Your search keyword '"laser beam machining"' showing total 603 results

1. A Systematic Study on the Processing Strategy in Femtosecond Laser Scribing via a Two-Temperature Model.

Author

Wang, Rujia, Wang, Yufeng, Yang, Yong, Zhang, Shuowen, Liu, Yunfeng, Yao, Jianhua, and Zhang, Wenwu

Subjects

*ULTRA-short pulsed lasers, *THERMAL equilibrium, *LASER machining, *FEMTOSECOND lasers

Abstract

Balancing quality and productivity, especially deciding on the optimal matching strategy for multiple process parameters, is challenging in ultrashort laser processing. In this paper, an economical and new processing strategy was studied based on the laser scribing case. To reveal the temperature evolution under the combination of multiple process parameters in the laser scribing process, a two-temperature model involving a moving laser source was developed. The results indicated that the peak thermal equilibrium temperature between the electron and lattice increased with the increase in the laser fluence, and the temperature evolution at the initial position, influenced by subsequent pulses, was strongly associated with the overlap ratio. The thermal ablation effect was strongly enhanced with the increase in laser fluence. The groove morphology was controllable by selecting the overlap ratio at the same laser fluence. The removal volume per joule (i.e., energy utilization efficiency) and the removal volume per second (i.e., ablation efficiency) were introduced to analyze the ablation characteristics influenced by multiple process parameters. The law derived from statistical analysis is as follows; at the same laser fluence with the same overlap ratio, the energy utilization efficiency is insensitive to changes in the repetition rate, and the ablation efficiency increases as the repetition rate increases. As a result, a decision-making strategy for balancing quality and productivity was created. [ABSTRACT FROM AUTHOR]

Published

2023

2. Laser Beam Machining of Titanium Alloy—A Review.

Author

Pramanik, Alokesh and Basak, Animesh Kumar

Subjects

LASER machining, TITANIUM alloys, MANUFACTURING processes, SURFACE finishing, LASER beams, THERMAL conductivity

Abstract

This study investigates the laser beam machining mechanism, surface formation mechanisms, heat-affected zone, taper formation, and the dimensional deviation of the titanium alloy, based on the information available in literature. The heat induced by the laser beam melts and vaporises titanium alloy, which is removed by a high pressure-assisted gas. The machined titanium alloy surface is expected to have craters and resolidified materials which were contributed by the low thermal conductivity of the titanium alloy. Taper and circularity error can be minimised by optimising the laser parameter, but it cannot be avoided in the laser beam machining of titanium alloy. Laser beam machining induces a non-diffusion phase transformation, which slightly changes the surface mechanical properties of the titanium alloys. Laser beam machining is gaining popularity as a way to improve the surface finish quality and properties of titanium components manufactured by additive manufacturing processes. To enhance the machining efficacy of titanium alloys, several hybrid machining processes were proposed. [ABSTRACT FROM AUTHOR]

Published

2023

3. Impact of Green Ceramic Hybrid Machining (GCHM) on Reliability and Repeatability of the Properties of Sintered Yttrium-Tetragonal Zirconia Polycrystal Parts.

Author

Ducobu, François, Demarbaix, Anthonin, Rivière-Lorphèvre, Edouard, Spitaels, Laurent, Petit, Fabrice, Preux, Nicolas, Duterte, Charles, Mulliez, Marylou, and Lauwers, Bert

Subjects

LASER machining, CERAMIC materials, CERAMICS, MACHINING, STATISTICAL reliability, ZIRCONIUM oxide

Abstract

The innovative Green Ceramic Hybrid Machining (GCHM) process sequentially combines milling with a cutting tool (GCM, Green Ceramic Machining) and laser beam machining (GCLBM) of a ceramic material (black Y-TZP in this study) at the green stage mainly to increase productivity, avoid taper angle limitations of laser beam machining, and obtain micro-features. The study focuses on the reliability and the repeatability of the properties of sintered parts obtained by three manufacturing processes (GCM, GCLBM, GCHM) to assess the performance of hybridisation. It turns out that GCHM is a compromise of both milling and laser beam processes; it increases the repeatability of the surface quality and it slightly reduces (less than 7%) the flexural strength by comparison to milling for a similar reliability. The study also highlights that the surface quality of GCLBM processed parts relies on of the surface generated by the previous operation. Milling that surface at the previous step is therefore recommended, corresponding to the sequence adopted by GCHM. [ABSTRACT FROM AUTHOR]

Published

2023

4. Performance Evaluation of Input Power of Diode Laser on Machined Leather Specimen in Laser Beam Cutting Process.

Author

Khalaf, Tamer, Thangaraj, Muthuramalingam, Moiduddin, Khaja, Swaminathan, Vasanth, Mian, Syed Hammad, Ahmed, Faraz, and Aboudaif, Mohamed Kamaleldin

Subjects

*LASER beam cutting, *SEMICONDUCTOR lasers, *LASER machining, *LEATHER, *POWER density, *CARBONIZATION

