Relevant bibliographies by topics / Laser manufacturing

Academic literature on the topic 'Laser manufacturing'

Author: Grafiati
Published: 10 December 2022
Last updated: 28 January 2023

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Journal articles on the topic "Laser manufacturing"

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SOZON, Tsopanos. "Laser Additive Manufacturing (LAM)." JOURNAL OF THE JAPAN WELDING SOCIETY 83, no. 4 (2014): 266–69. http://dx.doi.org/10.2207/jjws.83.266.

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Kuriyagawa, Tsunemoto, and Masayoshi Mizutani. "Special Issue on Laser-Based/Assisted Manufacturing." International Journal of Automation Technology 14, no. 4 (July 5, 2020): 533. http://dx.doi.org/10.20965/ijat.2020.p0533.

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The “process chain” concept for the integration of multiple manufacturing processes has been attracting attention in the field of manufacturing in recent years. In a number of specialized fields, laser-based processes in particular are actively being studied, as their high flexibility allows them to be used not only as individual manufacturing processes but also in combination to develop new ones. Most of the practical laser technologies involve heat, which can be used for thermal processing to change surface properties or for removal processing. In recent years, lasers have also been used as a heat source for additive manufacturing, as well as ultra-short-pulsed lasers being applied to non-thermal processes. This special issue features various studies and reports that present the latest advances as well as current challenges in laser-based/assisted manufacturing. It includes nine related papers that indicate the possibilities and future of new laser processing technologies. We deeply appreciate all the authors and reviewers for their efforts and contributions, and we also hope this special issue will encourage further research on laser-based/assisted manufacturing.
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Kaligar, Atiq Basha, Hemnath Anandan Kumar, Asghar Ali, Wael Abuzaid, Mehmet Egilmez, Maen Alkhader, Farid Abed, and Ali Sami Alnaser. "Femtosecond Laser-Based Additive Manufacturing: Current Status and Perspectives." Quantum Beam Science 6, no. 1 (January 18, 2022): 5. http://dx.doi.org/10.3390/qubs6010005.

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The ever-growing interest in additive manufacturing (AM) is evidenced by its extensive utilisation to manufacture a broad spectrum of products across a range of industries such as defence, medical, aerospace, automotive, and electronics. Today, most laser-based AM is carried out by employing continuous-wave (CW) and long-pulsed lasers. The CW and long-pulsed lasers have the downside in that the thermal energy imparted by the laser diffuses around the irradiated spot and often leads to the creation of heat-affected zones (HAZs). Heat-affected zones may degrade the material strength by producing micro-cracks, porous structures and residual stresses. To address these issues, currently, attempts are being made to employ ultrafast laser sources, such as femtosecond (fs) lasers, in AM processes. Femtosecond lasers with pulse durations in the order of 10−15 s limit the destructive laser–material interaction and, thus, minimise the probability of the HAZs. This review summarises the current advancements in the field of femtosecond laser-based AM of metals and alloys. It also reports on the comparison of CW laser, nanosecond (ns)/picosecond (ps) lasers with fs laser-based AM in the context of heat-affected zones, substrate damage, microstructural changes and thermomechanical properties. To shed light on the principal mechanisms ruling the manufacturing processes, numerical predictions are discussed and compared with the experimental results. To the best of the authors’ knowledge, this review is the first of its kind to encompass the current status, challenges and opportunities of employing fs lasers in additive manufacturing.
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Bogue, Robert. "Lasers in manufacturing: a review of technologies and applications." Assembly Automation 35, no. 2 (April 7, 2015): 161–65. http://dx.doi.org/10.1108/aa-07-2014-066.

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Purpose – This paper aims to provide details of the role that lasers play in manufacturing processes. Design/methodology/approach – Following an introduction, this paper first considers laser technologies used in welding, cutting and drilling. Techniques which add material or modify material’s properties, namely, pulsed laser deposition, laser cladding, heat treatment and laser peening are then discussed. A number of specific applications are cited and finally, brief conclusions are drawn. Findings – This paper shows that many laser-based processes are used to conduct a range of critical functions in the automotive, electronics, aerospace, power generation, medical and other industries. Originality/value – This paper illustrates the importance of lasers in a diversity of manufacturing processes.
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Deininger, Christoph. "Orbital Laser Manufacturing." Laser Technik Journal 12, no. 5 (November 2015): 37–40. http://dx.doi.org/10.1002/latj.201500034.

