The present disclosure relates to nondestructive inspection/evaluation (NDI/NDE), and more particularly to an extended reach apparatus and sensors used in NDI/NDE that detect defects in structures and parts.
Increases in the complexity of aerospace structures have made NDI/NDE, which terms are used interchangeably herein, more and more difficult to apply successfully and cost-effectively. Often, a region of a particular structure requires inspection, but is inaccessible for the application of conventional NDE methods. In some cases, inspection requirements of regions with limited access have prompted part removal to improve access, or expensive redesigns altogether. Conventional tools include extenders and manipulation arms to reach into limited access areas and to aid probe placement on or near limited access areas of aircraft. Such areas may be cavities or obstructed areas, and include, for example, the interior of aircraft wings.
When in operation, certain sensors for detection of defects in a surface are preferably seated on the surface, or at least require maintaining no more than a maximum clearance from the surface. When a sensor, for example an eddy current sensor, is not completely seated on the surface, which may be referred to as “lift-off,” the result may be a reduced sensitivity to small cracks.
A sensor may be applied to a surface that is not completely flat and require movement of the probe along the surface, or may be mounted to a rotating end of a probe for NDE in limited access areas. Either case may result in lift-off. For the rotating application, if the probe end is not exactly perpendicular to the surface to be inspected, the rotating path of the sensor will be eccentric; although the sensor may be flush with the surface at one point along the path, at an opposite point on the path (or some other location) there will be lift-off. Accordingly, an apparatus is needed that addresses lift-off to provide adequate sensitivity for detection of defects over the full range of motion of the sensor.
In accordance with an embodiment, an extended reach inspection apparatus may include a scanner device and a robotic manipulator arm. The robotic manipulator arm may include a plurality of arm segments including a distal end arm segment and a proximal end arm segment. A movable joint may couple the distal end arm segment to the robotic manipulator arm. A telescoping extension mechanism may be coupled to the distal end arm segment. The scanner device is mounted to the telescoping extension mechanism for moving the scanner device between a retracted position proximate to the robotic manipulator arm and an extended position at a distance from the robotic manipulator arm. A control handle may be coupled to the proximal end arm segment of the plurality of arm segments for manipulating the robotic manipulator arm.
In accordance with another embodiment, an extended reach inspection apparatus may include a robotic manipulator arm and a scanner device. The scanner device is coupled to the robotic manipulator arm. The scanner device may include a probe having a longitudinal axis, a first end, and a second, free end defining an opening, wherein the opening is offset from the longitudinal axis. The scanner device may also include a sensor for inspecting a target and providing an electrical output. The sensor is received in the opening and when the probe is rotated about the longitudinal axis, the sensor moves in a substantially circular path. The scanner device may additionally include a bias means received in the opening in-between the first end of the probe and the sensor to urge the sensor away from the first end of the probe.
In accordance with another embodiment, a method may include inserting a robotic manipulator arm through at least one inspection port of an enclosed structure. The robotic manipulator arm may include a plurality of arm segments and a telescoping extension mechanism coupled to a distal end arm segment of the plurality of arm segments. A scanner device is mounted to the telescoping extension mechanism for moving the scanner device between a retracted position proximate to the robotic manipulator arm and an extended position at a distance from the robotic manipulator arm for performing an inspection. The method may also include operating a movable joint that couples the distal segment to the robotic manipulator arm to position the scanner relative to a component for performing the inspection. The method may additionally include moving the telescoping extension mechanism to position the scanner over the component for performing the inspection.
In accordance with an embodiment and any of the previous embodiments, the telescoping extension mechanism may include a base platform. The scanner device may be coupled to one side of the base platform and a track follower may be mounted to an opposite side of the base platform. The telescoping extension mechanism may also include a telescope extension track mounted to the distal end arm segment of the robotic manipulator arm. The track follower is configured to move along the telescope extension track between the retracted position and the extended position. The telescoping extension mechanism may also include a motor that moves the track follower along the telescope extension track. The controller controls the motor to move the scanner device between the retracted position and the extended position.
In accordance with an embodiment and any of the previous embodiments, the distal end arm segment may include a stationary portion coupled to the robotic manipulator arm by the movable joint and a rotatable portion rotationally coupled to the stationary portion. The distal end arm segment includes a longitudinal axis defined through the stationary portion and the rotatable portion. The rotatable portion is rotatable about the longitudinal axis relative to the stationary portion. The extended reach inspection apparatus may also include an indexing feature for determining an angle of rotation of the rotatable portion relative to the stationary portion.