Abstract

Numerous industries, including footwear, handicrafts, and the automobile industry, utilize leather materials. The main goal of this study was to investigate the effect of input power of the diode laser in laser cutting on vegetable chrome tanned buffalo leather to enhance the cutting process. In the present investigation, carbonization, kerf width, and material removal rate (MRR) were taken as performance measures. The diode-based laser beam machining was designed and fabricated with 2.5 W, 5.5 W, and 20 W diode laser to cut vegetable chrome tanned leather. The high-intensity 20 W diode laser produced lower carbonization, lower kerf width, and higher material removal rate compared with the 2.5 W and 5.5 W diodes. This improved performance was due to the adjustable features associated with this diode laser actuation in the form of circular shape with adjustable diameter. A high power with a lower spot size under pulsed mode can produce higher power density. Since a higher power density can establish less interaction time, it produces lower carbonization. Due to the ability of the 20 W diode laser driver to control the beam shape and size, it could produce a lower kerf width and higher MRR. The optimal parameters for cutting chrome vegetable tanned cow leather were a standoff distance of 18 mm, feed rate of 200 mm/min, and duty cycle of 70%. [ABSTRACT FROM AUTHOR]

Published

2023

5. USE OF NON-TRADITIONAL MACHINING IN THE TEXTILE INDUSTRY

Author

N L Nikhil, Prasad Prasad, Praveen Kumar, Raveen Kumar P, and T S Nanjundeswaraswamy

Subjects

nontraditional machining, textile industry, laser beam machining, Engineering (General). Civil engineering (General), TA1-2040

Abstract

The process of unconventional machining is widely used to produce detailed, complex and accurate forms in materials such as titanium, stainless steel, high power temperature resistant alloys. It is used to remove materials using devices that are harder than the content itself. In the modern manufacturing system, to enhance the productivity of textile industries extensively using nontraditional machining system. Laser beam machining is one of them. The present paper is an attempt to review the usage of nontraditional machining especially laser beam machining.

Published

2022

6. A Systematic Study on the Processing Strategy in Femtosecond Laser Scribing via a Two-Temperature Model

Author

Rujia Wang, Yufeng Wang, Yong Yang, Shuowen Zhang, Yunfeng Liu, Jianhua Yao, and Wenwu Zhang

Subjects

laser beam machining, heat accumulation effect, ablation characteristics, process optimization, processing strategy, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Balancing quality and productivity, especially deciding on the optimal matching strategy for multiple process parameters, is challenging in ultrashort laser processing. In this paper, an economical and new processing strategy was studied based on the laser scribing case. To reveal the temperature evolution under the combination of multiple process parameters in the laser scribing process, a two-temperature model involving a moving laser source was developed. The results indicated that the peak thermal equilibrium temperature between the electron and lattice increased with the increase in the laser fluence, and the temperature evolution at the initial position, influenced by subsequent pulses, was strongly associated with the overlap ratio. The thermal ablation effect was strongly enhanced with the increase in laser fluence. The groove morphology was controllable by selecting the overlap ratio at the same laser fluence. The removal volume per joule (i.e., energy utilization efficiency) and the removal volume per second (i.e., ablation efficiency) were introduced to analyze the ablation characteristics influenced by multiple process parameters. The law derived from statistical analysis is as follows; at the same laser fluence with the same overlap ratio, the energy utilization efficiency is insensitive to changes in the repetition rate, and the ablation efficiency increases as the repetition rate increases. As a result, a decision-making strategy for balancing quality and productivity was created.

Published

2023

7. Laser Beam Machining of Tungsten Alloy: Experimental and Numerical Analysis.

Author

Begic-Hajdarevic, Derzija and Bijelonja, Izet

Subjects

LASER machining, TUNGSTEN alloys, LASER beam cutting, FINITE volume method, NUMERICAL analysis, TITANIUM alloys, LASER drilling, TUNGSTEN

Abstract

Laser beam machining of various materials has found wide applications in the industry due to its advantages of high-speed machining, no tool wear and no vibration, precision and accuracy, low cost of machining, etc. Investigations into the laser beam machining of uncommon alloy are still limited and more research is needed in this field. In this paper, an analysis of the laser beam machining of tungsten alloy was performed, for cutting and drilling machining processes. First, an experimental analysis of microhardness and microstructure on the laser-cut samples was performed, and then the numerical simulation of the laser beam drilling process and its experimental validation was carried out. The experiments were carried out on a tungsten alloy plate of two different thicknesses, 0.5 and 1 mm. No significant changes in the microhardness, nor in the microstructure characteristics in the heat-affected zone (HAZ), were observed for the cutting conditions considered. A two-dimensional axisymmetric mathematical model for the simulation of the laser beam drilling process is solved by a finite volume method. The model was validated by comparing numerical and experimental results in terms of the size of HAZ and the size and shape of the drilled hole. Experimental and numerical results showed that HAZ is larger in the 0.5-mm-thick plate than in the 1-mm-thick plate under the same drilling conditions. Good agreement was observed between the experimental and numerical results. The developed model improves the understanding of the physical phenomena of laser beam machining and allows the optimization of laser and process parameters. [ABSTRACT FROM AUTHOR]

Published

2022

8. Lasers that learn: The interface of laser machining and machine learning

Author

Benjamin Mills and James A. Grant‐Jacob

Subjects

laser beam machining, manufacturing systems, deep learning (artificial intelligence), Applied optics. Photonics, TA1501-1820

Abstract

Abstract Laser machining is a highly flexible non‐contact fabrication method used extensively across academia and industry. Whilst simulations based on fundamental understanding offer some insight into the processes, both the highly non‐linear interactions between laser light and matter and the variety of materials involved mean that theoretical modelling is not particularly applicable to practical experimentation. However, recent breakthroughs in machine learning have resulted in neural networks that are capable of accurate and rapid modelling of laser machining at a scale, speed, and precision well beyond those of existing theoretical approaches with applications including 3‐D surface visualisation and real‐time error correction. A perspective at the intersection of laser machining and machine learning is presented, followed by a discussion of future milestones and challenges for this field.

