Experimental Analysis and Identification of Thermodynamic Transfer Functions of the Laser Remelting Process Towards Developing Process Control
| dc.contributor.advisor | Tutunea-Fatan, Ovidiu-Remus | |
| dc.contributor.advisor | Bordatchev, Evgueni | |
| dc.contributor.author | Meyer, Patrick | |
| dc.date.accessioned | 2025-12-01T18:16:37Z | |
| dc.date.issued | 2025-10-02 | |
| dc.description.abstract | Laser remelting (LRM) is a laser-based technique for surface modification, capable of polishing and restructuring surfaces at high speed and with full automation. However, LRM is sensitive to thermodynamic disturbances, making real-time monitoring and process control essential for achieving consistent results. This thesis investigates thermographic (TG) monitoring as a basis for closed-loop control of LRM. A coaxial thermographic camera was used to record transient responses of the molten pool under variations in laser power, scanning speed, and exposure time. The resulting image sequences were reduced to scalar signals, enabling identification of first-order transfer functions (TFs) that capture the dynamic relationship between process inputs and thermographic outputs. In addition to classical image signatures, a novel Gaussian parameterization strategy was introduced to describe thermographic distributions. These Gaussian descriptors not only allow reconstruction of missing image regions but also provide physically interpretable features, such as intensity and distribution width, parameters that were shown to align with conventional signatures. The findings demonstrate that exposure time is as influential as laser power or scanning speed in shaping thermographic response, and that Gaussian parameters offer an expanded set of feedback variables for process control. Together, these results establish a foundation for future closed-loop strategies in LRM, where real-time thermographic feedback can be systematically linked to surface quality outcomes. | |
| dc.description.copyright | Patrick Meyer 2025 | |
| dc.identifier.uri | https://hdl.handle.net/20.500.14721/39181 | |
| dc.language.iso | en | |
| dc.publisher | The University of Western Ontario | |
| dc.rights | Attribution-NonCommercial-ShareAlike 4.0 International | en |
| dc.subject | Laser remelting | |
| dc.subject | surface polishing | |
| dc.subject | closed-loop control | |
| dc.subject | thermographic monitoring | |
| dc.subject | thermographic response | |
| dc.subject | first-order transfer function | |
| dc.subject | normal distribution | |
| dc.subject | image reconstruction | |
| dc.subject | transient analysis. | |
| dc.title | Experimental Analysis and Identification of Thermodynamic Transfer Functions of the Laser Remelting Process Towards Developing Process Control | |
| dc.type | thesis | |
| oaire.license.condition | http://creativecommons.org/licenses/by-nc-sa/4.0/ | |
| thesis.degree.discipline | Mechanical and Materials Engineering | |
| thesis.degree.grantor | The University of Western Ontario | |
| thesis.degree.name | M Eng Sci | |
| uwo.description.laySummary | Laser remelting (LRM) is a process for altering the surface of a material by creating a small liquid pool on the surface, it can be used to produce a variety of features including structures or polishes. LRM is advantageous as a polishing method for its speed and automation; surface polishing by laser remelting (SP-LRM) can be fully computer controlled and completed in a fraction of the time of a manual polishing operation. In order to fully realise the capabilities of SP-LRM, method for monitoring and reacting to the system in real-time are required. Within this research a thermographic (TG) camera is used to watch the area where the laser is applied. Multiple experiments are performed where the camera records the laser while its travelling. The images recorded for each experiment form the experimental response that will be used for analysing how the system reacts to differing inputs. A method for describing the relationship of the input and output over time, called a transfer function (TF), is used to compare reactiveness over different experiments. The analysis will consider the input as laser power and the output as specific values calculated from each image, called image signatures, that describe a particular property. The TFs are used to illustrate changes in each experiment, using linear approximation, when properties like laser power, scanning speed, and thermographic exposure are varied. Strategies for describing the information within each image and demonstrating how it relates across the entirety of each experiment are also explored. Images are described using equations that will recreate the information and allow for restoration of missing areas. Images demonstrate their relation across the operating area when combined to show how strong each image is in relation to where it was applied. The characterization of each image introduces new values that will function as additional image signatures and expand the available information. The descriptions of image data and the information about changes in process response presented within this work are key steps for developing systems to provide feedback and control the LRM process. |
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