Fastening tools with floating magnet sleeves

What is claimed is: 1. A fastener driving tool, comprising: a shaft with a working region disposed at a first end of the shaft and configured to drive a fastener, a shank portion disposed proximate a second end of the shaft and configured to couple the shaft to a power tool, and a reduced diameter torsion zone disposed between the shank portion and the working region, the torsion zone extending from a first shoulder closer to the working region to a second shoulder closer to the shank portion, wherein a length (L) and radius (c) of the torsion zone have been determined based on an equation ϕ = T ⁡ ( 2 ⁢ ⁢ L π · c 4 ) ⁢ 1 G where φ is an angle of twist, T is a torque input, and G is a shear modulus of the shaft, such that the length (L) and the radius (c) of the torsion zone have been optimized so that approximately half of breakages occur in the working region and approximately half of breakages occur in the torsion zone. 2. The fastener driving tool of claim 1 , wherein the working region comprises one of a fastening bit tip and a holder for a fastening bit. 3. The fastener driving tool of claim 1 , wherein the torsion zone comprises a first reduced diameter torsion zone extending from the first shoulder to an intermediate shoulder between the first and second shoulders, and a second reduced diameter torsion zone extending from the intermediate shoulder to the second shoulder, the length (L) extending from the first shoulder to the second shoulder. 4. The fastener driving tool of claim 3 , wherein each of the first and second torsion zones has the radius (c). 5. The fastener driving tool of claim 3 , wherein the first torsion zone has a first length (L 1 ) and the second torsion zone has a second length (L 2 ) that is equal to the first length (L 1 ). 6. The fastener driving tool of claim 5 , further comprising a band around one of the first and second torsion zones. 7. The fastener driving tool of claim 3 , wherein the first torsion zone has a first length (L 1 ) and the second torsion zone has a second length (L 2 ) that is different from the first length (L 1 ). 8. The fastener driving tool of claim 1 , further comprising a floating sleeve having a radially inwardly projecting retention member and a magnet at a front end of the sleeve, the floating sleeve receivable over the shaft with the retention mechanism received in the torsion zone such that the floating sleeve may move axially between a forward position in which the magnet is proximate the working region and able to engage a fastener being driven by the working region and a rearward position in which the retention member abuts the second shoulder. 9. The fastener driving tool of claim 8 , wherein the retention member comprises one of an O-ring, a C-ring, a hog ring, a flexible finger, and a ball received in a window with a spring band biasing the ball radially inward. 10. The fastener driving tool of claim 8 , wherein the retention member comprises one of an O-ring, a C-ring, a hog ring, a flexible finger, and a ball received in a window with a spring band biasing the ball radially inward. 11. The fastener driving tool of claim 1 , wherein the torsion zone comprises a first torsion sub-zone having a length L 1 of approximately 8 mm to approximately 12 mm and a second torsion sub-zone having a length L 2 of approximately 10 mm to approximately 15 mm, and the radius (c) of the first torsion sub-zone and the second torsion sub-zone each are approximately 1.6 mm to approximately 2.0 mm. 12. A fastener driving tool, comprising: a shaft with a first working region disposed at a first end of the shaft and configured to drive a fastener, a second portion disposed proximate a second end of the shaft and configured to couple the shaft to a power tool, and a reduced diameter torsion zone disposed between the second portion and the first working region; and a floating sleeve having a radially inwardly projecting retention member and a magnet at a front end of the sleeve, the floating sleeve receivable over the shaft with the retention mechanism received in the torsion zone such that the floating sleeve may move axially between a forward position in which the magnet is proximate the working region and able to engage a fastener being driven by the working region and a rearward position in which the magnet is retracted from the working region, wherein a length (L) and radius (c) of the torsion zone have been determined based on an equation ϕ = T ⁡ ( 2 ⁢ ⁢ L π · c 4 ) ⁢ 1 G where φ is an angle of twist, T is a torque input, and G is a shear modulus of the shaft such that the length (L) and the radius (c) of the torsion zone have been optimized so that approximately half of breakages occur in the working region and approximately half of breakages occur in the torsion zone. 13. The fastener driving tool of claim 12 , wherein the first working region comprises one of a fastening bit tip and a holder for a fastening bit. 14. The fastener driving tool of claim 12 , wherein the torsion zone comprises a first reduced diameter torsion zone extending from a first shoulder, which is closer to the first end, to an intermediate shoulder, and a second reduced diameter torsion zone extending from the intermediate shoulder to a second shoulder, which is closer to the second end, the length (L) extending from the first shoulder to the second shoulder. 15. The fastener driving tool of claim 14 , wherein each of the first and second torsion zones has the radius (c). 16. The fastener driving tool of claim 14 , wherein the first torsion zone has a first length (L 1 ) and the second torsion zone has a second length (L 2 ) that is equal to the first length (L 1 ). 17. The fastener driving tool of claim 14 , wherein the first torsion zone has a first length (L 1 ) and the second torsion zone has a sec