Towards automated damage detection for in-situ remanufacturing
Remanufacturing is the restoration of used products to a like-new condition, with warranty matching the original product. It is labour intensive, and faces problems of increasing labour costs, labour shortage, and varying quality of work between individuals, but can be solved by automation. Howev...
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| Format: | Thesis-Doctor of Philosophy |
| Language: | English |
| Published: |
Nanyang Technological University
2021
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| Online Access: | https://hdl.handle.net/10356/146561 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Remanufacturing is the restoration of used products to a like-new condition, with
warranty matching the original product. It is labour intensive, and faces problems
of increasing labour costs, labour shortage, and varying quality of work between
individuals, but can be solved by automation. However, in the marine and
offshore industry, the large parts are impractical to disassemble and transport to
remanufacture offsite, and hence it should be carried out in-situ. With automated
in-situ remanufacturing, there is increased safety, efficiency in material use,
reduced turnaround time, and in turn reduced costs, and is the motivation for it.
However, there is a lack of a formal framework for such remanufacturing to
ensure repeatability and accountability, and is first established in this thesis.
A laborious remanufacturing process that benefits from automation is the
inspection process, specifically damage detection and classification. It is
preferable to automate damage detection from 3D data over 2D images, as the
3D data of the detected damage region is required for the hybrid manufacturing
process in the downstream repair procedure. Although the ideal 3D damage
detection method is comparing the scanned 3D model to the as-built model, some
as-built models of legacy parts may be missing, whilst other damaged parts may
differ from the as-built model due to undocumented modifications, or allowable
deformations. As such, this research focuses on automating damage detection
from only the 3D scan data of the part, for use in downstream repair processes.
The unoptimized computational efficiency for geometric learning, and lack of
training data inhibits the direct application of machine learning for damage
detection from 3D data. A literature review reveals that current 3D damage
detection methods are unable to detect different damage types, have assumptions
on the geometry of the undamaged part, or require additional inputs, representing
a significant gap within the knowledge, and is filled by this research. Selected
algorithms for 3D damage detection reviewed are implemented, alongside
several proposed novel algorithms for dimensionality reduction. The extracted
features are then processed via machine learning, with different machine learning
models compared. The models were trained and demonstrated on synthetic scan
data due to the limited access to real-world data, followed by validation of the
trained model on real scan of physically damaged parts. The proposed approach
can detect different types of damage from 3D scan data without assumptions on
the undamaged part geometry or requiring additional inputs, with a sensitivity of
95.9%, representing a substantial improvement over current 3D damage detection
methodologies. Based on the visual results, damaged regions are largely
identified, although the proposed approach has difficulties identifying the exact
borders of the damage region. The same approach is also implemented to classify
the damage type, attaining an accuracy of 73.2%. However, it should be noted
that the proposed approach may wrongly identify certain intended features as
damage, such as debossed text, and is also sensitive to noise in the data.
While there are other enabling technologies required to fully automate in-situ
remanufacturing, this thesis only focuses on the processes leading up to the
damage detection and classification. |
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