Autonomous inspection of a surface topology of an airfoil of a gas turbine engine

The invention claimed is: 1 . An autonomous device for inspecting surface topology of an airfoil of a gas turbine engine, the autonomous device comprising: a base; means for coupling the base to the airfoil in a manner that permits movement of the base across the airfoil while remaining coupled thereto; means for moving the base across the airfoil while remaining coupled thereto; a tactile gel sensor extending from the base to the airfoil when the base is coupled thereto, the tactile gel sensor including: a flexible optical gel having nominally planar opposite surfaces defining a nominal gel thickness extending over an image area; a lighting element configured to illuminate the flexible optical gel from an end surface between the nominally planar opposite surfaces flexible optical gel; a plurality of airfoil contacting members extending between one of the nominally planar opposite surfaces of the flexible optical gel and the airfoil when the base is coupled thereto, thereby distorting the flexible optical gel in response to changes in the surface topology of the airfoil; and a two-dimensional imager that images the flexible optical gel over the image area, thereby capturing two-dimensional images; and a surface topology calculator attached to the base and electrically connected tactile gel sensor and configured to locate defects in the surface topology of the airfoil based on the two-dimensional images captured by the two-dimensional imager. 2 . The autonomous device of claim 1 , wherein each of the plurality of airfoil contacting member causes a geometrical artifact to be imaged at a corresponding pixel region within each of the two-dimensional images captured by the two-dimensional imager, the geometrical artifact being indicative of the surface topology at a location where the airfoil contacting member contacts the airfoil. 3 . The autonomous device of claim 2 , wherein the surface topology calculator is trained to associate each of the geometrical artifacts with a surface condition or surface image features within a library of surface conditions or surface image features. 4 . The autonomous device of claim 2 , wherein the surface topology calculator determines surface topology at a location where the airfoil contacting member contacts the airfoil based on a metrics of the geometrical artifacts. 5 . The autonomous device of claim 4 , wherein a nominal shape of the geometrical artifacts is a circle. 6 . The autonomous device of claim 5 , wherein the shape of the geometrical artifact is a circle in response to the plurality of airfoil contacting members contacting a planar surface parallel to the surface of the nominally planar surface of the flexible optical gel. 7 . The autonomous device of claim 5 , wherein the geometrical artifact becomes non-circular in response to the airfoil contacting member contacting a defect in the airfoil. 8 . The autonomous device of claim 7 , wherein an angle of a major or minor axis of the non-circular elliptical geometrical artifact is indicative of an orientation of the defect in the airfoil. 9 . The autonomous device of claim 1 , wherein the means for coupling the base to the airfoil uses contacting member that couples the base to the airfoil using van der Waals force. 10 . The autonomous device of claim 1 , wherein the means for coupling the base to the airfoil includes: a sealing element circumscribing an evacuation chamber, the sealing element configured to engage the surface of the airfoil; and a vacuum pump configured to evacuate the evacuation chamber, thereby causing the autonomous device to adhere to the surface of the airfoil. 11 . The autonomous device of claim 1 , wherein the means for moving the base across the airfoil includes: a wheel extending from the base so as to engage the airfoil when the base is coupled thereto; and a motor configured to rotate the wheel, thereby moving the base across the airfoil when coupled thereto. 12 . The autonomous device of claim 1 , wherein the means for moving the base across the airfoil includes: an arm or leg that sequentially positions itself so as to engage the airfoil and, using static friction, pushes or pulls the base across the airfoil when coupled thereto. 13 . The autonomous device of claim 1 further comprising: means for steering the base as it moves across the airfoil. 14 . The autonomous device of claim 13 further comprising: edge sensors that sense the edge of the airfoil. 15 . The autonomous device of claim 14 further comprising: a navigation computer configured to control the means for steering the base and the means for moving the base across the airfoil so as to map the surface topology of the airfoil. 16 . The autonomous device of claim 15 , wherein the navigation computer is configured to cause the base to move across the airfoil in a serpentine fashion. 17 . The autonomous device of claim 1 , wherein each of the plurality of airfoil contacting members is a ball bearing. 18 . The autonomous device of claim 1 , wherein each of the plurality of airfoil contacting members has a pointed tip configured to contact the airfoil. 19 . A method for inspecting surface topology of an airfoil of a gas turbine engine, the method comprising: adhering a base of an autonomous device to the airfoil in a manner that permits movement of the base across the airfoil while remaining coupled thereto; moving the base of the autonomous device across the airfoil while remaining coupled thereto; extending a tactile gel sensor from the base to the airfoil when the base is coupled thereto, the tactile gel sensor: providing a flexible optical gel having nominally planar opposite surfaces defining a nominal gel thickness extending over an image area; extending a plurality airfoil contacting members between one of the nominally planar opposite surfaces of the flexible optical gel and the airfoil; illuminating, via a lighting element, the flexible optical gel from an end surface between the nominally planar opposite surfaces of the flexible optical gel; distorting the elastic containment vessel in response to changes in the surface topology of the airfoil as transmitted to the flexible optical gel via the plurality of airfoil contacting members; and imaging, via a two-dimensional optical imager, the optical gel over the image area, thereby creating two-dimensional images; and locating, via a surface topology calculator, defects in the surface topology of the airfoil based on the two-dimensional images. 20 . The method of claim 19 , wherein: each of the plurality of airfoil contacting member causes a geometrical artifact to be imaged at a corresponding pixel region within the two-dimensional image created by the two-dimensional imager, the shape of the geometrical artifact being indicative of the surface topology at a location where the airfoil contacting member contacts the airfoil, and the surface topology calculator determines surface topology at a location where the airfoil contacting member contacts the airfoil based on a metric of the geometrical artifact.