Published

2021

9. Laser Beam Machining of Titanium Alloy—A Review

Author

Alokesh Pramanik and Animesh Kumar Basak

Subjects

laser beam machining, material removal rate, titanium alloy, surface integrity, hybrid machining, Mining engineering. Metallurgy, TN1-997

Abstract

This study investigates the laser beam machining mechanism, surface formation mechanisms, heat-affected zone, taper formation, and the dimensional deviation of the titanium alloy, based on the information available in literature. The heat induced by the laser beam melts and vaporises titanium alloy, which is removed by a high pressure-assisted gas. The machined titanium alloy surface is expected to have craters and resolidified materials which were contributed by the low thermal conductivity of the titanium alloy. Taper and circularity error can be minimised by optimising the laser parameter, but it cannot be avoided in the laser beam machining of titanium alloy. Laser beam machining induces a non-diffusion phase transformation, which slightly changes the surface mechanical properties of the titanium alloys. Laser beam machining is gaining popularity as a way to improve the surface finish quality and properties of titanium components manufactured by additive manufacturing processes. To enhance the machining efficacy of titanium alloys, several hybrid machining processes were proposed.

Published

2023

10. Impact of Green Ceramic Hybrid Machining (GCHM) on Reliability and Repeatability of the Properties of Sintered Yttrium-Tetragonal Zirconia Polycrystal Parts

Author

François Ducobu, Anthonin Demarbaix, Edouard Rivière-Lorphèvre, Laurent Spitaels, Fabrice Petit, Nicolas Preux, Charles Duterte, Marylou Mulliez, and Bert Lauwers

Subjects

hybrid machining, laser beam machining, milling, ceramic, green ceramic, phase transformation, Production capacity. Manufacturing capacity, T58.7-58.8

Abstract

The innovative Green Ceramic Hybrid Machining (GCHM) process sequentially combines milling with a cutting tool (GCM, Green Ceramic Machining) and laser beam machining (GCLBM) of a ceramic material (black Y-TZP in this study) at the green stage mainly to increase productivity, avoid taper angle limitations of laser beam machining, and obtain micro-features. The study focuses on the reliability and the repeatability of the properties of sintered parts obtained by three manufacturing processes (GCM, GCLBM, GCHM) to assess the performance of hybridisation. It turns out that GCHM is a compromise of both milling and laser beam processes; it increases the repeatability of the surface quality and it slightly reduces (less than 7%) the flexural strength by comparison to milling for a similar reliability. The study also highlights that the surface quality of GCLBM processed parts relies on of the surface generated by the previous operation. Milling that surface at the previous step is therefore recommended, corresponding to the sequence adopted by GCHM.

Published

2023

11. Performance Evaluation of Input Power of Diode Laser on Machined Leather Specimen in Laser Beam Cutting Process

Author

Tamer Khalaf, Muthuramalingam Thangaraj, Khaja Moiduddin, Vasanth Swaminathan, Syed Hammad Mian, Faraz Ahmed, and Mohamed Kamaleldin Aboudaif

Subjects

leather material, laser beam machining, carbonization, material removal rate, kerf width, power diode, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Numerous industries, including footwear, handicrafts, and the automobile industry, utilize leather materials. The main goal of this study was to investigate the effect of input power of the diode laser in laser cutting on vegetable chrome tanned buffalo leather to enhance the cutting process. In the present investigation, carbonization, kerf width, and material removal rate (MRR) were taken as performance measures. The diode-based laser beam machining was designed and fabricated with 2.5 W, 5.5 W, and 20 W diode laser to cut vegetable chrome tanned leather. The high-intensity 20 W diode laser produced lower carbonization, lower kerf width, and higher material removal rate compared with the 2.5 W and 5.5 W diodes. This improved performance was due to the adjustable features associated with this diode laser actuation in the form of circular shape with adjustable diameter. A high power with a lower spot size under pulsed mode can produce higher power density. Since a higher power density can establish less interaction time, it produces lower carbonization. Due to the ability of the 20 W diode laser driver to control the beam shape and size, it could produce a lower kerf width and higher MRR. The optimal parameters for cutting chrome vegetable tanned cow leather were a standoff distance of 18 mm, feed rate of 200 mm/min, and duty cycle of 70%.

