Loadcell probe for overload protection

What is claimed is: 1 . A probe assembly for materials testing, comprising: a probe arranged and configured for contact with a materials testing sample, the probe further including a component of a switch mechanism wherein, in a first position of the probe, the switch mechanism is closed and, in a second position of the probe, the switch mechanism is open; a load cell coupling arranged and configured to be driven by a materials testing machine; a spring placed between the probe and the load cell coupling; the spring, in response to forces below a pre-selected threshold, transfers force between the probe and the load cell coupling and maintains the probe in the first position so that the switch mechanism is in a closed configuration, and, in response to force above a pre-selected threshold, compresses and moves the probe to the second position so that the switch mechanism is open. 2 . The probe assembly of claim 1 wherein the spring is a coil spring loaded in a compression state. 3 . The probe assembly of claim 2 wherein at least a portion of the probe is surrounded by a first cylindrical wall portion. 4 . The probe assembly of claim 3 wherein at least a portion of the spring is surrounded by a second cylindrical wall portion. 5 . The probe assembly of claim 4 wherein the first cylindrical wall includes first cap, the first cap further including an aperture through which the probe extends. 6 . The probe assembly of claim 5 wherein the second cylindrical wall includes a second cap and wherein the second cap is attached to the load cell coupling, a first end of the spring engages the probe and a second end of the spring is nested within the second cap. 7 . The probe assembly of claim 6 wherein the switch assembly includes a plug extending through the first cylindrical wall portion. 8 . The probe assembly of claim 6 wherein the switch assembly is arranged and constructed to be operatively connected to a materials testing machine. 9 . The probe assembly of claim 6 wherein the switch assembly is arranged and constructed to be electrically wired to a stop mechanism of a materials testing machine driving the load cell coupling. 10 . The probe assembly of claim 6 wherein the first cylindrical wall portion is separable from the second cylindrical wall portion. 11 . The probe assembly of claim 10 wherein the first cylindrical wall portion includes an inner cylindrical wall portion and wherein the second cylindrical wall portion fits concentrically over the inner cylindrical wall portion. 12 . The probe assembly of claim 6 wherein a cap assembly is attached to the second cylindrical wall portion, the cap assembly including an aperture through which a portion of the load cell coupling extends. 13 . The probe assembly of claim 12 wherein the load cell coupling includes a mechanical stop element to limit travel of the load cell coupling into the second cylindrical wall portion. 14 . The probe assembly of claim 6 wherein the probe includes a tip for contacting a materials testing sample. 15 . The probe assembly of claim 6 wherein the first cylindrical wall portion and the second cylindrical wall portion have a common longitudinal axis. 16 . A probe assembly for materials testing, comprising: a probe arranged and configured for contact with a materials testing sample, the probe being surrounded by a first wall portion; a load cell coupling arranged and configured to be driven by a materials testing machine, the load cell coupling engaging a second wall portion; a spring placed between the probe and the load cell coupling; the spring, in response to forces below a pre-selected threshold, transfers force between the probe and load cell coupling and maintains the probe in the first position and, in response to force above a pre-selected threshold, compresses and moves the probe to the second position; the second position causing the probe to travel past a pre-determined threshold which is detected by the materials testing machine, and operation of the materials testing machine is terminated by detection of travel of the probe past the pre-determined threshold. 17 . The probe assembly of claim 16 wherein the spring is a coil spring loaded in a compression state. 18 . The probe assembly of claim 17 wherein the first wall portion includes first cap, the first cap further including an aperture through which the probe extends. 19 . The probe assembly of claim 18 wherein the second wall portion includes a second cap. 20 . The probe assembly of claim 19 wherein the second cap is attached to the load cell coupling, a first end of the coil spring engages the probe and a second end of the spring is nested within the second cap.