Method and system for surface profile inspection of off-line industrial gas turbines and other power generation machinery

What is claimed is: 1. A method for non-contact, internal inspection, including relative height sizing of component surface profiles, within an assembled power generation machine; the method comprising: providing an internal inspection system apparatus having: a base; an inspection scope having a proximal end for coupling to the base; an extendable elongated body defining a central axis, extended and driven by a linear drive that is capable of remote actuation by a control system; and a distal end that is insertable into an inspection port of and maneuvering within an internal cavity of an assembled power generation machine to an internal area of interest; a laser profilometer head, coupled to the inspection scope distal end, including a laser profilometer having a two-dimensional height and width scanning field of view that is capable of remote scanning field image capture by, and image transmission to a control system; and a control system coupled to the linear drive and the laser profilometer, for maneuvering the laser profilometer scanning field of view to an area of interest within the assembled power generation machine by actuation of the linear drive, for capturing a scanning field of view image thereof, and for converting said image into relative two-dimensional height/width relative sizing data; providing an assembled power generation machine having an inspection port that is in communication with an internal cavity and internal area of interest in the machine; attaching the base to the machine in a fixed position relative to the inspection port; inserting the inspection scope distal end, including the laser profilometer head, into the inspection port; coupling the inspection scope proximal end to the base; maneuvering the laser profilometer scanning field of view within the internal cavity to an internal area of interest by actuating the linear drive with the control system; capturing a scanning field of view image data of the area of interest by actuating the laser profilometer with the control system; transferring the captured image data to the control system; and converting the captured image data into two-dimensional height/width relative sizing data of the area of interest with the control system. 2. The method of claim 1 , further comprising identifying component surface features, including perforations in surfaces, surface coating spallation, surface coating delamination, or gaps between opposed surfaces, including tip gap, with the two-dimensional sizing data. 3. The method of claim 1 , further comprising converting the captured image data into a two-dimensional height/width relative sizing, surface profile map. 4. The method of claim 1 , further comprising generating three-dimensional height/width/length relative sizing data of the area of interest, by: moving the scanning field of view relative to the surface of the area of interest by actuating the linear drive with the control system; capturing a plurality of scanning field of view images data at multiple spatial positions along a drive path of the linear drive by actuating the laser profilometer with the control system; transferring the plurality of captured images data to the control system; and converting the plurality of captured images data into a three-dimensional height/width/length relative sizing data of the area of interest with the control system. 5. The method of claim 4 , further comprising identifying component surface features, including perforations in surfaces, surface coating spallation, surface coating delamination, or gaps between opposed surfaces, with the three-dimensional sizing data. 6. The method of claim 5 , further comprising determining relative cross sectional area dimensions of component surface features with the three-dimensional sizing data. 7. The method of claim 4 , further comprising converting the captured image data into a three-dimensional height/width/length relative sizing surface profile map with the control system. 8. The method of claim 1 , further comprising: the provided inspection system further including: the base having a mounting flange for affixation to an inspection port; the inspection scope further having a rotational drive coupled to the control system and the laser profilometer head, and an articulation drive coupled to the control system and the laser profilometer head, for rotating and articulating the laser profilometer scanning field relative to the inspection scope centerline axis; and maneuvering the laser profilometer scanning field of view within the internal cavity to an internal area of interest by actuating the rotational or articulation drives with the control system. 9. A method for measuring blade tip gap in an assembled turbine engine power generation machine, having an inspection port in communication with open inter-row spacing volume between an opposing turbine vane and turbine blade row, comprising: providing an assembled turbine engine, having an inspection port in communication with open inter-row spacing volume between an opposing turbine vane and turbine blade row; providing an internal inspection system apparatus having: a base; an inspection scope having a proximal end for coupling to the base; an extendable elongated body defining a central axis, extended and driven by a linear drive that is capable of remote actuation by a control system; and a distal end that is insertable into an inspection port of, and maneuvering within an internal cavity of an assembled power generation machine to an internal area of interest; a laser profilometer head, coupled to the inspection scope distal end, including a laser profilometer having a two-dimensional height and width scanning field of view that is capable of remote scanning field image capture by, and image transmission to a control system; and a control system coupled to the linear drive and the laser profilometer, for maneuvering the laser profilometer scanning field of view to an area of interest within the assembled power generation machine by actuation of the linear drive, for capturing a scanning field of view image thereof, and for converting said image into two-dimensional height/width relative sizing data; inserting and coupling the inspection scope to the engine in a fixed position relative to the inter-row communicating inspection port; maneuvering the laser profilometer scanning field of view within the inter-row spacing volume to scan turbine blade tip gap defined between a turbine blade tip surface and its corresponding opposed circumferential abradable surface of the turbine engine casing, by actuating the linear drive with the control system; capturing the tip gap scanning field of view image data by actuating the laser profilometer with the control system; transferring the corresponding tip gap captured image data to the control system; converting the captured image data into a two-dimensional height/width relative sizing data of the corresponding blade tip and abradable opposed surfaces defining the tip gap; and determining blade tip gap with the relative sizing data. 10. The method of claim 9 , further comprising generating a three-dimensional height/width/length relative sizing surface profile map of the blade tip gap, by: moving the scanning field of view relative to the corresponding blade tip and abradable opposed surfaces defining the tip gap by actuating the linear drive with the control system; capturing a plurality of scanning field of view images data at multiple spatial positions along a drive path of the linear drive by actuating the laser profilometer with the control system; transferring the plurality of captured images data to the control system; and