Published

2023

12. A Holistic Approach to Polymeric Material Selection for Laser Beam Machining using Methods of DEA and TOPSIS

Author

Roy Manish Kumar, Shivakoti Ishwer, Phipon Ruben, and Sharma Ashis

Subjects

laser beam machining, polymers, dea, ahp, topsis, mcdm, Electronic computers. Computer science, QA75.5-76.95

Abstract

Laser Beam machining (LBM) nowadays finds a wide acceptance for cutting various materials and cutting of polymer sheets is no exception. Greater reliability of process coupled with superior quality of finished product makes LBM widely used for cutting polymeric materials. Earlier researchers investigated the carbon dioxide laser cutting to a few thermoplastic polymers in thickness varying from 2mm to 10mm. Here, an approach is being made for grading the suitability of polymeric materials and to answer the problem of selection for LBM cutting as per their weightages obtained by using multi-decision making (MCDM) approach. An attempt has also been made to validate the result thus obtained with the experimental results obtained by previous researchers. The analysis encompasses the use of non-parametric linear-programming method of data envelopment analysis (DEA) for process efficiency assessment combined with technique for order preference by similarity to an ideal solution (TOPSIS) for selection of polymer sheets, which is based on the closeness values. The results of this uniquely blended analysis reflect that for 3mm thick polymer sheet is polypropelene (PP) to be highly preferable over polyethylene (PE) and polycarbonate (PC). While it turns out to be that polycarbonate (PC) to be highly preferable to other two polymers for 5mm thick polymer sheets. Hence the present research analysis fits very good for the polymer sheets of 3mm thickness while it deviates a little bit for the 5mm sheets.

Published

2020

13. PREDICTION OF HOLE ACCURACY BY USING LASER MACHINING

Author

Saad Kariem Shather and Zainb Abd Al Jabar

Subjects

response surface methodology, laser beam machining, hole drilling, anova program, Engineering (General). Civil engineering (General), TA1-2040

Abstract

The aim of this study is to predict the hole accuracy which drilled by laser beam machining using Response Surface Methodology (RSM) within Minitab 17. ANOVA program and compare the results with the experimental values which performed under different cutting conditions Cutting speed (2, 2.5, 3, 3.5, 4 m/min ) with power ( 600, 700, 800, 900, 1000 watt ) and gas pressure assist ( 2, 3 ,4, 5,6 bar ) so another parameters that using during operation remain constant. Experiments were conducted to predict the hole accuracy, the estimated result shows that there is good agreement between average experiments values and predicted values of hole accuracy (95.96%).

Published

2020

14. Laser Beam Machining of Tungsten Alloy: Experimental and Numerical Analysis

Author

Derzija Begic-Hajdarevic and Izet Bijelonja

Subjects

laser beam machining, tungsten alloy, microhardness, microstructure, finite volume method, Mining engineering. Metallurgy, TN1-997

Abstract

Laser beam machining of various materials has found wide applications in the industry due to its advantages of high-speed machining, no tool wear and no vibration, precision and accuracy, low cost of machining, etc. Investigations into the laser beam machining of uncommon alloy are still limited and more research is needed in this field. In this paper, an analysis of the laser beam machining of tungsten alloy was performed, for cutting and drilling machining processes. First, an experimental analysis of microhardness and microstructure on the laser-cut samples was performed, and then the numerical simulation of the laser beam drilling process and its experimental validation was carried out. The experiments were carried out on a tungsten alloy plate of two different thicknesses, 0.5 and 1 mm. No significant changes in the microhardness, nor in the microstructure characteristics in the heat-affected zone (HAZ), were observed for the cutting conditions considered. A two-dimensional axisymmetric mathematical model for the simulation of the laser beam drilling process is solved by a finite volume method. The model was validated by comparing numerical and experimental results in terms of the size of HAZ and the size and shape of the drilled hole. Experimental and numerical results showed that HAZ is larger in the 0.5-mm-thick plate than in the 1-mm-thick plate under the same drilling conditions. Good agreement was observed between the experimental and numerical results. The developed model improves the understanding of the physical phenomena of laser beam machining and allows the optimization of laser and process parameters.

Published

2022

15. Fabrication, Testing and Machining of Hybrid Basalt-Glass Fiber Reinforced Plastic composite.

Author

Jain, Akshay, Singh, Bhagat, Sharma, Kapil K., and Shrivastava, Yogesh

Subjects

BASALT, FIBROUS composites, MICROFABRICATION, LASER beams, COMPOSITE materials

Abstract

In modern industries, basalt and glass are the most commonly used fibers for the fabrication of various engineering components. Present work is focused on the fabrication of hybrid fiber reinforced plastic (FRP) composites, comprises of basalt and glass fibers. The aim of the work is to fabricate a composite justifying the current requirement of the era followed by the identification of the capabilities of fabricated composite by investigating its mechanical properties. Further, the machining of the fabricated composite has also been explored in order to limit the common problems in machining like fiber pull-out and delamination. From the results, it has been perceived that the fabricated composite can be machined flawlessly using laser beam machine subjected to the selection of input parameters. The proposed methodology seems helpful for researchers in fabricating the FRP composite and in identifying the range of input parameters suitable for machining. [ABSTRACT FROM AUTHOR]

Published

2021

16. Analytical solution for the heat conduction mechanism appropriate to the laser heating process

Author

Yilbas, B [King Fahd Univ. of Petroleum and Minerals, Dhahran (Saudi Arabia). Dept. of Mechanical Engineering]

