Internal inspection of machinery by stitched surface imaging

The invention claimed is: 1. A method of inspecting an interior surface of a component of a gas turbine engine comprising: inserting a scope into an inner portion of the component without removing the component from the engine; obtaining a first set of circumferential photographs around a circumference of the interior surface at a given axial reference position therein with a camera on a distal end of the scope; and digitally stitching the first set of photographs to form a stitched view of the interior surface at the given axial reference position. 2. The method of claim 1 , further comprising; removing a pilot fuel nozzle from a pilot fuel port of a combustor installed on the gas turbine engine; inserting the scope into the combustor via the pilot fuel port; and rotating the camera on the distal end of the scope over 360 degrees at the axial reference position. 3. The method of claim 1 , further comprising: obtaining further sets of circumferential photographs at respective further axial reference positions; stitching the first and further sets of circumferential photographs of the interior surface to form a comprehensive image of the interior surface; and determining a condition of the interior surface by analysis of the comprehensive image for indications of use and degradation of the interior surface. 4. The method of claim 3 , further comprising mapping and projecting the comprehensive image onto a three-dimensional engineering model of the interior surface, creating a digital visual model of the interior surface in a computer. 5. The method of claim 3 , further comprising defining a three-dimensional geometry of the interior surface by scanning the interior surface with a 3D surface scanner in the distal end of the scope, and digitally modeling the interior surface in three dimensions by mapping the comprehensive image onto the three-dimensional geometry of the interior surface creating a digital visual model of the interior surface in a computer for interactive viewing. 6. The method of claim 5 , further comprising: creating a degree of roughness contour on the comprehensive image by computerized contouring of a roughness of the interior surface defined by the 3D scanner, and further quantifying the indications of use and degradation of the interior surface by computer analysis of the degree of roughness contour. 7. The method of claim 3 , further comprising: creating a set of intensity contours on the comprehensive image by computerized contouring of colors and shadings in the comprehensive image, and quantifying the indications of use and degradation of the interior surface by computer analysis of the set of intensity contours. 8. The method of claim 7 , wherein the quantifying comprises computing an area within each contour, computing gradients and overlaps of the contours, and computing a shape aspect of each contour. 9. The method of claim 7 , further comprising indicating an alert status by computerized flashing of one of the contours on the comprehensive image. 10. A method of evaluating a condition of an interior surface of a gas turbine combustor and transition duct, comprising: creating a sequence of comprehensive images of the interior surface over a respective time sequence of successive digital camera inspections of the gas turbine combustor; generating by computer a set of color and shading intensity contours on each of the comprehensive images; identifying and tracking by computer ones of the contours over successive ones of the comprehensive images; plotting a time series of a size of each tracked contour; and evaluating by computer the time series for indications of degradation of the interior surface. 11. The method of claim 10 , further comprising providing a computerized alert when an acceleration of a degradation rate is found in the time series. 12. The method of claim 10 , further comprising performing computerized identification of aspects of size, gradient, shape, and overlap of the contours, and computerized analysis of said aspects for the indications of degradation of the interior surface. 13. The method of claim 10 , further comprising forming each comprehensive image by obtaining a circumferential sequence of photographs around a circumference of the interior surface at each of a sequence of axial positions along a 3D centerline of the interior surface; and digitally stitching the photographs together. 14. The method of claim 13 , further comprising; removing a pilot fuel nozzle from a pilot fuel port of the gas turbine combustor; inserting a scope into the combustor via the pilot fuel port; rotating a camera on a distal end of the scope around the circumference of the interior surface at each of the sequence of axial positions to obtain each circumferential sequence of photographs. 15. The method of claim 13 , further comprising defining a three-dimensional geometry of the interior surface by scanning the interior surface with a 3D surface scanner in the distal end of the scope, and digitally modeling the interior surface in three dimensions by mapping the comprehensive image onto the three-dimensional geometry of the interior surface creating a digital visual model of the interior surface in a computer for interactive viewing. 16. The method of claim 15 further comprising performing computerized analysis of a degree of a roughness of the interior surface as defined by the 3D scanner. 17. A method for evaluating a condition of an interior surface of a component in a gas flow path of a gas turbine, comprising: forming a comprehensive image of the interior surface over a circumference and a length thereof by digitally stitching a plurality of individual images of the interior surface obtained from a device on a scope inserted into the component; and determining the condition of the interior surface by creating contours of colors in the comprehensive image and analyzing the contours thereof for indicators of the condition of the interior surface. 18. The method of claim 17 , further comprising: before forming the comprehensive image, painting the interior surface with a thermal imaging paint, and starting and running the gas turbine; and stopping the gas turbine, and forming the comprehensive image.