English
Arabic
Chinese (Simplified)
Dutch
Esperanto
French
German
Greek
Italian
Japanese
Korean
Portuguese
Russian
Spanish
UrduResearchers from the University of Edinburgh, in a study (DOI: 10.1007/s40436-024-00515-y) published on August 7, 2024 in Advances in Manufacturing, have integrated three-dimensional (3D) scanning technology with computer aided design (CAD) models to track and monitor pipeline assembly progress. By comparing real-time scans with as-designed models, this approach empowers operators to spot potential issues early, preventing them from escalating into major problems. The study’s findings, validated using both real-world and synthetic datasets, demonstrate the effectiveness of this innovative approach.
The research presents a novel system that merges 3D scanning with CAD models to enhance quality control during pipeline assembly. The process leverages unorganised point clouds from 3D scans to detect deviations and component clashes early in the installation phase. A deep learning model, trained on synthetic datasets that replicate real-life conditions, classifies pipeline components with high accuracy, allowing for the precise identification of misalignments. This approach was tested on a downscaled prototype, showcasing how automated classification and CAD comparisons significantly reduce manual inspections and error rates. By providing real-time feedback, the system enables operators to address issues immediately, cutting down on rework and improving overall assembly efficiency. This seamless integration automates quality control, ensuring that critical deviations are detected early.
Dr. Nan Yu, Senior Lecturer in Digital Manufacture at the University of Edinburgh, emphasized the impact of this technology: “This approach represents a significant step forward in pipeline installation and quality control. By leveraging the latest in 3D scanning and AI technologies, we can detect errors before they become critical, saving time and resources in the assembly process.”
The study’s implications extend across industries that rely on complex pipeline installations, including oil, gas, and shipbuilding. By facilitating early detection of deviations and potential clashes, the method not only minimizes costly rework but also enhances overall assembly efficiency. This technology can serve as a valuable addition to current quality control protocols, seamlessly integrating into existing manufacturing workflows to improve productivity, reduce downtime, and ensure the accuracy of complex installations.
###
References
DOI
Original Source URL
https://doi.org/10.1007/s40436-024-00515-y
Funding information
This research was founded by Scottish Research Partnership in Engineering (SRPe), the National Manufacturing Institute Scotland (NMIS), ShapeSpace Ltd (Grant No. SFC-NMIS-IDP/020), and State Key Laboratory of Robotics and System (Grant No. SKLRS/2022/ KF/01).
About Advances in Manufacturing
As an innovative, fundamental and scientific journal, Advances in Manufacturing aims to describe the latest regional and global research results and forefront developments in advanced manufacturing field. All articles in Advances in Manufacturing are peer reviewed. Respected scholars from the fields of advanced manufacturing fields will be invited to write some comments. The targeted fields include: manufacturing automation, mechatronics and robotics, precision manufacturing and control, micro-nano-manufacturing, green manufacturing, design in manufacturing, metallic and nonmetallic materials in manufacturing, metallurgical process, etc. The forms of articles include (but not limited to): academic articles, research reports, and general reviews. As such, it serves as an international platform for academic exchange between experts, scholars and researchers in this field.