Published

2020

17. An Alternative Form of Laser Beam Characterization

Author

MACCALLUM, DANNY

Published

2000

18. Microstructure Development in Nickel Base Superalloys during Weld Thermal Cycle

Author

David, S

Published

2000

19. LASER ENGINEERED NET SHAPING FOR REPAIR AND HYDROGEN COMPATIBILITY

Author

Adams, T

Published

2011

20. Measurement and calculation of recoil pressure produced during CO{sub 2} laser interaction with ice

Author

Kanouff, M

Published

1999

21. Materials processing research and development opportunities with new generation of FELs

Author

Kelley, Michael

Published

1999

22. A review on the intensification of metal matrix composites and its nonconventional machining

Author

Srivastava Ashish Kumar, Dixit Amit Rai, and Tiwari Sandeep

Subjects

abrasive water jet (awj) machining, laser beam machining, metal matrix composite (mmcs), titanium metal matrix composite (timmcs), wire-edm, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Metal matrix composites (MMCs) are the new-generation advanced materials that have excellent mechanical properties, such as high specific strength, strong hardness, and strong resistance to wear and corrosion. All these qualities make MMCs suitable material in the manufacture of automobiles and aircraft. The machining of these materials is still difficult due to the abrasive nature of the reinforced particles and hardness of MMCs. The conventional machining of MMCs results in high tool wear and slow removal of materials, thereby increasing the overall machining cost. The nonconventional machining of these materials, on the contrary, ensures much better performance. This paper reviews various research works on the development of MMCs and the subsequent hybrid composites and evaluates their performances. Further, it discusses the influence of the process parameters of conventional and nonconventional machining on the performance of MMCs. At the end, it identifies the research gaps and future scopes for further investigations in this field.

Published

2018

23. Multi-cycle phase transformation during laser hardening of AISI 4140.

Author

Lu, Y., Meyer, H., and Radel, T.

Abstract

Laser hardening is a process that modifies not only hardness, but also residual stresses near the surface. However, limited information is available on the effect of multi-cycle phase transformation on the hardness and residual stresses, which could be a possibility to achieve different material modifications. In this paper, the effects of multi-pass laser hardening on the material modifications of quenched and tempered as well as ferrite/pearlite AISI 4140 steel have been investigated. The multi-cycle phase transformation process has been carried out using a continuous wave laser with a rectangular beam shape using different schemes, without heat accumulation between each cycle. Results showed that material properties were modified with accumulation effects within the given pass up to 16 cycles. With increasing passes, it was found that the induced compressive residual stress at the surface decreased despite of the initial material state, while the hardness in the subsurface area and hardening depth increased differently, which depended on the initial heat treatment condition. These results indicated the possibility of tailoring the material hardness and surface residual stress by the given heat treatment condition, laser process and cycle number in the multi-pass laser hardening. [ABSTRACT FROM AUTHOR]

Published

2020

24. PREDICTION OF HOLE ACCURACY BY USING LASER MACHINING.

Author

Shather, Saad Kariem and Al Jabar, Zainb Abd

Subjects

LASER machining, FORECASTING, LASER drilling

Abstract

The aim of this study is to predict the hole accuracy which drilled by laser beam machining using Response Surface Methodology (RSM) within Minitab 17. ANOVA program and compare the results with the experimental values which performed under different cutting conditions Cutting speed (2, 2.5, 3, 3.5, 4 m/min ) with power ( 600, 700, 800, 900, 1000 watt ) and gas pressure assist ( 2, 3 ,4, 5,6 bar ) so another parameters that using during operation remain constant. Experiments were conducted to predict the hole accuracy, the estimated result shows that there is good agreement between average experiments values and predicted values of hole accuracy (95.96%). [ABSTRACT FROM AUTHOR]

Published

2020

25. Laser machining of special designed photopolymers-photochemical ablation mechanism

Author

Wokaun, A [Paul Scherrer Institute, Villigen, (Switzerland)]

Published

1997

26. Impact of Green Ceramic Hybrid Machining (GCHM) on Reliability and Repeatability of the Properties of Sintered Yttrium-Tetragonal Zirconia Polycrystal Parts

Author

Lauwers, François Ducobu, Anthonin Demarbaix, Edouard Rivière-Lorphèvre, Laurent Spitaels, Fabrice Petit, Nicolas Preux, Charles Duterte, Marylou Mulliez, and Bert

Subjects

hybrid machining, laser beam machining, milling, ceramic, green ceramic, phase transformation

Abstract

The innovative Green Ceramic Hybrid Machining (GCHM) process sequentially combines milling with a cutting tool (GCM, Green Ceramic Machining) and laser beam machining (GCLBM) of a ceramic material (black Y-TZP in this study) at the green stage mainly to increase productivity, avoid taper angle limitations of laser beam machining, and obtain micro-features. The study focuses on the reliability and the repeatability of the properties of sintered parts obtained by three manufacturing processes (GCM, GCLBM, GCHM) to assess the performance of hybridisation. It turns out that GCHM is a compromise of both milling and laser beam processes; it increases the repeatability of the surface quality and it slightly reduces (less than 7%) the flexural strength by comparison to milling for a similar reliability. The study also highlights that the surface quality of GCLBM processed parts relies on of the surface generated by the previous operation. Milling that surface at the previous step is therefore recommended, corresponding to the sequence adopted by GCHM.

