Method and system for immersion ultrasound inspection including within downwardly opening cavities

What is claimed is: 1. A method for immersion based ultrasonic, non-destructive evaluation of an area of interest within a sleeve neck of a tubular steam inlet sleeve for a steam turbine engine, the area of interest including a portion of the sleeve neck defining a trepan fillet radius surface that is in communication with an outer wall of the inlet sleeve and an inner wall of a circumferential sleeve which is circumferentially spaced, in opposing relationship with the outer wall of the inlet sleeve, and a sleeve slope formed in the sleeve neck, above the trepan fillet radius, the sleeve slope bridging the inlet-sleeve outer wall and an outer wall of the circumferential sleeve, the method comprising: providing a tubular steam inlet sleeve, having an outlet end, a sleeve neck, which defines a trepan fillet radius surface portion, proximate an opposite end of the sleeve, and a sleeve cavity in communication with both of said ends, the sleeve neck having an area of interest including: the trepan fillet radius surface, in communication with both an adjoining outer wall of the inlet sleeve and an adjoining inner wall of a circumferential sleeve, with the circumferential sleeve oriented in opposing, circumferentially spaced relationship with the outer wall of the inlet sleeve, and a sleeve slope formed in the sleeve neck, above the trepan fillet radius surface, the sleeve slope bridging the inlet-sleeve outer wall and an outer wall of the circumferential sleeve; providing an ultrasonic inspection system for inspecting the area of interest in the inlet sleeve, having: a shaft assembly, having a shaft centerline axis, for insertion into the sleeve cavity through one of said inlet sleeve ends; first and second phased array, immersion ultrasonic probes, respectively coupled to an upstream distal end of the shaft assembly in opposed 180 degree circumferential positions, selectively positioned radially with respect to the shaft centerline axis, for transmitting ultrasonic waves through surrounding immersion fluid and into a scan volume of the area of interest within the inlet sleeve, bounded by respective extreme upper and lower beam angles, wherein the difference between the upper and lower beam angles is between 30 to 60 degrees, relative to a radius of the shaft assembly, receiving responsive echo ultrasonic waves, and converting the received waves into a test data stream; an inflatable bladder coupled to a downstream proximal end of the shaft assembly, for insertion into the sleeve cavity and for subsequent inflation to establish a fluid tight seal within the sleeve cavity upstream of the bladder, facilitating immersion of the first and second ultrasonic probes; a motion control system, coupled to the first and second ultrasonic probes and the shaft assembly, for: selectively rotating the first and second ultrasonic probes circumferentially with respect to the shaft assembly and the sleeve cavity, selectively translating at least part of the shaft assembly in an axial direction that is parallel to its centerline axis and the inlet sleeve neck, and generating first and second ultrasonic probes transducer position data; an ultrasonic testing instrument interfacing with the first and second ultrasonic probes, for receiving and processing the test data stream into processed data, in order to identify potential defect location and size characteristics within the scan volume of the scanned inlet sleeve; and a controller interfacing with the ultrasonic testing instrument and the motion control system, for receiving the processed data and the first and second ultrasonic probes respective transducer position data, and for identifying potential defect location and size characteristics within the scan volume of the area of interest of the inspected inlet sleeve; inserting the distal end of the shaft assembly, along with the first and second ultrasonic probes and the bladder, into the inlet sleeve cavity; aligning the respective beam angles of the first and second ultrasonic probes, so that their respective lower and upper extreme angles bound in the axial dimension the scan volume of the area of interest of the sleeve neck there between, by selectively positioning said probes radially with respect to the shaft centerline axis and axially by translating at least of the shaft assembly with the motion control system; inflating the bladder and establishing a fluid tight seal within the inlet sleeve cavity upstream of the bladder; introducing fluid upstream of the inflated bladder, immersing the first and second ultrasonic probes in the fluid; transmitting with the respective first and second probes ultrasonic waves through the fluid in the cavity surrounding the probes and into the scan volume of the area of interest of the sleeve neck; receiving responsive echo ultrasonic waves and converting the received waves into a test data stream with the respective first and second ultrasonic probes; rotating the shaft assembly 180 degrees with the motion control system, in order to capture, collectively with both of the first and second ultrasonic probes, a full 360 degree circumferential and axial inspection scan of entire scan volume of the area of interest within the inlet sleeve neck, and generate a test data stream thereof, and generating corresponding transducer position data with the motion control system; receiving and processing the test data stream into processed data with the ultrasonic testing instrument, in order to identify potential defect location and size characteristics in the scan volume of the area of interest within the inlet sleeve neck; receiving the processed data and the respective transducer position data, and identifying potential defect location and size characteristics within the scan volume of the area of interest within the inlet of the sleeve neck, with the controller. 2. The method of claim 1 , the provided shaft assembly comprising a pair of tubular, first and second nested shafts movable relative to each other; the first and second ultrasonic probes and motion control system coupled to the first shaft, the probes movable axially and circumferentially relative to the cavity under control of the motion control system; and the bladder coupled to the second shaft. 3. The method of claim 2 , the provided shaft assembly further comprising: a stationary third shaft circumscribed by the first shaft, for guiding axial and radial motion of the first shaft; and the second shaft circumscribing the first shaft, defining a fluid passage there between, for introduction of probe immersion fluid upstream of the bladder. 4. The method of claim 3 , the provided inspection system further comprising: the third shaft having tubular construction, and captured therein a probe communication cable, for interfacing with the ultrasonic testing instrument; a first coupling portion affixed to a distal end of the cable; a second coupling portion affixed to the probe; the first and second coupling portions selectively attachable to each other for establishing communication of the data test stream from the probe to the ultrasonic testing instrument. 5. The method of claim 1 , further comprising providing inflatable bellows coupled to the shaft assembly upstream of the first and second ultrasonic probes, for inhibiting propagation of immersion fluid upstream of the probe, and inflating the bellows to establish a fluid tight seal, for retaining immersion fluid downstream thereof. 6. The method of claim 1 comprising: orienting the tubular steam inlet sleeve vertically, so that the sleeve neck is above the outlet end thereof; inserting the distal end of the shaft assembly upwardly into the sleeve outlet end into the sleeve cavity; inflating the bladder to establish a fluid tight seal, for retaining i