In accordance with an embodiment and any of the previous embodiments, the extended reach apparatus may also include a midspar support apparatus configured to support the robotic manipulator arm between two spars of an enclosed structure. The midspar support apparatus may include a head fitting configured to releasably attach to an inspection port support member and the inspection port support member may be releasably attachable to a first inspection port in a first spar. The midspar support apparatus may also include a plurality of collapsible leg members extending from the head fitting. The plurality of collapsible leg members may be configured to contact a second spar opposite the first spar. The plurality of collapsible leg members are collapsible to fit through a second inspection port in the second spar.
Other aspects and features of the present disclosure, as defined solely by the claims, will become apparent to those ordinarily skilled in the art upon review of the following non-limited detailed description of the disclosure in conjunction with the accompanying figures.
The following detailed description of embodiments refers to the accompanying drawings, which illustrate specific embodiments of the disclosure. Other embodiments having different structures and operations do not depart from the scope of the present disclosure.
The following detailed description of embodiments refers to the accompanying drawings, which illustrate specific embodiments of the disclosure. Other embodiments having different structures and operations do not depart from the scope of the present disclosure. Like reference numerals may refer to the same element or component in the different drawings.
Certain terminology is used herein for convenience only and is not to be taken as a limitation on the embodiments described. For example, words such as “proximal”, “distal”, “top”, “bottom”, “upper,” “lower,” “left,” “right,” “horizontal,” “front,” “back,” “vertical,” “upward,” and “downward” merely describe the configuration shown in the figures or relative positions. The referenced components may be oriented in any direction and the terminology, therefore, should be understood as encompassing such variations unless specified otherwise.
The movable joints 24a-24e may be motorized joints and may be remotely controlled by a controller 26. An electrical cable 28 may operatively connect the controller 26 to the proximal end arm segment 20 of the robotic manipulator arm 12 to supply electrical power and control operation of the robotic manipulator arm 12. The electrical cable 28 may include electrical power wiring and control wiring for each of the movable joints 24a-24e. The electrical cable 28 may also include signal wiring for controlling operation of the scanner device 14 and for transmitting electrical signals to and from the scanner in response to performing an inspection by the inspection probe 16 on a target or component similar to that described herein. Electrical power wiring and signal wiring may extend through an interior of the robotic manipulator arm 12 for controlling operation of the movable joints 24a-24e and the scanner device 14 and for transmitting signals responsive to the inspection tests. An end of electrical cable 28 may include a suitable plug 28a as best shown in
The controller 26 may include a plurality of control devices or manipulators 30a, 30b, 30c, etc., such as rotatable dials, joy sticks or other types of control devices, for controlling the movable joints 24a-24e for articulating and rotating the arm segments 18-22c for positioning the scanner device 14 and inspection probe 16 for inspection of a component or target as described herein.
The robotic manipulator arm 12 may also include a control handle 32 coupled to the proximal end arm segment 20 for manipulating the robotic manipulation arm 12. The control handle 32 may be used by an operator for positioning and adjusting placement of the robotic manipulator arm 12 for performing inspections.
The NDI/NDE system 10 may also include a probe camera monitor 34. As described in more detail herein with reference to
NDI/NDE system 10 may also include a wide angle camera 38 and a wide angle camera monitor 40. The wide angle camera 38 may be coupled to an articulating arm 42. The articulating arm 42 may position the wide angle camera 38 for use in configuring the robotic manipulator arm 12 for inspection of a component or target.
The distal end arm segment 18 may include a stationary portion 18a and rotatable portion 18b that is rotationally coupled to the stationary portion 18a. The longitudinal axis 19 may be defined through the stationary portion 18a and the rotatable portion 18b. The rotatable portion 18b is rotatable about the longitudinal axis 19 relative to the stationary portion 18a. A motorized rotation joint 24f may rotate the rotatable portion 18b between about 0 degrees and about 180 degrees clockwise or counterclockwise relative to the stationary portion 18a. The motorized rotation joint 24f may be remotely controlled by the controller 26.
The robotic manipulator arm 12 may also include a telescoping extension mechanism 44 coupled to the distal end arm segment 18 of the robotic manipulator arm 12. The telescoping extension mechanism 44 may be attached to the rotatable portion 18b of the distal end arm segment 18. The scanner device 14 is mounted to the telescoping extension mechanism 44 for moving the scanner device 14 between a retracted position proximate the robotic manipulator arm 12 and an extended position at a distance from the robotic manipulator arm 12 for performing an inspection similar to that described herein. Referring also to
A track follower 48 is mounted to an opposite side of the base platform 46. The scanner device 14 may be attached to the spring biased portion 46b of the base platform 46 and the track follower 48 may be mounted to the stationary portion 46a of the base platform 46. The track follower 48 may include a first segment 48a and a second segment 48b. A telescope extension track 50 is mounted to the rotatable portion 18b of the distal end arm segment 18 of the robotic manipulator arm 12. The track follower 48 is configured to move along the telescope extension track 50 between the retracted position and the extended position.