Published

2023

27. Laser materials processing at Sandia National Laboratories

Author

Cieslak, M

Published

1994

28. Applications for reactor-pumped lasers

Author

McArthur, D [Sandia National Labs., Albuquerque, NM (United States). Nuclear Systems Research]

Published

1994

29. Computational modeling of physical processes during laser ablation

Author

Puretzky, A

Published

1994

30. The future of diode pumped solid state lasers and their applicability to the automotive industry

Author

Hackel, L [and others]

Published

1994

31. Advances in tunable powerful lasers: The advanced free-electron laser

Author

Sheffield, R

Published

1993

32. Beam-quality measurements for materials processing lasers and the proposed ISO standard

Author

Essien, M

Published

1993

33. High-power copper vapor lasers and their application to precision drilling and cutting

Author

Weber, P

Published

1993

34. Progress in Non-Traditional Processing for Fabricating Superhydrophobic Surfaces

Author

Dili Shen, Wuyi Ming, Xinggui Ren, Zhuobin Xie, and Xuewen Liu

Subjects

superhydrophobic surfaces, laser beam machining, electrical discharge machining, electrochemical machining, ion beam machining, non-traditional processing, Mechanical engineering and machinery, TJ1-1570

Abstract

When the water droplets are on some superhydrophobic surfaces, the surface only needs to be inclined at a very small angle to make the water droplets roll off. Hence, building a superhydrophobic surface on the material substrate, especially the metal substrate, can effectively alleviate the problems of its inability to resist corrosion and easy icing during use, and it can also give it special functions such as self-cleaning, lubrication, and drag reduction. Therefore, this study reviews and summarizes the development trends in the fabrication of superhydrophobic surface materials by non-traditional processing techniques. First, the principle of the superhydrophobic surfaces fabricated by laser beam machining (LBM) is introduced, and the machining performances of the LBM process, such as femtosecond laser, picosecond laser, and nanosecond laser, for fabricating the surfaces are compared and summarized. Second, the principle and the machining performances of the electrical discharge machining (EDM), for fabricating the superhydrophobic surfaces, are reviewed and compared, respectively. Third, the machining performances to fabricate the superhydrophobic surfaces by the electrochemical machining (ECM), including electrochemical oxidation process and electrochemical reduction process, are reviewed and grouped by materials fabricated. Lastly, other non-traditional machining processes for fabricating superhydrophobic surfaces, such as ultrasonic machining (USM), water jet machining (WJM), and plasma spraying machining (PSM), are compared and summarized. Moreover, the advantage and disadvantage of the above mentioned non-traditional machining processes are discussed. Thereafter, the prospect of non-traditional machining for fabricating the desired superhydrophobic surfaces is proposed.

Published

2021

35. Laser beam diagnostics for kilowatt power pulsed YAG laser

Author

Leong, Keng

Published

1992

36. Excimer laser surface processing for tribological applications in metals and ceramics

Author

Nastasi, M

Published

1991

37. Response to 'Comment on 'Evidence for phase explosion and generation of large particles during high power nanosecond laser ablation of silicon''[Appl. Phys. Lett. 76, 783 (2000)]

Author

Russo, R

Published

2001

38. A multivariate normal boundary intersection PCA-based approach to reduce dimensionality in optimization problems for LBM process.

Author

Belinato, Gabriela, de Almeida, Fabrício Alves, de Paiva, Anderson Paulo, de Freitas Gomes, José Henrique, Balestrassi, Pedro Paulo, and Rosa, Pedro Alexandre Rodrigues Carvalho

Subjects

LASER machining, MANUFACTURING processes, GEOGRAPHIC boundaries, EXPERIMENTAL design, INTERSECTION theory

Abstract

Laser beam machining (LBM) is a promising manufacturing process that exhibits several desirable quality characteristics. Given a large number of objective functions, the level of complexity increases in an optimization problem. Therefore, this study presents a multivariate application of the normal boundary intersection (NBI) method to reduce dimensionality in optimization problems of the LBM process. Such an approach is capable of exploring the entire solution space with only a small number of Pareto points, and generating equispaced frontiers based on the objective functions written in terms of principal component scores. Hence, a design of experiment with three input parameters and six quality characteristics was undertaken to appropriately model the process requirements applied to AISI 314S steel. The results indicate that the proposed methodology is capable of achieving optimal values for interest characteristics. In addition, this approach shows a reduction in computational effort of approximately 91.89% (from 259 to 21 subproblems) in obtaining the best solution for rough operation. [ABSTRACT FROM AUTHOR]

Published

2019

39. Laser Based Machining of Aluminum Metal Matrix Composites.

Author

Marimuthu, S., Dunleavey, J., and Smith, B.

