Abstract

This paper presents the design of a low-cost, compact instrumentation system to enable six degree of freedom motion tracking of acetal bricks within an experimental model of a cracked Advanced Gas-Cooled Reactor (AGR) core. The system comprises optical and inertial sensors and capitalises on the advantages offered by data fusion techniques. The optical system tracks LED indicators, allowing a brick to be accurately located even in cluttered images. The LED positions are identified using a geometrical correspondence algorithm, which was optimised to be computationally efficient for shallow movements, and complex camera distortions are corrected using a versatile Incident Ray-Tracking calibration. Then, a Perspective-Ray-based Scaled Orthographic projection with Iteration (PRSOI) algorithm is applied to each LED position to determine the six degree of freedom pose. Results from experiments show that the system achieves a low Root Mean Squared (RMS) error of 0.2296 mm in x, 0.3943 mm in y, and 0.0703 mm in z. Although providing an accurate measurement solution, the optical tracking system has a low sample rate and requires the line of sight to be maintained throughout each test. To increase the robustness, accuracy, and sampling frequency of the system, the optical system can be augmented with an Inertial Measurement Unit (IMU). This paper presents a method to integrate the optical system and IMU data by accurately timestamping data from each set of sensors and aligning the two coordinate axes. Once miniaturised, the developed system will be used to track smaller components within the AGR models that cannot be tracked with current instrumentation, expanding reactor core modelling capabilities.

Highlights

  • Within the UK, several Advanced Gas-Cooled Reactor (AGR) cores are currently approaching the end of their design life [1]

  • In collaboration with EDF and SNC-Lavalin’s Atkins business’, the University of Bristol developed the Multi-Layer Array (MLA) [3], which is a quarter-sized model of an AGR core

  • Developing this compact and accurate instrumentation was essential, as it is necessary to show that the relative motions of the Triply Cracked Brick (TCB) and Quadruply Cracked Bricks (QCB) bricks in the MLA during testing agrees with that produced by FE modelling of the array, helping to validate the modelling approach being used for the reactor safety cases

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Summary

Introduction

Within the UK, several Advanced Gas-Cooled Reactor (AGR) cores are currently approaching the end of their design life [1]. This paper describes the design and development of cheap, compact instrumentation, which will satisfy these design constraints and is capable of achieving sub-millimetre and sub-degree accuracy in all six DOF between the QCB components. Developing this compact and accurate instrumentation was essential, as it is necessary to show that the relative motions of the TCB and QCB bricks in the MLA during testing agrees with that produced by FE modelling of the array, helping to validate the modelling approach being used for the reactor safety cases. Timestamping and aligning the axes of the optical and inertial data and the future development is discussed, showing that it is possible to develop a cheap but compact instrumentation system that will allow accurate monitoring of the relative motions of the TCB and QCB bricks during MLA testing

Instrumentation Concept
Selection of Optical Tracking Algorithm
System Description
Optical Tracking Methodology
Image Acquisition
Image Filtering
IRT Calibration Algorithm
PRSOI Algorithm
Implementation of Algorithm
Compute Position
Camera Calibration
PRSOI Accuracy
Timestamping and Aligning the Axes of the Optical and Inertial Data
Optical Tracking Timestamps
Screen Synchronisation
Camera Initialisation Time
IMU Timestamps
Common Coordinate System between Optical and IMU Data
System Development
Conclusions

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