Non-destructive ultrasonic inspection apparatus, systems, and methods

What is claimed is: 1. A system for inspecting a component, comprising: an ultrasonic inspection probe comprising a component surface interface; a robotic device comprising an end effector coupled to the ultrasonic inspection probe by an articulation subsystem comprising a two-axis gimbal structure arranged to passively absorb pitch and roll movement of the ultrasonic inspection probe, wherein the robotic device is automatably controllable to move the ultrasonic inspection probe across a surface of the component; an angle sensor subsystem coupled to the two-axis gimbal structure, wherein the angle sensor subsystem is configured to operably detect an actual orientation of the end effector relative to a presently inspected portion of the surface of the component; and a controller configured to receive orientation data from the angle sensor subsystem based on the actual orientation of the end effector, compare the actual orientation to a desired orientation, and control the robotic device to adjust the actual orientation of the end effector to be in the desired orientation. 2. The system of claim 1 , wherein the desired orientation comprises a longitudinal axis of the end effector perpendicular to the presently inspected portion of the surface of the component. 3. The system of claim 1 , wherein the articulation subsystem is coupled between the inspection probe and the end effector, and further wherein the articulation subsystem is configured to operably maintain the component surface interface properly engaged with the presently inspected portion of the surface of the component. 4. The system of claim 3 , wherein the two-axis gimbal structure is coupled between the ultrasonic inspection probe and the end effector, and further wherein the two-axis gimbal structure, being configured to passively absorb pitch and roll movement of the ultrasonic inspection probe maintains the component surface interface substantially parallel to the presently inspected portion of the surface of the component. 5. The system of claim 4 , wherein the articulation subsystem further comprises a pneumatic actuator coupled between the two-axis gimbal structure and the end effector, wherein the pneumatic actuator is configured to passively absorb movement of the ultrasonic inspection probe, via the two-axis gimbal structure, along an axis substantially perpendicular to the presently inspected portion of the surface of the component. 6. The system of claim 4 , wherein the angle sensor subsystem comprises a plurality of transducers coupled to the two-axis gimbal structure. 7. The system of claim 6 , wherein the plurality of transducers comprises a rotary variable differential transformer (RVDT) coupled to each axis of the two-axis gimbal structure. 8. The system of claim 1 , wherein the ultrasonic inspection probe comprises: a housing; an ultrasonic array coupled to the housing; a component surface interface of the housing, the component surface interface comprising a liquid couplant port, an engagement lip engageable with a surface of the component, and at least one vacuum port, wherein the engagement lip circumferentially circumscribes the liquid couplant port and the at least one vacuum port circumferentially circumscribes the engagement lip, wherein the at least one vacuum port is fluidly coupleable with a vacuum source; a liquid couplant chamber disposed between the ultrasonic array and the liquid couplant port of the component surface interface, wherein the liquid couplant chamber is in fluid communication with the liquid couplant port and the liquid couplant chamber is fluidly coupleable with a liquid couplant supply; and the articulation subsystem coupled to the housing and configured to operably maintain the engagement lip of the component surface interface properly engaged with the presently inspected portion of the surface of the component. 9. An apparatus for inspecting a component, comprising: a housing; an ultrasonic array coupled to the housing; a component surface interface of the housing, the component surface interface comprising a liquid couplant port, an engagement lip engageable with a surface of the component, and at least one vacuum port, wherein the engagement lip has an annular shape and circumferentially circumscribes the liquid couplant port and the at least one vacuum port has an annular shape and circumferentially circumscribes the engagement lip, wherein the at least one vacuum port is fluidly coupleable with a vacuum source; a liquid couplant chamber disposed between the ultrasonic array and the liquid couplant port of the component surface interface, wherein the liquid couplant chamber is in fluid communication with the liquid couplant port and the liquid couplant chamber is fluidly coupleable with a liquid couplant supply; and an end effector of a robotic device, coupled to an articulation subsystem, wherein the robotic device is automatably controllable to move the apparatus across the surface of the component; wherein the articulation subsystem comprises a two-axis gimbal structure coupled between the housing and the end effector, and is configured to operably maintain the component surface interface properly engaged with a presently inspected portion of the surface of the component. 10. The apparatus of claim 9 , further comprising a central axis extending from the ultrasonic array and through the liquid couplant chamber and liquid couplant port, wherein the articulation subsystem is configured to operably maintain the central axis substantially perpendicular to the presently inspected portion of the surface of the component. 11. The apparatus of claim 9 , wherein the engagement lip of the component surface interface is protruded relative to the at least one vacuum port so as to be positionable closer to the surface of the component relative to the at least one vacuum port. 12. The apparatus of claim 9 , wherein the two-axis gimbal structure is configured to passively absorb pitch and roll movement of the housing. 13. The apparatus of claim 9 , wherein the articulation subsystem further comprises a pneumatic actuator coupled between the two-axis gimbal structure and the end effector, wherein the pneumatic actuator is configured to passively absorb movement of the housing, via the two-axis gimbal structure, along an axis substantially perpendicular to the presently inspected portion of the surface of the component. 14. The apparatus of claim 9 , further comprising: an angle sensor subsystem coupled to the two-axis gimbal structure, wherein the angle sensor subsystem is configured to detect an actual orientation of the end effector relative to the presently inspected portion of the surface of the component; and a controller configured to receive orientation data from the angle sensor subsystem corresponding to the actual orientation of the end effector, compare the actual orientation to a desired orientation, and control the robotic device to adjust the actual orientation of the end effector to be in the desired orientation. 15. The apparatus of claim 14 , wherein the desired orientation comprises a longitudinal axis of the end effector perpendicular to the presently inspected portion of the surface of the component. 16. The apparatus of claim 14 , wherein the angle sensor subsystem comprises a plurality of transducers coupled to the two-axis gimbal structure. 17. The apparatus of claim 16 , wherein the plurality of transducers comprises a rotary variable differential transformer (RVDT) coupled to each axis of the two-axis gimbal structure. 18. A method