Abstract

Aluminium metal matrix composites (Al MMC) are a relatively new type of material which combine lightweight metallic matrices (aluminium) with hard ceramic reinforcements (like alumina fibre or silicon carbide particles). Al MMCs have excellent potential in various applications from automotive to aerospace; however, their use is currently limited due to their low machinability. Conventional laser processes such as the laser drilling or cutting of monolithic materials (metals/alloys) are well-established processes. However, conventional laser processing of anisotropic materials like metal matrix composites is challenging due to the immense differences in the chemical and physical properties of the matrix and reinforcement. Over the last decade, nanosecond laser based water jet guided (WJG) machining has securely established itself as a novel laser based machining process, especially for the machining of non-monolithic materials like composites. The main investigation of this paper is centred on understanding the performance of WJG laser and conventional high power fibre laser machining of Al MMC. Laser machining of both fibre-based and particle-based Al MMC has been investigated (Al 2 O 3 Fibre–Al MMC; SiC Particle–Al MMC). The WJG laser machining results were compared with the results from conventional long pulse/continuous wave laser process. [ABSTRACT FROM AUTHOR]

Published

2019

40. Evaluation of surface integrity after high energy machining with EDM, laser beam machining and abrasive water jet machining of alloy 718.

Author

Holmberg, Jonas, Berglund, Johan, Wretland, Anders, and Beno, Tomas

Subjects

*ALLOYS, *THREE-dimensional printing, *LASER beams, *WATER jet cutting, *ABRASIVES

Abstract

Development of future aero engine components based on new design strategies utilising topological optimisation and additive manufacturing has in the past years become a reality. This allows for designs that involve geometries of "free form" surfaces and material combinations that could be difficult to machine using conventional milling. Hence, alternative manufacturing routes using non-conventional high energy methods are interesting to explore. In this investigation, the three high energy machining methods abrasive water jet machining (AWJM), electrical discharge machining (EDM) and laser beam machining (LBM) have been compared in terms of surface integrity to the reference, a ball nosed end milled surface. The results showed great influence on the surface integrity from the different machining methods. It was concluded that AWJM resulted in the highest quality regarding surface integrity properties with compressive residual stresses in the surface region and a low surface roughness with texture from the abrasive erosion. Further, it was shown that EDM resulted in shallow tensile residual stresses in the surface and an isotropic surface texture with higher surface roughness. However, even though both methods could be considered as possible alternatives to conventional milling they require post processing. The reason is that the surfaces need to be cleaned from either abrasive medium from AWJM or recast layer from EDM. It was further concluded that LBM should not be considered as an alternative in this case due to the deep detrimental impact from the machining process. [ABSTRACT FROM AUTHOR]

Published

2019

41. Superhydrophobic aluminum surfaces with nano-micro hierarchical composite structures: A novel and sustainable approach to corrosion protection.

Author

Tran, Ngoc Giang, Chun, Doo-Man, and Abd-Elrahim, A.G.

Subjects

*SUPERHYDROPHOBIC surfaces, *COMPOSITE structures, *CORROSION & anti-corrosives, *LASER machining, *SURFACE analysis, *HEAT treatment, *ALUMINUM composites

Abstract

The unique properties of aluminum (Al) and its alloys make Al one of the most versatile, economical, and widely-used materials in various industries. However, the corrosion and leaching of Al can cause significant issues for the lifetimes of mechanical structures and machine components as well as environment and health problems. In the present study, a simple, eco-friendly, and rapid fabrication of superhydrophobic Al surfaces was introduced. The superhydrophobic Al surfaces with hierarchical composite structures combining microstructures prepared by laser texturing, the new formation of pseudo-boehmite nanostructures prepared by boiling water treatment, and low surface energy prepared by silicone oil heat treatment showed excellent corrosion resistance. The mechanism for wettability change and anti-corrosion were analyzed. The influence of laser parameters and surface modification procedures on the wettability and corrosion resistance of Al surfaces was also analyzed systematically through a series of surface characterization techniques, potentiodynamic polarization tests, and electrochemical impedance spectroscopy tests. The corrosion protection efficiency of the fabricated superhydrophobic Al surface has reached up to 99.40 % as compared with an untreated flat surface. Furthermore, the fabricated superhydrophobic surfaces show good stability even after prolonged exposure to air, fresh water, seawater, and high temperature environments. The performance of the non-wetting surfaces is demonstrated through self-cleaning, water jetting, and water droplet bouncing phenomena. This research provides a novel and sustainable approach for superhydrophobic metal surfaces and improved corrosion resistance for potential practical applications. [Display omitted] • Superhydrophobic (SHP) Al surface was fabricated by a facile and eco-friendly process. • The mechanism of wettability change and corrosion resistance was analyzed. • Boehmite nanostructure and hydrophobic group result in superior corrosion resistance. • The anti-corrosion efficiency of nano-micro hierarchical structures SHP has reached up 99.4%. • Excellent stability, thermal durability, and performance of SHP surface were demonstrated. [ABSTRACT FROM AUTHOR]

Published

2023

42. Laser glazing of rails - WBB/IWS tests (CNRC-Ottawa).

Author

DiMelfi, R

Published

2005

43. Design and precision tracking control of a high-bandwidth fast steering mirror for laser beam machining

Author

Tadahiko Shinshi, Jianpeng Zhong, and Rina Nishida

Subjects

Control theory, Computer science, Laser beam machining, Charge control, General Engineering, Trajectory, Feed forward, Bandwidth (computing), Natural frequency, Tracking (particle physics), Compensation (engineering)

