Vacuum adhering apparatus for automated maintenance of airfoil-shaped bodies

The invention claimed is: 1. An apparatus comprising: a frame; a vacuum adherence device coupled to said frame, said vacuum adherence device comprising a seal, the orientation of said seal relative to said frame being adaptable; a carriage linearly displaceably coupled to said frame; a first motor for driving linear displacement of said carriage along said frame; an end effector coupled to said carriage, said end effector being configured to perform a maintenance function, wherein said maintenance function consists of at least one of the following: nondestructive inspection, drilling, scarfing, grinding, fastening, appliqué application, ply mapping, depainting, cleaning, and painting; a drive wheel rotatably coupled to said frame; and a second motor for driving rotation of said drive wheel. 2. The apparatus as recited in claim 1 , further comprising a ball-and-socket bearing coupled to said frame or to said vacuum adherence device, wherein a ball of said ball-and-socket bearing is disposed within or in proximity to an area bounded by said seal and protrudes beyond said seal. 3. The apparatus as recited in claim 2 , wherein said vacuum adherence device comprises a vacuum plate having a channel, said seal is attached to and projects from a side of said vacuum plate, and said ball-and-socket bearing is coupled to said vacuum plate in an area bounded by said seal, said apparatus further comprising a vacuum port in flow communication with a space adjacent said area bounded by said seal via said channel. 4. The apparatus as recited in claim 3 , wherein said vacuum plate comprises flexible material capable of conforming to a shape of a confronting surface of an airfoil-shaped body. 5. The apparatus as recited in claim 3 , wherein said vacuum plate comprises a plurality of rigid segments, a plurality of continuous membranes connecting said plurality of rigid segments in series, and a plurality of hinges which pivotably couple adjacent rigid segments of said plurality of rigid segments. 6. The apparatus as recited in claim 2 , further comprising an attachment plate having a first channel, wherein said vacuum adherence device comprises a suction cup having a second channel in flow communication with said first channel, said suction cup and said ball-and-socket bearing being attached to said attachment plate, and said second channel having an opening surrounded by said seal. 7. The apparatus as recited in claim 6 , wherein said suction cup comprises: a sleeve housing attached to said attachment plate; a sleeve comprising a first portion displaceably coupled to said sleeve housing and a second portion comprising a bearing surface; and a socket ring pivotably coupled to said second portion of said sleeve and comprising a bearing surface in contact with said bearing surface of said second portion of said sleeve, said seal being attached to said socket ring. 8. An apparatus comprising: a frame; an attachment plate coupled to said frame; and a plurality of suction cups, each of said suction cups comprising a sleeve housing attached to said attachment plate, a sleeve comprising a first portion displaceably coupled to said sleeve housing and a second portion comprising a bearing surface, a socket ring pivotably coupled to said second portion of said sleeve and comprising a bearing surface in contact with said bearing surface of said second portion of said sleeve, and a seal attached to said socket ring. 9. The apparatus as recited in claim 8 , further comprising: a carriage linearly displaceably coupled to said frame; a first motor for driving linear displacement of said carriage along said frame; an end effector coupled to said carriage, said end effector being configured to perform a maintenance function, wherein said maintenance function consists of at least one of the following: nondestructive inspection, drilling, scarfing, grinding, fastening, appliqué application, ply mapping, depainting, cleaning, and painting; a drive wheel rotatably coupled to said frame; and a second motor for driving rotation of said drive wheel. 10. The apparatus as recited in claim 8 , further comprising first and second ball-and-socket bearings, each of said first and second ball-and-socket bearings comprising a socket attached to said attachment plate and a ball rotatably coupled to said socket. 11. An apparatus comprising: a frame; a vacuum plate coupled to said frame, said vacuum plate comprising a channel; a seal attached to and projecting from a side of said vacuum plate; a vacuum port in flow communication with a space adjacent an area bounded by said seal via said channel of said vacuum plate; a carriage linearly displaceably coupled to said frame; a first motor for driving linear displacement of said carriage along said frame; an end effector coupled to said carriage, said end effector being configured to perform a maintenance function, wherein said maintenance function consists of at least one of the following: nondestructive inspection, drilling, scarfing, grinding, fastening, appliqué application, ply mapping, depainting, cleaning, and painting; a drive wheel rotatably coupled to said frame; and a second motor for driving rotation of said drive wheel. 12. The apparatus as recited in claim 11 , wherein said vacuum plate comprises flexible material capable of conforming to a shape of a confronting surface of an airfoil-shaped body. 13. The apparatus as recited in claim 11 , wherein said vacuum plate comprises a plurality of rigid segments, a plurality of continuous membranes connecting said plurality of rigid segments in series, and a plurality of hinges which pivotably couple adjacent rigid elements of said plurality of rigid elements. 14. The apparatus as recited in claim 11 , further comprising a plurality of ball-and-socket bearings coupled to said vacuum plate, wherein said vacuum plate can be positioned adjacent a portion of an airfoil-shaped body in a manner such that said seal is adjacent to and balls of said plurality of ball-and-socket bearings are in contact with that portion of the airfoil-shaped body. 15. A method for coupling a crawler vehicle to an airfoil-shaped body, comprising: equipping the crawler vehicle with vacuum adherence devices; placing the vacuum adherence devices in positions such that respective seals of those vacuum adherence devices are adjacent to respective portions of the surface of the airfoil-shaped body; partially evacuating respective channels of the vacuum adherence devices to produce floating adherence of the crawler vehicle to the surface of the airfoil-shaped body; equipping the crawler vehicle with ball-and-socket bearings, a drive wheel and a motor for driving rotation of the drive wheel; placing the ball-and-socket bearings and the drive wheel in contact with respective portions of the surface of the airfoil-shaped body, the drive wheel being oriented to roll in a spanwise direction along the surface of the airfoil-shaped body; and driving the drive wheel to rotate. 16. A system comprising: an airfoil-shaped body having a surface; a frame; a first vacuum adherence device comprising a channel and a seal capable of adapting to a contour of said surface, wherein said first vacuum adherence device is coupled for concurrent movement with said frame; a vacuum system coupled to enable partial evacuation of said channel of said first vacuum adherence device, wherein said vacuum system comprises an electrically controllable valve; a drive wheel in contact with said airfoil-shaped body, wherein said drive wheel is rotatably coupled to said fr