The telescoping extension mechanism 44 also includes a motor 52 that moves the track follower 48 along the telescope extension track 50. The motor 52 may be mounted to the stationary portion 46a of the base platform 46 at a predetermined distance from the spring biased portion 46b to permit compression of the spring biased portion 46b when the inspection probe 16 is in contact with a component or target for performing an inspection. The controller 26 (
An electrical cable 54 may be connected between the stationary portion 18a of the distal end arm segment 18 and the telescoping extension mechanism 44 and the rotatable portion 18b of the distal end arm segment 18. The electrical cable 54 may include a first plug 56a that connects to electrical wiring in the stationary portion 18a of the distal end arm segment 18. As previously described, electrical power wiring and signal wiring may extend through the interior of the robotic manipulator arm 12 for controlling operation of the scanner device 14, telescoping extension mechanism 44 and multi-axis movable joints 24a-24f. The electrical cable 54 may also include a second plug 56b for electrically connecting to a receptacle 58 on the stationary portion 46a of the base platform 46 adjacent to the motor 52. The electrical cable 54 is of a sufficient length to allow the rotatable portion 18b of the distal end arm segment 18 to rotate a predetermined angle of rotation relative to the stationary portion 18a and for the telescope extension mechanism 44 to extend to the extended position. For example, the rotatable portion 18b may be rotated between about 0 degrees and at least about 180 degrees clockwise and counterclockwise relative to the stationary portion 18a.
Referring also to
The robotic manipulator arm 12 may also be extended through at least a second access hole or inspection access port 76 in the second spar 70. A midspar support apparatus 78 may be inserted and deployed in the enclosed structure 66 between the first spar 68 and the second spar 70 to support the robotic manipulator arm 12. Referring also to
A protective pad 88 may be disposed between the first spar 68 and the second spar 70. The protective pad 88 may also be extendable over a face 91 of the first spar 68. The protective pad 88 protects the interior area of the enclosed structure 66 between the first spar 68 and the second spar 78 and the face of the first spar 68 from damage during installation and removal of the midspar support apparatus 78 and the robotic manipulator arm 12 during an inspection procedure. For an interior area that is within an aircraft, aircraft components, such as wings and other flight control surfaces may be manufactured from a lightweight honeycomb sandwich structure including a cellular layer including a multiplicity of honeycomb shaped cells disposed or sandwiched between an inner layer of material and outer layer of material. The honeycomb sandwich structure may be damaged if impacted by the robotic manipulator arm 12 or midspar support apparatus 78.
Referring also to
The inspection port support member 80 may also include a substantially semi-circular shaped lip 94 extending from the flat top portion 90 (
The inspection port support member 80 may also include a threaded opening 96. The threaded opening 96 may be configured to matingly receive a screw 98 (
A tether 107 may be looped around the threaded bolt 109 of the knob 106 and another end of the tether 107 may be secured to the inspection probe 16. The scanner device 14 may include a scanner body 200. The inspection probe 16 may extend from the scanner body 200 on a rotating shaft 202 or spindle. The inspection probe 16 is removable from the scanner device 14 and may be dislodged from the scanner body 200 if the inspection probe 16 strikes an object during insertion or removal of the robotic manipulator arm 12 during an inspection procedure. The tether 107 connects the probe 16 to the scanner body 200 to prevent loss of the probe within an interior of a structure under inspection. The tether 107 will retain the inspection probe 16 with the scanner body 200 in response to the inspection probe 16 being pulled from the scanner device 14. In accordance with an embodiment, a collar 204 may be attached to the shaft 202. The collar 204 may include a groove 206 for receiving and retaining the tether 107. The tether 107 may be looped around the groove 206 in the collar 107 and fastened to retain the tether 107 within the groove 206. In another embodiment, the collar 107 may be a bearing fastened to the shaft 202 with a groove in an exterior portion of the bearing. The bearing allows the shaft 202 to rotate within the bearing and the tether 107 fastened within the groove in the exterior portion of the bearing is allowed free movement or to remain stationary as the shaft 202 rotates during performance of an inspection.
