Periodical macro stripes have been found on diamond film prepared on a Si substrate by the multifilament chemical vapor deposition (CVD) method when the filament substrate distance is less than 2 mm. The properties ...Periodical macro stripes have been found on diamond film prepared on a Si substrate by the multifilament chemical vapor deposition (CVD) method when the filament substrate distance is less than 2 mm. The properties of the stripe on the film were characterized qualitatively by a scanning electron microscope (SEM) and Raman scattering spectrometer. The measurement results show that this stripe corresponds to the different kinds of the microstructure and thickness of the film. Through calculation of the thermal radiation energy density distribution on the surface of substrate, this phenomenon can be explained successfully.展开更多
The model of heat source(MHS) which reflects the thermal interaction between materials and laser during processing determines the accuracy of simulation results. To acquire desirable simulations results, although vari...The model of heat source(MHS) which reflects the thermal interaction between materials and laser during processing determines the accuracy of simulation results. To acquire desirable simulations results, although various modifications of heat sources in the aspect of absorption process of laser by materials have been purposed, the distribution of laser power density(DLPD) in MHS is still modeled theoretically. However, in the actual situations of laser processing, the DLPD is definitely different from the ideal models. So, it is indispensable to build MHS using actual DLPD to improve the accuracy of simulation results. Besides, an automatic modeling method will be benefit to simplify the tedious pre-processing of simulations. This paper presents a modeling method and corresponding algorithm to model heat source using measured DLPD. This algorithm automatically processes original data to get modeling parameters and provides a step MHS combining with absorption models. Simulations and experiments of heat transfer in steel plates irradiated by laser prove the mothed and the step MHS. Moreover, the investigations of laser induced thermal-crack propagation in glass highlight the signification of modeling heat source based on actual DLPD and demonstrate the enormous application of this method in the simulation of laser processing.展开更多
文摘Periodical macro stripes have been found on diamond film prepared on a Si substrate by the multifilament chemical vapor deposition (CVD) method when the filament substrate distance is less than 2 mm. The properties of the stripe on the film were characterized qualitatively by a scanning electron microscope (SEM) and Raman scattering spectrometer. The measurement results show that this stripe corresponds to the different kinds of the microstructure and thickness of the film. Through calculation of the thermal radiation energy density distribution on the surface of substrate, this phenomenon can be explained successfully.
基金Project(2021YFF0500200) supported by the National Key R&D Program of ChinaProject(52105437) supported by the National Natural Science Foundation of China+1 种基金Project(202006120184) supported by the Heilongjiang Provincial Postdoctoral Science Foundation,ChinaProject(LBH-Z20054) supported by the China Scholarship Council。
文摘The model of heat source(MHS) which reflects the thermal interaction between materials and laser during processing determines the accuracy of simulation results. To acquire desirable simulations results, although various modifications of heat sources in the aspect of absorption process of laser by materials have been purposed, the distribution of laser power density(DLPD) in MHS is still modeled theoretically. However, in the actual situations of laser processing, the DLPD is definitely different from the ideal models. So, it is indispensable to build MHS using actual DLPD to improve the accuracy of simulation results. Besides, an automatic modeling method will be benefit to simplify the tedious pre-processing of simulations. This paper presents a modeling method and corresponding algorithm to model heat source using measured DLPD. This algorithm automatically processes original data to get modeling parameters and provides a step MHS combining with absorption models. Simulations and experiments of heat transfer in steel plates irradiated by laser prove the mothed and the step MHS. Moreover, the investigations of laser induced thermal-crack propagation in glass highlight the signification of modeling heat source based on actual DLPD and demonstrate the enormous application of this method in the simulation of laser processing.
