Overload inhibiting torque meter

What is claimed is: 1. A torque meter apparatus, comprising: a rotating member having a first end and a second end; an indicating member overlying and spaced radially outward from the rotating member, a first end of the indicating member fixedly attached to and rotating with the first end of the rotating member, and a second end of the indicating member overlapping and rotating independently of the second end of the rotating member; a first set of protrusions fixedly attached to the second end of the indicating member, a second set of protrusions coupled to the second end of the rotating member and interlaced with the first set of protrusions, wherein the first set and second set of protrusions are configured to be used for measuring a torque load on the rotating member, the first set and second set of protrusions not in contact with each other when the rotating member is not operating under torque; and a sensor positioned adjacent the second end of the indicating member, the sensor configured to measure a gap between the first set of protrusions and the second set of protrusions; wherein the second set of protrusions are configured to engage the first set of protrusions when a torque load less than a yield torque is applied to the rotating member, and wherein the indicating member is configured to support at least a portion of the torque load after the first set and second set of protrusions are engaged. 2. The torque meter of claim 1 , wherein the rotating member is a drive shaft and the indicating member is a witness tube. 3. The torque meter of claim 1 , wherein the first set of protrusions and the second set of protrusions are configured to engage at a root portion. 4. The torque meter of claim 3 , wherein the first set of protrusions and the second set of protrusions comprise an upper portion and the root portion, and wherein a gap remains between the upper portions of adjacent protrusions when the root portions of the adjacent protrusions engage. 5. The torque meter of claim 3 , wherein the root portions of the first set of protrusions and the second set of protrusions are configured to support forces that are greater than those generated when the yield torque is applied to the rotating member. 6. A torque meter, comprising: a drive shaft having a first end coupled to a power source and a second coupled to a load; a witness tube overlying and spaced radially outward from the drive shaft, a first end of the witness tube fixedly attached to and rotating with the load end of the drive shaft, and a second end of the witness tube overlapping and rotating independently of the power source end of the drive shaft; and a sensor positioned adjacent to the first set and second set of teeth, the sensor configured to measure gaps between the first set of teeth and the second set of teeth; wherein the witness tube has a first set of teeth spaced around the second end and the drive shaft has a second set of teeth interspaced between and apart from the first set of teeth when the drive shaft is not operating under torque, the first set of teeth and the second set of teeth configured to be used for measuring a torque load on the drive shaft; and wherein the second set of teeth are configured to engage the first set of teeth when a torque load less than a yield torque is applied to the drive shaft, and wherein the witness tube is configured to support at least a portion of the torque load after the first set and second set of teeth are engaged. 7. The torque meter of claim 6 , wherein the first set of teeth and the second set of teeth are configured to engage at a root portion. 8. The torque meter of claim 7 , wherein the first set of teeth and the second set of teeth comprise an upper portion and the root portion, and wherein a gap remains between the upper portions of adjacent protrusions when the root portions of the adjacent teeth engage. 9. The torque meter of claim 7 , wherein the root portions of the first set of teeth and the second set of teeth are configured to support forces that are greater than those generated when the yield torque is applied to the drive shaft. 10. A drive shaft apparatus, comprising: a first rotary member having a first set of elements spaced apart around its circumference at a first end; a second rotary member arranged coaxially with said first rotary member, the second rotary member having a second set of elements spaced apart around its circumference at a first end, the elements in the second set spaced apart from the elements in the first set when the first and second rotary members are at rest, a second end of the first rotary member fixedly connected to a second end of the second rotary member; and a sensor positioned adjacent the first set and second set of elements, the sensor configured to measure a gap between the first set of elements and the second set of elements; wherein the first rotary member is configured to undergo torsion when a load is applied during rotation, the torsion causing the first set of elements to move closer to the second set of elements; and wherein the first set of elements are configured to engage the second set of elements when a torque load less than a yield torque is applied to the first rotary member, and wherein the second rotary member is configured to carry at least a portion of the torque load after the first set and second set of elements are engaged. 11. The drive shaft apparatus of claim 10 , wherein the first rotating member is a drive shaft and the second rotating member is a witness tube. 12. The drive shaft apparatus of claim 10 , wherein the first set of elements and the second set of elements are teeth that are configured to engage at a root portion. 13. The drive shaft apparatus of claim 12 , wherein the first set of elements and the second set of elements comprise an upper portion and the root portion, and wherein a gap remains between the upper portions of adjacent protrusions when the root portions of the adjacent protrusions engage. 14. The drive shaft apparatus of claim 12 , wherein the root portions of the first set of elements and the second set of elements are configured to support forces that are greater than those generated when the yield torque is applied to the rotating member. 15. The drive shaft apparatus of claim 10 , wherein a torque capacity of the first rotary member is increased when the first set of elements engage the second set of elements due to sharing of the torque load with the second rotary member. 16. The drive shaft apparatus of claim 15 , wherein the increased torque capacity of the first rotary member provides a significant increase in a safety margin over a complete loss of torque of the drive shaft apparatus.