A spring 130, such as a coil spring as schematically shown, a leaf spring, compressible and resilient material, or other biasing means may be provided in between the proximal end of the bore 120 and the proximal end of the sensor 110, and urges the sensor 100 distally such that the sensor 100 may extend out of the bore 120 past the distal surface 132 of the housing 114. The spring loading increases the probe's compliance to the surface of the structure 906 under inspection. Seating of the eddy current sensor 100 over the fastener so that the sensor 100 lies as flat as possible on the structure 906 is generally desirable for conducting a proper inspection. The sensor 100 is retained in the bore 120 with a pin 134 that extends laterally through an opening 136 in the housing wall 126 and passes through a slot 138 in the sensor 100. The proximal side 140 of the slot 138 is blocked by the pin 134 as the spring 130 urges the sensor 100 to withdraw from the bore 120. The proximal side 140 of the slot 138 is located such that the sensor 100 may extend a predetermined distance X from the bore 120 below the distal surface 132 of the housing 114.
In addition, a joint 142 may be provided in the spindle 110 at the connection to the central member 112. The joint 142 may be, for example, a gimbal joint, a ball and socket type joint, or the like, and in the embodiment of an inspection probe 16 described herein, may allow for a deflection of, for example, at least approximately 12 degrees, with a preferred angle of at least 15 degrees between the spindle 110 and the longitudinal axis of the inspection probe 16. Joint deflection may be greater with other embodiments, and particularly in embodiments where the sensor 100 can extend a greater predetermined distance X from the bore 120 below the distal surface 132 of the housing 114 than in the exemplary embodiment described herein.
The joint 142 may be designed to transfer scan rotation through an angle as needed, but to return to a zero angle position when the end is free, which may be referred to as self-aligning. This self-aligning may be accomplished in a variety of ways, for example in a ball and socket type joint, using a non-spherical ball and socket that pulls slightly out and extends an inner spring when an angle away from the longitudinal axis of the inspection probe 16 is created. The spindle 110 and joint 142 rotate during scanning, as does the rest of the inspection probe 16.
In one exemplary embodiment, the inside diameter of the housing 114 is 0.5 inches, the housing wall 126 thickness distally from the central member 112 is 0.112 inches, the radius from the longitudinal axis of the inspection probe 16 to the longitudinal axis of the sensor 100 is 0.183 inches, and the predetermined distance X that the sensor 100 may extend past the distal surface 132 of the housing 114 is 0.008 inches.
The probe materials may include, for example, for the central member 112, spindle 110, spring 130, and pin 134, metals such as steel, stainless steel, or other steel alloy. The housing 114 may be molded plastic or other nonconductive material, which may be translucent to facilitate assembly and visualization of a fastener during scanning. The sensor 100 may be made of materials as known to one of ordinary skill in the art.
Curve A in
In a test with an eddy current sensor mounted to a probe without a spring to extend the sensor out of the housing, and a spindle with a joint allowing an angle of incidence of 10.5 degrees off of a line perpendicular to the target surface, the dot traveled along curve A approximately within range G as the sensor rotated. With a spring that allowed the sensor to extend 0.008 inches out of the housing, the joint angle could be increased to 15 degrees, and the dot traveled approximately only within range H, providing improved ability to accurately detect flaws.
There are some significant differences between aluminum and titanium structures when eddy current testing for surface flaws. Titanium electrical conductive is significant less than aluminum. This requires a much different coil driver frequency, which generate the eddy currents in the structure, to detect the surface flaw. These driver frequencies in titanium are much higher, which causes the eddy current depth-of-penetration to be significantly less, and detection of the crack more sensitive to different amounts of lift-off, or coil distances lifted-off the surface of the structure.
The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the disclosure. As used herein, the singular forms “a”, “an”, and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms “comprises” and/or “comprising,” when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.
Although specific embodiments have been illustrated and described herein, those of ordinary skill in the art appreciate that any arrangement which is calculated to achieve the same purpose may be substituted for the specific embodiments shown and that the embodiments herein have other applications in other environments. This application is intended to cover any adaptations or variations of the present disclosure. The following claims are in no way intended to limit the scope of the disclosure to the specific embodiments described herein.
The present application is a divisional application of U.S. application Ser. No. 14/803,758, filed Jul. 20, 2015 which is a continuation-in-part application of U.S. application Ser. No. 13/547,190, filed Jul. 12, 2012 (now U.S. Pat. No. 9,086,386). The contents of both are hereby incorporated herein by reference in their entirety.
Number | Date | Country | |
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Parent | 14803758 | Jul 2015 | US |
Child | 15922509 | US |
Number | Date | Country | |
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Parent | 13547190 | Jul 2012 | US |
Child | 14803758 | US |