, 03:12:34 amGoing over 100lbs on a 12MM head is not abnormal. When I started with VW diesels, it seems I really had to reef on em, so i did a few with the clicker, and some were in the upper hundredandteens.IMO, watching the torque is a waste of time, the bolts don't work that way, They are designed for an angle torque application , because doing it the old way wasn't good/consistent enough. Therefor watching the beam wrench does not deliver useful information. Please explain.
Going over 100lbs on a 12MM head is not abnormal. When I started with VW diesels, it seems I really had to reef on em, so i did a few with the clicker, and some were in the upper hundredandteens.IMO, watching the torque is a waste of time, the bolts don't work that way, They are designed for an angle torque application , because doing it the old way wasn't good/consistent enough. Therefor watching the beam wrench does not deliver useful information.
Quote from: TylerDurden on December 05, 2012, 04:23:13 amQuote from: 745 turbogreasel on December 05, 2012, 03:12:34 amGoing over 100lbs on a 12MM head is not abnormal. When I started with VW diesels, it seems I really had to reef on em, so i did a few with the clicker, and some were in the upper hundredandteens.IMO, watching the torque is a waste of time, the bolts don't work that way, They are designed for an angle torque application , because doing it the old way wasn't good/consistent enough. Therefor watching the beam wrench does not deliver useful information. Please explain.That answer your question?
The torque applied to a fastener is absorbed in three main areas. First, there is underhead friction, which may absorb 50 percent or more of the total torque. Thread friction absorbs as much as 40 percent of the applied torque. The final 10 percent of the applied torque develops the clamping force that holds the components together. Thus an increase in either friction component of 5% can reduce tension by half.*****When torque-only control is used as the method for tightening a fastener, there is absolutely no way to be 100 percent certain that the desired tension will be created. Using installation torque alone to control the process always introduces an element of “statistical gambling” into the assembly process. Installation torque measurements that are not backed up with simultaneous angle-of-turn measurements cannot be totally relied upon to insure that proper fastener installation has been accomplished.For bolted joints where safety and reliable performance are dependent upon proper initial tension, both torque and angle-of-turn must be monitored and controlled during the tightening process. As each fastener is installed, the torque-angle tightening signature of the bolted joint should be compared to established assembly process limits to insure that the specified assembly preload has been achieved.The fundamental tightening procedure for Torque-Angle-Tension Control is simply defined as follows.1. Torque is applied until a specified “threshold” level is attained.2. An additional angle-of-turn is applied to finish the installation.*****The most general model of the fastener tightening process has four distinct zones as illustrated in Figure 19.Zone 1 is the rundown or prevailing torque zone that occurs before the fastener or nut contacts the bearing surface. Prevailing torque due to thread locking features such as nylon inserts or deformed threads will show up in the rundown zone. Frictional drag on the shank or threads due to misalignment of parts, chips or foreign material in the threads as well as unintended interference due to out of tolerance threads are additional causes of prevailing torque in the rundown zone.Zone 2, is the alignment or snugging zone, wherein the fastener and joint mating surfaces are drawn into alignment, or a stable, clamped condition. The nonlinear alignment zone is a complex function of the process of drawing together the mating parts, and bending of the fastener as a result of non-parallelism of the bearing surface to the fastener underhead surface. In addition to the macro effects related to alignment of parts, there are micro effects within the alignment zone. The micro effects include contact stress-induced deformations of plating and coatings as well as local surface roughness and thread deformations.Zone 3, is the elastic clamping zone, wherein the slope of the torque-angle signature curve is constant. The elastic clamping zone torque-angle slope is a very important characteristic of each bolted joint. This slope can be projected backward to locate the elastic origin. Angle-of-turn from the elastic origin is multiplied by the angle-tension coefficient to calculate the tension that has been created by the tightening process.Zone 4, as shown in Figure 19, is the post-yield zone, which begins with an inflection point at the end of the elastic clamping range. Yielding can occur in the bolt or in the joint assembly, as a result of underhead embedment or as thread strip in the bolt or mating threads. The yield point can be used to establish or verify the tension-angle coefficient for the torque-angle-tension tightening process.*****For this process to work reliably, it is necessary that the threshold torque level for starting angle counting be set at a level which is above the alignment zone of the tightening process.
