Self contained load frame for in-situ inspection

The invention claimed is: 1. A load frame, comprising: a first gripper configured to position a first end of a test sample; a second gripper configured to position a second end of the test sample; a center tube that encircles a test region; a first end tube that encircles the first gripper and is axially aligned with the center tube; and a second end tube that encircles the second gripper and is axially aligned with the center tube and the first end tube, wherein: the center tube is positioned between the first end tube and the second end tube; the test region is disposed between the first gripper and the second gripper; and the center tube is configured to allow passage of a penetrating wave through the center tube to the test region. 2. The load frame of claim 1 , wherein the first end tube is a first cylinder, the second end tube is a second cylinder, and the center tube is a third cylinder. 3. The load frame of claim 2 , further comprising: a first tube cap that physically contacts the first end tube and the center tube; and a second tube cap that physically contacts the second end tube and the center tube. 4. The load frame of claim 3 , wherein: the first tube cap defines a first slot configured to receive the test sample; and the second tube cap defines a second slot configured to receive the test sample. 5. The load frame of claim 4 , further comprising: a first end cap that physically contacts the first end tube; and a second end cap that physically contacts the second end tube. 6. The load frame of claim 5 , further comprising a tensioner configured to apply a compressive force to the first end tube, the second end tube, and the center tube, and further configured to applied a tensile load to the test sample. 7. The load frame of claim 6 , wherein the tensioner comprises a jack bolt extending through a hole in the second end cap and at least one external nut attached to the jack bolt, wherein the tensile load applied to the test sample is configured to be adjusted through manual rotation of the external nut. 8. The load frame of claim 7 , wherein the tensioner is attached to the second gripper and is configured to move the second gripper toward and away from the first gripper during rotation of the external nut. 9. The load frame of claim 8 , wherein: the tensioner further comprises a midplate positioned between the second gripper and the second end cap; the midplate comprises a central opening therein; and the jack bolt extends through the central opening in the midplate. 10. The load frame of claim 9 , further comprising at least one clevis pin that extends through the second end cap and through the midplate, wherein the at least one clevis pin is configured to reduce or prevent torsional stresses in the test sample during rotation of the external nut. 11. The load frame of claim 10 , further comprising an adapter attached to the midplate and to the second gripper. 12. The load frame of claim 11 , further comprising a tension plate attached to the first gripper and having a bottom surface, wherein the second end cap comprises a flat edge that rests on the bottom surface of the tension plate and is configured to slide along the bottom surface during rotation of the external nut. 13. The load frame of claim 11 , further comprising a test sample having a first end, a second end, and a mid-portion between the first end and the second end, wherein the first gripper positions the first end, the second gripper positions the second end, and the center tube encircles the mid-portion. 14. The load frame of claim 1 , wherein the first gripper is a first clamp comprising a first pair of opposing jaws, and the second gripper is a second clamp comprising a second pair of opposing jaws. 15. A method for performing a test, measurement, and/or inspection on a test sample, comprising: securing a first end of the test sample within a first gripper; placing a first end tube over the first gripper such that the first end tube encircles the first gripper; inserting a second end of the test sample through a first slot in a first tube cap; positioning the first tube cap onto the first end tube; inserting the second end of the test sample into a center tube; physically contacting the center tube with the first tube cap; inserting the second end of the test sample through a second slot in a second tube cap; physically contacting the second tube cap with the center tube; securing the second end of the test sample within a second gripper; placing a second end tube over the second gripper such that the second end tube encircles the second gripper; and exerting a tensile load on the test sample using a tensioner while a mid-portion of the test sample is positioned within the center tube, the first gripper secures the first end of the test sample, and the second gripper secures the second end of the test sample. 16. The method of claim 15 , further comprising exerting a compressive force on the first end tube, the second end tube, and the center tube during the exerting of the tensile load on the test sample. 17. The method of claim 16 , further comprising rotating an external nut on a jack bolt to increase the tensile load on the test sample. 18. The method of claim 17 , further comprising attaching the second gripper to the tensioner subsequent to the securing of the second end of the test sample within the second gripper and prior to the exerting of the tensile load on the test sample. 19. The method of claim 18 , wherein the first end tube, the second end tube, and the center tube are cylinders, and the method further comprises axially aligning the first end tube, the second end tube, and the center tube, each with the other. 20. A load frame, comprising: a first gripper configured to position a first end of a test sample; a second gripper configured to position a second end of the test sample; a test region positioned between the first gripper and the second gripper; a center tube that encircles the test region; a first end tube that encircles the first gripper; and a second end tube that encircles the second gripper, wherein: the center tube is positioned between the first end tube and the second end tube; and the center tube is configured to allow passage of a penetrating wave through the center tube to the test region.