• 제목/요약/키워드: Laser-assisted Turning

검색결과 9건 처리시간 0.024초

레이저 보조선삭 중 주철환봉 내부의 온도분포 예측에 관한 연구 (A study for prediction of temperature distribution in laser-assisted turning for rod-shaped cast iron)

  • 김관우;조해용;이제훈;서정;신동식
    • 한국레이저가공학회지
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    • 제13권2호
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    • pp.10-16
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    • 2010
  • Laser-assisted machining is dependent on absorbed energy density into workpiece. Generally, the absorptivity of laser beam is dependent on wave length of laser, materials, surface roughness, etc. Various shapes and energy densities for beam irradiation can be used to laser-assisted machining. In this thesis, efficient method of heat source modeling was developed and designed by using one fundamental experimental trials. And then, laser-assisted machining of rod-shaped cast iron was simulated by using commercial FEM code MARC. Simulations and experiments with various conditions were carried out to determine suitable condition of pre-heating for laser-assisted turning process. Temperature distribution of cutting zone could be predicted by simulation.

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사각형재의 레이저 예열 선삭에서 레이저 열원 투영법을 이용한 열해석 (Thermal Analysis for Laser Assisted Turning of Square Bar using Laser Heat Source Projection Method)

  • 김재현;최준영;이춘만
    • 한국정밀공학회지
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    • 제28권12호
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    • pp.1353-1358
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    • 2011
  • LAT(Laser Assisted Turning) is a method that applies a machining process after softening a workpiece in which a preheating process is locally applied to its machining section using laser heat source. LAT shows several advantages, such as high productivity, reduction of manufacturing cost, high quality. Analysis of temperature distribution after preheating for LAT is very difficult due to its very small heat input area and large energy and its movement. Also, the LAT for a square bar is more difficult because the shape of a laser heat source can be changed according to the rotation of the workpiece. In this study, thermal analysis for LAT of square bar was performed using laser heat source projection method. And, the analysis results were compared with the results of the prior study of numerical calculation method. It is thus shown that the proposed method is efficient for the thermal analysis of a shaped bar.

레이저보조가공에서 열원과 공구 사이의 거리선정을 위한 해석적 연구 (Analytical Study of the Determination of Distance between the Laser Heat Source and Tool for Laser-Assisted Machining)

  • 백종태;이춘만
    • 한국정밀공학회지
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    • 제32권8호
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    • pp.699-704
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    • 2015
  • Laser-assisted machining has shown its potential to significantly improve product quality and reduce manufacturing costs; additionally, laser-assisted turning (LAT) and laser-assisted milling (LAM) have been studied by numerous researchers. A research study on the determination of the distance between the laser heat source and the tool for laser-assisted machining, however, has not yet been attempted; we conducted such an analysis by using a finite-element method and heat-transfer equation. The results of this analysis can be used as a reference for the determination of the distance between the laser heat source and the tool for laser-assisted machining.

A Study on the Optimum Machining Conditions and Energy Efficiency of a Laser-Assisted Fillet Milling

  • Woo, Wan-Sik;Lee, Choon-Man
    • International Journal of Precision Engineering and Manufacturing-Green Technology
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    • 제5권5호
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    • pp.593-604
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    • 2018
  • Laser-assisted machining (LAM) is known to be an effective and economical technique for improving the machinability of difficult-to-machine materials. In the LAM method, material is preheated using a laser heat source and then the preheated area is removed by following cutting tool. For laser-assisted turning (LAT), the configuration of the system is not complicated because laser irradiates from a fixed position. In contrast, laser-assisted milling (LAMill) system is not only complicated but also difficult to control because laser heat source must always move ahead of the cutting tool along a three dimensional (3D) tool path. LAMill is still early stage and cannot yet be used to machine finished products with 3D shapes. In this study, a laser-assisted fillet milling process was developed for machining 3D shapes. There are no prior studies combining fillet milling and LAMill. Laser-assisted fillet milling strategy was proposed, and effective depth of cut (EDOC) was obtained using thermal analysis. Experiments were designed using response surface method and cutting force prediction equations were developed using statistical analysis and regression analysis. The optimum machining conditions were also proposed, and energy efficiency of the LAMill was analyzed by comparing the specific cutting energy of conventional machining (CM) and LAMill.

3차원 레이저 보조 밀링을 위한 레이저 예열 방법에 관한 연구 (Laser Preheating Method for Three-Dimensional Laser Assisted Milling)

  • 오원정;이춘만
    • 한국정밀공학회지
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    • 제32권12호
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    • pp.1031-1037
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    • 2015
  • Laser assisted machining (LAM) is an effective method with which to effectively process difficult-to-cut materials. Simple machining processes, such as turning and linear tool paths, have been studied by many researchers. But, there are few research efforts on LAM workpieces using threedimensional shapes because of difficulties controlling the laser heat on workpieces with inclined angles or curved surfaces. Two methods for machining three-dimensional workpieces are proposed in this paper. The first is that the heat source shape and laser focal length are maintained using an index table. Second, a rotary type laser module is controlled using an algorithm to move the laser heat source in all directions. This algorithm was developed to control the rotary type laser module and the machine tool simultaneously. These methods are verified by a CATIA simulation.

레이저 보조 모듈을 이용한 Si 소재의 절삭조건 및 보정가공에 관한 연구 (A Study on Cutting Conditions and Finishing Machining of Si Material Using Laser Assisted Module)

  • 박영덕
    • Design & Manufacturing
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    • 제17권2호
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    • pp.15-21
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    • 2023
  • In this study, a diamond turning machine and a laser-assisted machining module were utilized for the complex combined cutting of aspheric shapes and fine patterns on the surface of high-hardness brittle material, silicon. The analysis of material's form accuracy and corrective machining was conducted based on key factors such as laser output, rotational speed, feed rate, and cutting depth to achieve form accuracy below 1 ㎛ and surface roughness below 0.1 ㎛. The cutting condition and corrective machining methods were investigated to achieve the desired form accuracy and surface roughness. The rotational speed of the spindle and the linear feed rate of the diamond turning machine were varied in five stages for the cutting condition test. Surface roughness and form accuracy were measured using both a contact surface profilometer and a non-contact surface profilometer. The experimental results revealed a tendency of improved surface roughness with increased rotational speed of the workpiece, and the best surface roughness and form accuracy were observed at a feed rate of 5 mm/min. Furthermore, based on the cutting condition experiments, corrective machining was performed. The experimental results demonstrated an improvement in form accuracy from 0.94 ㎛ to 0.31 ㎛ and a significant reduction in the average value of the surface roughness curve from 0.234 ㎛ to 0.061 ㎛. This research serves as a foundation for future studies focusing on the machinability in relation to laser output parameters.

레이저보조가공을 위한 2-축 구동 매니퓰레이터 설계에 관한 기초 연구 (A Fundamental Study on the Design of Two-axis Drive Manipulator for Laser-assisted Machining)

  • 김동현;차나현;김태우;이춘만
    • 한국정밀공학회지
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    • 제29권8호
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    • pp.813-817
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    • 2012
  • Laser assisted machining (LAM) is machining method that performs a machining for workpieces using laser beam preheating. LAM is in the early stage of its applications and has only been used in limited fields including turning, planning and micro end-milling throughout the world. LAM system should be able to move to the laser radiation direction and to rotate on a tool path for machining of complex shapes. A laser module with two-axis manipulator is designed in this study. It has been performed static structural analysis and shape modification of the manipulator. As the results of shape modification it has been obtained better results than the initial model. These results will be able to use in development of the two-axis manipulator.