Abstract

In this article, we report on a high-bandwidth large-aperture fast steering mirror (FSM) actuated by piezoelectric actuators (PEAs) for laser beam machining and a control strategy to achieve high bandwidth and precision tracking control. To simultaneously achieve high bandwidth and a large aperture, we used a low-density and high-rigidity 50-mm round mirror to ensure sufficient stiffness and to minimize the moment of inertia. Also, the overall structure of the moving part in the FSM was simplified to further reduce the moment of inertia. Based on modal analysis, and taking into account the conflicting requirements for the natural frequency and the stroke, the thickness of the base plate used to provide the preload force to the PEAs and to transmit motion to the mirror was determined. Moreover, to achieve high bandwidth and precision tracking control, we propose an integrated control solution, in which an inner digital charge control (DCC) loop is used to eliminate hysteresis, an outer displacement loop with a design based on pole-zero cancellation and loop shaping is introduced to eliminate resonance, and feedforward compensation is applied to reduce the phase lag. The feasibility of an FSM with this control solution was validated by experiments. A bandwidth of 10 kHz with a resolution of less than 0.3 μrad can be achieved for the FSM. Moreover, precision tracking with a maximum radius error of less than 2.2 μrad below 2 kHz for a circular trajectory at a radius of 25 μrad can be realized.

Published

2022

44. Micromachining of Biolox Forte Ceramic Utilizing Combined Laser/Ultrasonic Processes

Author

Basem M. A. Abdo, Syed Hammad Mian, Abdualziz El-Tamimi, Hisham Alkhalefah, and Khaja Moiduddin

Subjects

biolox forte ceramic, laser beam machining, rotary ultrasonic machining, combined process, micromachining, microchannels, surface roughness, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Micromachining has gained considerable interest across a wide range of applications. It ensures the production of microfeatures such as microchannels, micropockets, etc. Typically, the manufacturing of microchannels in bioceramics is a demanding task. The ubiquitous technologies, laser beam machining (LBM) and rotary ultrasonic machining (RUM), have tremendous potential. However, again, these machining methods do have inherent problems. LBM has issues concerning thermal damage, high surface roughness, and vulnerable dimensional accuracy. Likewise, RUM is associated with high machining costs and low material-removal rates. To overcome their limits, a synthesis of LBM and RUM processes known as laser rotary ultrasonic machining (LRUM) has been conceived. The bioceramic known as biolox forte was utilized in this investigation. The approach encompasses the exploratory study of the effects of fundamental input process parameters of LBM and RUM on the surface quality, machining time, and dimensional accuracy of the manufactured microchannels. The performance of LRUM was analyzed and the mechanism of LRUM tool wear was also investigated. The results revealed that the surface roughness, depth error, and width error is decreased by 88%, 70%, and 80% respectively in the LRUM process. Moreover, the machining time of LRUM is reduced by 85%.

Published

2020

45. The Morphology and Mechanical Properties of ESD Coatings before and after Laser Beam Machining

Author

Norbert Radek, Jacek Pietraszek, Aneta Gądek-Moszczak, Łukasz J. Orman, and Agnieszka Szczotok

Subjects

ESD coating, laser beam machining, electrodes, morphology, mechanical properties, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Electro-spark deposition (ESD) and laser beam machining (LBM) are the technologies using the concentrated energy flux. This paper deals with the issue of the impact of laser modification on the morphology and mechanical properties of carbide/copper coatings produced by electro-spark treatment. The coatings were applied to C45 carbon steel samples using the EIL-8A device. The following three types of electrodes made using the powder metallurgy (PM) hot pressing technique, from copper and tungsten carbide powders of different percentage compositions, were used for the coatings: 25% WC and 75% Cu; 50% WC and 50% Cu; and 75% WC and 25% Cu. Laser modification of the surface layers was performed with an Nd:YAG laser. The research focused on the analysis of the morphology of coatings applied by electro-spark technology before and after laser processing. The analysis of the morphology of electro-spark coatings revealed that the coatings had microcracks and pores. The laser beam machining of ESD coatings led to the homogenization of chemical composition, fragmentation of the structure, and elimination of microcracks. In addition, measurements of porosity, microhardness, adhesion, and analysis of XRD phase composition of the electro-spark coatings were performed. Laser processing proved to have a positive effect on improving the adhesion of coatings and reducing their porosity. This paper also presents a simulation model of heat transfer processes for the case of laser radiation impact on a WC-Cu coating. The developed numerical model, describing the influence of laser treatment on the distribution of temperature fields in the heated material (at a given depth) is of significant importance in the development of treatment technologies. Laser-modified ESD coatings perform anti-wear and protective functions, which enable their potential application in means of transport such as rolling stock.

Published

2020

46. Laser Peening - A Processing Tool to Strengthen Metals or Alloys

Author

Hackel, L

Published

2003

47. Laser Peening--Strengthening Metals to Improve Fatigue Lifetime and Retard Stress-Induced Corrosion Cracking in Gears, Bolts and Cutter

Author

Chen, H-L

Published

2003

48. Photovoltaic manufacturing cost and throughput improvements for thin-film CIGS-based modules: Phase 1 technical report, July 1998--July 1999

Author

Wendt, R

Published

2000

49. LASER CLEANING OF CONTAMINATED PAINTED SURFACES

Author

Jensen, Robert

Published

1999

50. Development of an Innovative Laser-Assisted Coating Process for Extending Lifetime of Metal Casting Dies. Final Report

Author

Gonvindaraju, Madhav

Published

1999