In present day, laser beam machining technology attracts great attention due to its cost-effectiveness, high machining quality, mass manufacturing velocity and broad areas of applicability throughout different manufacturing industries. However, intensive researches are required since many materials with different properties (chemical and mechanical) are used in the manufacturing industries; and there is need for high quality machining through newly developed laser technologies. In this context, in this experimental research, unlike most studies in the literature, an investigation was carried out on heat affected zone (HAZ) occurring in AISI 4140 steel machined by laser beam in different cutting geometries (triangle, square and circle cutting). In the present study, when the average HAZ widths calculated according to the laser cutting geometries were examined, it was understood that the highest average HAZ width (579 μm) was obtained in the triangle cutting geometry and the lowest average HAZ width (369 μm) was obtained in the circle cutting geometry. What is more, when the average HAZ widths obtained according to laser cutting geometries were compared, it was observed that the average HAZ widths of the specimens cut in triangle geometry were 31.61% and 56.93% larger than the specimens cut in square and circle cutting geometries, respectively. Furthermore, it was found that as the laser power increased, the HAZ widths were negatively affected (i.e., HAZ widths increased), but as the cutting speed increased, the HAZ widths were positively affected (i.e., HAZ widths decreased). From the ANOVA analyses, it was found that the cutting geometry (with a rate of 51.32%) was the most pivotal parameter influencing the HAZ width. When the regression analysis results (based on quadratic regression models) were checked, it was understood that R2 value had a very high rate (96.79%) as desired. Thus, from these results, it was understood that the model developed to predict the HAZ width values has a high success rate and reliability.
Dear Editor; I confirm that the work described has not been published previously, that it is not under consideration for publication elsewhere, that its publication is approved and that, if accepted, it will not be published elsewhere in the same form, in English or in any other language, without the written consent of the Publisher. I hope that the manuscript is suitable for the publication in an exclusive journal, Dicle Üniversitesi Mühendislik Fakültesi Mühendislik Dergisi. Yours sincerely, with best regards. *Asst. Prof. Dr. Mehmet Şükrü Adin1 *Corresponding Author 1*Batman University, Besiri OSB Vocational School, Batman, 72060, Turkey *Mehmet Şükrü Adin (M.Ş. Adin, ORCID ID: 0000-0002-2307-9669 ) E-mail: mehmetsukru.adin@batman.edu.tr Tel.: +90 488-217-3929 WhatsApp: +90 505 226 71 32
In present day, laser beam machining technology attracts great attention due to its cost-effectiveness, high machining quality, mass manufacturing velocity and broad areas of applicability throughout different manufacturing industries. However, intensive researches are required since many materials with different properties (chemical and mechanical) are used in the manufacturing industries; and there is need for high quality machining through newly developed laser technologies. In this context, in this experimental research, unlike most studies in the literature, an investigation was carried out on heat affected zone (HAZ) occurring in AISI 4140 steel machined by laser beam in different cutting geometries (triangle, square and circle cutting). In the present study, when the average HAZ widths calculated according to the laser cutting geometries were examined, it was understood that the highest average HAZ width (579 μm) was obtained in the triangle cutting geometry and the lowest average HAZ width (369 μm) was obtained in the circle cutting geometry. What is more, when the average HAZ widths obtained according to laser cutting geometries were compared, it was observed that the average HAZ widths of the specimens cut in triangle geometry were 31.61% and 56.93% larger than the specimens cut in square and circle cutting geometries, respectively. Furthermore, it was found that as the laser power increased, the HAZ widths were negatively affected (i.e., HAZ widths increased), but as the cutting speed increased, the HAZ widths were positively affected (i.e., HAZ widths decreased). From the ANOVA analyses, it was found that the cutting geometry (with a rate of 51.32%) was the most pivotal parameter influencing the HAZ width. When the regression analysis results (based on quadratic regression models) were checked, it was understood that R2 value had a very high rate (96.79%) as desired. Thus, from these results, it was understood that the model developed to predict the HAZ width values has a high success rate and reliability.
Dear Editor; I confirm that the work described has not been published previously, that it is not under consideration for publication elsewhere, that its publication is approved and that, if accepted, it will not be published elsewhere in the same form, in English or in any other language, without the written consent of the Publisher. I hope that the manuscript is suitable for the publication in an exclusive journal, Dicle Üniversitesi Mühendislik Fakültesi Mühendislik Dergisi. Yours sincerely, with best regards. *Asst. Prof. Dr. Mehmet Şükrü Adin1 *Corresponding Author 1*Batman University, Besiri OSB Vocational School, Batman, 72060, Turkey *Mehmet Şükrü Adin (M.Ş. Adin, ORCID ID: 0000-0002-2307-9669 ) E-mail: mehmetsukru.adin@batman.edu.tr Tel.: +90 488-217-3929 WhatsApp: +90 505 226 71 32
Primary Language | English |
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Subjects | Material Design and Behaviors |
Journal Section | Articles |
Authors | |
Early Pub Date | December 23, 2024 |
Publication Date | |
Submission Date | October 8, 2024 |
Acceptance Date | November 25, 2024 |
Published in Issue | Year 2024 Volume: 15 Issue: 4 |