Why? If the fixed end is larger it can resist 2x times the input side (within the shaft).Incorrect.
1 lbs at one foot is twice the torque of 1 lbs at 1/2 foot.
Why? If the fixed end is larger it can resist 2x times the input side (within the shaft).Incorrect.
I don't think you understand what torque is.Why? If the fixed end is larger it can resist 2x times the input side (within the shaft).
1 lbs at one foot is twice the torque of 1 lbs at 1/2 foot.
I get it. But differently. It requires more torque to move the larger fastener, requiring a larger driveshaft.I don't think you understand what torque is.
That requires a tool capable of more torque.I get it. But differently. It requires more torque to move the larger fastener, requiring a larger driveshaft.
The smaller fastener is bought home at less torque.
I understand torque. 2 weeks ago I checked my click wrenches in a vice with a weight. They are less accurate than beam wrenches as they wear.
My 1/4 inch torque wrench needs replaced.
That requires a tool capable of more torque.
Any tool is only capable of providing an X amount of torque, and if it's a cordless impact driver, it will not provide any more torque than it's capable of, no matter what it's attached to.
If the adapter is capable of matching or exceeding the torque of the tool applying the torque, and the fastener requires a higher torque, the tool will stall. The tool can not increase it's torque, just because a larger attachment is used with that tool.
No, I do.I don't think you understand what torque is.
See, you do not understand torque.No, I do.
I’m not saying that the torque supplied by the driver to the load is different. I am saying the torque generated within the shaft between the input and load is multiplied by the larger end. Kind of like a sway bar on a car, if you make the ends longer, they will cause more torque across the sway bar.
And for some application's a click is worthless, I never bought a click 1/4 over, the only time I used a 1/4 is when setting the crush on a pinion gear. And the beam fits well with that.I get it. But differently. It requires more torque to move the larger fastener, requiring a larger driveshaft.
The smaller fastener is bought home at less torque.
I understand torque. 2 weeks ago I checked my click wrenches in a vice with a weight. They are less accurate than beam wrenches as they wear.
My 1/4 inch torque wrench needs replaced.
Think long, 3/4" nuts and bolts which have just enough tension that I cannot thread them by hand. Was thinking it would be a great job for my 1/4" impact to feed them on and snug them up before I tighten by hand. Unfortunately, I don't have the needed adapter and figured I'd look for advice on a better brand before buying again.Curious as to why you need to use a 1/2" drive socket to begin with. The tool will not produce enough torque to break a 1/4". or 3/8" socket. If this is a concern, they have a new invention referred to as "impact sockets".
I'm going to replace it with a beam.And for some application's a click is worthless, I never bought a click 1/4 over, the only time I used a 1/4 is when setting the crush on a pinion gear. And the beam fits well with that.
OK, you win the battle of terminology. The amount of torque causes an amount of torsional deflection - tomatoe/tamatoeSee, you do not understand torque.
Simply put...
Torque is the required force to rotate an object about it's axis.
By your logic, top fuel cars would have 24" drive shafts and 12" axles because that would increase the torque of the engine.
Simply incorrect.
Sway bars are torsional deflection, not torque.
So if my chosen point is 1/2" from the center of the shaft, I can expert twice theGive me a lever and a place to stand and I will move the Earth". Just as a linear force is a push or a pull applied to a body, a torque can be thought of as a twist applied to an object with respect to a chosen point.
If you're just running them down, the adapter shouldn't be breaking, but I recommend an impact adapter. They are hardened and heat treated for use for impact tools. Be sure to get one with a radius as opposed to the filet (90degree).Think long, 3/4" nuts and bolts which have just enough tension that I cannot thread them by hand. Was thinking it would be a great job for my 1/4" impact to feed them on and snug them up before I tighten by hand. Unfortunately, I don't have the needed adapter and figured I'd look for advice on a better brand before buying again.
Now you have the two mixed together.OK, you win the battle of terminology. The amount of torque causes an amount of torsional deflection - tomatoe/tamatoe
I'm saying the diameters of the input vs output will cause more or lesstorquetorsional deflection across the shaft.
So if my chosen point is 1/2" from the center of the shaft, I can expert twice theforcetorsional deflection than I can 1/4" from the center with the same amount of force on the end.
3/4 dry threads, 200-450 fts depending on grade.* I suspect it's the sudden stop as the bit reaches it's failure rate. A Dewalt or that cheap Menards bit should keep you out of the failure zone.Think long, 3/4" nuts and bolts which have just enough tension that I cannot thread them by hand. Was thinking it would be a great job for my 1/4" impact to feed them on and snug them up before I tighten by hand. Unfortunately, I don't have the needed adapter and figured I'd look for advice on a better brand before buying again.
Torsional deflection is not torque.
You're all over the place.The amount of torque causes an amount of torsional deflection.
Repeating myself ad nausium without comprehension.
According to my Mechanical PE friend, I am correct.
So if my chosen point is 1/2" from the center of a shaft, I can cause twice the torsional deflection than I can 1/4" from the center with the same amount of force.
A 1 foot long breaker bar can twist an extension twice as far as a 6" breaker bar exerting the same amount of force to the end of it.