Autonomous Robotic Sensing for Simultaneous Geometric and Volumetric Inspection of Free-Form Parts

Mineo, Carmelo; Cerniglia, Donatella; Poole, Alastair

doi:10.1007/s10846-022-01673-6

Cited by 6 publications

(7 citation statements)

References 23 publications

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“…The ITRA toolbox has been designed to enable the seamless integration of industrial robotic arms with server computers, sensors, and actuators, providing a platform that is both highly adaptable and extendable [11]. It has extensively been adopted in robotic non-destructive testing applications [24,25]. It enables real-time adaptive robotic responses and the control of multiple robots simultaneously.…”

Section: System Integration Toolboxesmentioning

confidence: 99%

Electric Vehicle Battery Disassembly Using Interfacing Toolbox for Robotic Arms

Rastegarpanah,

Mineo,

Contreras

et al. 2024

Batteries

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This paper showcases the integration of the Interfacing Toolbox for Robotic Arms (ITRA) with our newly developed hybrid Visual Servoing (VS) methods to automate the disassembly of electric vehicle batteries, thereby advancing sustainability and fostering a circular economy. ITRA enhances collaboration between industrial robotic arms, server computers, sensors, and actuators, meeting the intricate demands of robotic disassembly, including the essential real-time tracking of components and robotic arms. We demonstrate the effectiveness of our hybrid VS approach, combined with ITRA, in the context of Electric Vehicle (EV) battery disassembly across two robotic testbeds. The first employs a KUKA KR10 robot for precision tasks, while the second utilizes a KUKA KR500 for operations needing higher payload capacity. Conducted in T1 (Manual Reduced Velocity) mode, our experiments underscore a swift communication protocol that links low-level and high-level control systems, thus enabling rapid object detection and tracking. This allows for the efficient completion of disassembly tasks, such as removing the EV battery’s top case in 27 s and disassembling a stack of modules in 32 s. The demonstrated success of our framework highlights its extensive applicability in robotic manufacturing sectors that demand precision and adaptability, including medical robotics, extreme environments, aerospace, and construction.

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Section: System Integration Toolboxesmentioning

confidence: 99%

Electric Vehicle Battery Disassembly Using Interfacing Toolbox for Robotic Arms

Rastegarpanah,

Mineo,

Contreras

et al. 2024

Batteries

Self Cite

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“…Robotic NDT inspections generally occur in a well-structured environment, where the part position is precisely registered with respect to the robot reference system. Great care is dedicated to ensuring the robot tool path is accurately referenced to the sample reference frame to ensure effective data collection during automated inspections [24]. Despite the efforts, a deviation between the actual tool path and the ideal tool path always remains due to the following reasons: (i) the physical tolerances in the robot joints; (ii) the geometric deviations in the mounting support of the sensing instrumentation; (iii) the residual inaccuracy in the calibration of the part position; (iv) the deviation between the actual sample geometry from the part digital counterpart.…”

Section: Misalignment Issue In Robotically-acquired Imagesmentioning

confidence: 99%

Fine Alignment of Thermographic Images for Robotic Inspection of Parts with Complex Geometries

Mineo

Montinaro

Fustaino

et al. 2022

Sensors

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Increasing the efficiency of the quality control phase in industrial production lines through automation is a rapidly growing trend. In non-destructive testing, active thermography techniques are known for their suitability to allow rapid non-contact and full-field inspections. The robotic manipulation of the thermographic instrumentation enables the possibility of performing inspections of large components with complex geometries by collecting multiple thermographic images from optimal positions. The robotisation of the thermographic inspection is highly desirable to improve assessment speed and repeatability without compromising inspection accuracy. Although integrating a robotic setup for thermographic data capture is not challenging, the application of robotic thermography has not grown significantly to date due to the absence of a suitable approach for merging multiple thermographic images into a single presentation. Indeed, such an approach must guarantee accurate alignment and consistent pixel blending, which is crucial to facilitate defect detection and sizing. In this work, an innovative inspection platform was conceptualised and implemented, consisting of a pulsed thermography setup, a six-axis robotic manipulator and an algorithm for image alignment, correction and blending. The performance of the inspection platform is tested on a convex-shaped specimen with artificial defects, which highlights the potential of the new combined approach. This work bridges a technology gap, making thermographic inspections more deployable in industrial environments. The proposed fine image alignment approach can find applicability beyond thermographic non-destructive testing.

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“…To get over these challenges, some six-axis robotic arm applications for automating ultrasonic nondestructive testing (NDT) inspection have been developed [5][6][7][8][9][10][11]. Other than these uses, automation has not been attained in other inspection kinds; thermographic infrared (IR) testing is one example of this.…”

Section: Introductionmentioning

confidence: 99%

Robotization of the IR-Thermographic technique – impact on the visualisation quality and considerations on the data workflow

Montinaro,

Mineo,

Pantano

et al. 2024

IOP Conf. Ser.: Mater. Sci. Eng.

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Quality control automation is becoming increasingly popular in industrial production lines. Active thermography techniques are well-regarded for their adaptability, providing fast, non-contact, and full-field non-destructive evaluation. Automating thermographic evaluation can increase assessment speed and repeatability without sacrificing inspection accuracy. By using a robot arm to manipulate the thermographic setup, it becomes possible to inspect large components and refine scans on suspicious zones, even in parts with complex geometries. In this study, the performance of a new thermographic inspection platform is compared with a conventional setup to showcase the potential improvements. A plastic curved-shaped sample with artificial flat bottom hole defects is used as a benchmark for the comparison. The advantages and disadvantages of robotizing the infrared non-destructive setup are analyzed, and the impact of the data workflow and future research activities are also discussed.

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Autonomous Robotic Sensing for Simultaneous Geometric and Volumetric Inspection of Free-Form Parts

Cited by 6 publications

References 23 publications

Electric Vehicle Battery Disassembly Using Interfacing Toolbox for Robotic Arms

Electric Vehicle Battery Disassembly Using Interfacing Toolbox for Robotic Arms

Fine Alignment of Thermographic Images for Robotic Inspection of Parts with Complex Geometries

Robotization of the IR-Thermographic technique – impact on the visualisation quality and considerations on the data workflow

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