Temporal Analysis of Temperature Distribution at a Laser Spot in Selective Laser Thermoregulation Using a High-Speed Radiation Thermometer

Temporal Analysis of Temperature Distribution at a Laser Spot in Selective Laser Thermoregulation Using a High-Speed Radiation Thermometer

To clarify the mechanical properties of new high heat-resistant materials, the Selective Laser Thermoregulation (SET) method, a method of accelerated heating tests using a high-power laser, is being developed. The SET method uses a galvano scanner to scan the surface of the area to be heated with a...

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Veröffentlicht in:Journal of laser micro nanoengineering 2024-09, Vol.19 (2), p.140-144
Hauptverfasser: Kanai, Shuta, Ohkubo, Tomomasa, Ui, Shota, Kawarazaki, Yusaku, Matsunaga, Ei-ichi, Goto, Ken, Kagawa, Yutaka
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Sprache:eng
Schlagworte:
Accelerated tests
Aircraft
Airplane engines
Curve fitting
Fiber lasers
Heat
Heat resistant materials
High power lasers
High speed
High temperature
Laser beam heating
Lasers
Mechanical properties
Radiation
Radiation tolerance
Scanners
Temperature distribution
Thermometers
Thermometry
Thermoregulation
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container_end_page 144
container_issue 2
container_start_page 140
container_title Journal of laser micro nanoengineering
container_volume 19
creator Kanai, Shuta
Ohkubo, Tomomasa
Ui, Shota
Kawarazaki, Yusaku
Matsunaga, Ei-ichi
Goto, Ken
Kagawa, Yutaka
description To clarify the mechanical properties of new high heat-resistant materials, the Selective Laser Thermoregulation (SET) method, a method of accelerated heating tests using a high-power laser, is being developed. The SET method uses a galvano scanner to scan the surface of the area to be heated with a fiber laser, aiming to heat the sample while dynamically compensating the temperature distribution. However, the SET method has a problem: the sample's temperature distribution fluctuates spatially and temporally due to the movement of the irradiation point of the laser, which heats the target to a high temperature. In this study, a 400 W fiber laser was scanned back and forth over the sample at scan speeds of 5, 10, and 15 m/s, respectively, and the sample temperature distribution was measured using a high-speed radiation thermometer at 1000 fps. The temperature distribution of the sample was measured using a high-speed radiation thermometer at 1000 fps. The amount of temperature increase at the laser spot was evaluated by curve fitting. The temperature increases at the laser spot decreased to 95.0, 85.1, and 75.7 К when the scan speeds were increased to 5, 10, and 15 m/s, respectively. For all scan speeds, the temperature increase at the laser spot was smaller at locations where the sample temperature was higher. The local temperature increase at the laser spot was successfully suppressed to about 4.5% of the maximum temperature of the entire sample without the laser spot.
doi_str_mv 10.2961/ilmn.2024.02.2008
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source Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals
subjects Accelerated tests
Aircraft
Airplane engines
Curve fitting
Fiber lasers
Heat
Heat resistant materials
High power lasers
High speed
High temperature
Laser beam heating
Lasers
Mechanical properties
Radiation
Radiation tolerance
Scanners
Temperature distribution
Thermometers
Thermometry
Thermoregulation
title Temporal Analysis of Temperature Distribution at a Laser Spot in Selective Laser Thermoregulation Using a High-Speed Radiation Thermometer
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