Measurement of core temperature through semi-transparent polyamide 6 using scanner-integrated pyrometer in laser welding

Measurement of core temperature through semi-transparent polyamide 6 using scanner-integrated pyrometer in laser welding

•The core temperature during laser transmission welding of polyamide 6 is measured for the first time.•A two-dimensional finite element process simulation for laser transmission welding is build.•A measurement and evaluation procedure for the determination of optical properties of plastics is shown....

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Veröffentlicht in:International journal of heat and mass transfer 2020-01, Vol.146, p.118814, Article 118814
Hauptverfasser: Schmailzl, Anton, Käsbauer, Johannes, Martan, Jiří, Honnerová, Petra, Schäfer, Felix, Fichtl, Maximilan, Lehrer, Tobias, Tesař, Jiří, Honner, Milan, Hierl, Stefan
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Sprache:eng
Schlagworte:
Absorptivity
Carbon black
Computation
Computer simulation
Diameters
Emitters
Heat
Joining
Laser beam welding
Laser transmission welding
Lasers
Polyamide resins
Polymers
Pyrometer
Semi-transparent polymer
Sensitivity analysis
Spectral emittance
Temperature distribution
Temperature measurement
Thermal radiation
Thermal simulation
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container_end_page
container_issue
container_start_page 118814
container_title International journal of heat and mass transfer
container_volume 146
creator Schmailzl, Anton
Käsbauer, Johannes
Martan, Jiří
Honnerová, Petra
Schäfer, Felix
Fichtl, Maximilan
Lehrer, Tobias
Tesař, Jiří
Honner, Milan
Hierl, Stefan
description •The core temperature during laser transmission welding of polyamide 6 is measured for the first time.•A two-dimensional finite element process simulation for laser transmission welding is build.•A measurement and evaluation procedure for the determination of optical properties of plastics is shown.•A universally usable analytical heat emission model for semi-transparent materials is build up. Predicting the core temperature during welding is an ambitious aim in many research works. In this work, a 3D-scanner with integrated pyrometer is characterized and used to measure the temperature during quasi-simultaneous laser transmission welding of polyamide 6. However, due to welding in an overlap configuration, the heat radiation emitted from the joining zone of a laser transmission weld has to pass through the upper polymer, which is itself a semi-transparent emitter. Therefore, the spectral filtering of the heat radiation in the upper polymer is taken into account by calibrating the pyrometer for the measurement task. Thermal process simulations are performed to compare the temperature field with the measured temperature signal. The absorption coefficients of the polymers are measured, in order to get precise results from the computation. The temperature signals during welding are in good agreement with the computed mean temperature inside the detection spot, located in the joining area. This is also true for varying laser power, laser beam diameter and the carbon black content in the lower polymer. Both, the computed mean temperature and the temperature signal are representing the core temperature. In order to evaluate the spatial sensitivity of the measurement system, the emitted heat radiation from both polymers is calculated on basis of the computed temperature field. Hereby it is found, that more than 90 percent of the detected heat radiation comes from the joining area, which is a crucial information for contact-free temperature measurement tasks on semi-transparent polymers.
doi_str_mv 10.1016/j.ijheatmasstransfer.2019.118814
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Predicting the core temperature during welding is an ambitious aim in many research works. In this work, a 3D-scanner with integrated pyrometer is characterized and used to measure the temperature during quasi-simultaneous laser transmission welding of polyamide 6. However, due to welding in an overlap configuration, the heat radiation emitted from the joining zone of a laser transmission weld has to pass through the upper polymer, which is itself a semi-transparent emitter. Therefore, the spectral filtering of the heat radiation in the upper polymer is taken into account by calibrating the pyrometer for the measurement task. Thermal process simulations are performed to compare the temperature field with the measured temperature signal. The absorption coefficients of the polymers are measured, in order to get precise results from the computation. The temperature signals during welding are in good agreement with the computed mean temperature inside the detection spot, located in the joining area. This is also true for varying laser power, laser beam diameter and the carbon black content in the lower polymer. Both, the computed mean temperature and the temperature signal are representing the core temperature. In order to evaluate the spatial sensitivity of the measurement system, the emitted heat radiation from both polymers is calculated on basis of the computed temperature field. 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Predicting the core temperature during welding is an ambitious aim in many research works. In this work, a 3D-scanner with integrated pyrometer is characterized and used to measure the temperature during quasi-simultaneous laser transmission welding of polyamide 6. However, due to welding in an overlap configuration, the heat radiation emitted from the joining zone of a laser transmission weld has to pass through the upper polymer, which is itself a semi-transparent emitter. Therefore, the spectral filtering of the heat radiation in the upper polymer is taken into account by calibrating the pyrometer for the measurement task. Thermal process simulations are performed to compare the temperature field with the measured temperature signal. The absorption coefficients of the polymers are measured, in order to get precise results from the computation. The temperature signals during welding are in good agreement with the computed mean temperature inside the detection spot, located in the joining area. This is also true for varying laser power, laser beam diameter and the carbon black content in the lower polymer. Both, the computed mean temperature and the temperature signal are representing the core temperature. In order to evaluate the spatial sensitivity of the measurement system, the emitted heat radiation from both polymers is calculated on basis of the computed temperature field. 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subjects Absorptivity
Carbon black
Computation
Computer simulation
Diameters
Emitters
Heat
Joining
Laser beam welding
Laser transmission welding
Lasers
Polyamide resins
Polymers
Pyrometer
Semi-transparent polymer
Sensitivity analysis
Spectral emittance
Temperature distribution
Temperature measurement
Thermal radiation
Thermal simulation
title Measurement of core temperature through semi-transparent polyamide 6 using scanner-integrated pyrometer in laser welding
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