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Gillner, Arnold. "Laser Micro Manufacturing." Laser Technik Journal 6, no. 1 (January 2009): 16–19. http://dx.doi.org/10.1002/latj.200990001.

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Gasser, Andres, Gerhard Backes, Ingomar Kelbassa, Andreas Weisheit, and Konrad Wissenbach. "Laser Additive Manufacturing." Laser Technik Journal 7, no. 2 (February 2010): 58–63. http://dx.doi.org/10.1002/latj.201090029.

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Wu, Yuxiang, Yongxiong Chen, Lingchao Kong, Zhiyuan Jing, and Xiubing Liang. "A Review on Ultrafast-Laser Power Bed Fusion Technology." Crystals 12, no. 10 (October 18, 2022): 1480. http://dx.doi.org/10.3390/cryst12101480.

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Additive manufacturing of metals by employing continuous wave and short pulse lasers completely changes the way of modern industrial production. But the ultrafast laser has the superiority to short pulse laser and continuous wave laser in additive manufacturing. It has higher peak power, small thermal effect, high machining accuracy and low damage threshold. It can effectively perform additive manufacturing for special materials and improve the mechanical properties of parts. This article reviews the mechanism of the interaction between ultrafast laser and metal materials to rule the manufacturing processes. The current application of ultrafast laser on forming and manufacturing special materials, including refractory metals, transparent materials, composite materials and high thermal conductivity materials are also discussed. Among the review, the shortcomings and challenges of the current experimental methods are discussed as well. Finally, suggestions are provided for the industrial application of ultrashort pulse laser in the field of additive manufacturing in the future.
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Ting, Ben, and Vincent P. Manno. "Transient Thermomechanical Simulation of Laser Hammering in Optoelectronic Package Manufacturing." Journal of Electronic Packaging 127, no. 3 (November 1, 2004): 299–305. http://dx.doi.org/10.1115/1.1938206.

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Laser hammering (LH) is a process used in the manufacturing of butterfly optoelectronic packages to correct laser-to-fiber misalignment that occurs when the semiconductor lasers are welded in place. High-power, precisely positioned pulsed lasers are used in LH to induce deformation of the fiber support housing to, in turn, induce realignment. A thermomechanical modeling study of LH is reported in this paper, which focuses on the degree to which a steady-state model can predict the asymptotic state of a transient response subjected to a periodic laser excitation. A baseline, two-dimensional fiber mounting/ferrule geometry is employed in a finite element analysis simulation case study. Various laser wave forms are applied to focus spot location sizes of 50 and 200μm over a range of applied heat fluxes (10-1000W∕mm2). Effects of laser energy deposition location, as well as the use of multiple lasers, are also studied. The results show that the steady-state solution is in good agreement with the asymptotic transient response for horizontal fiber displacement and fiber temperature. The laser focus spot surface temperature predictions are also found to be in reasonable agreement. However, the vertical fiber displacement tends to be overpredicted by the steady-state solution, sometimes by as much as an order of magnitude. The causes, both physical and computational, of this disagreement are discussed.
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Parshin, V. A., V. V. Bliznyuk, and A. V. Dolgov. "Polarization stability of the single-mode laser diodes radiation applied in radiation scattering study complexes." Journal of Physics: Conference Series 2127, no. 1 (November 1, 2021): 012040. http://dx.doi.org/10.1088/1742-6596/2127/1/012040.

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Abstract Key features of semiconductor lasers and its serially manufacturing technology modernization have greatly expanded of its using at applied studies at last 20 years. But there is set of factors restricting such lasers application in a number of optical-electronic measuring complexes. Particularly in particle image velocimetry (PIV) and laser Doppler velocimetry (LDV) complexes commonly the gas and solid-state lasers is used due to more stability of spectral, energy and polarization characteristics of radiation then semiconductor lasers have. However gradual introduction of the serially manufacturing laser diodes into such systems picking up the pace that certainly characterizes the progress of reaching the required stability of its output laser radiation parameters. In laser measurement systems where medium investigation carried out by analyzing of scattering radiation in it the probe radiation polarization is often important. So the using in such systems the laser diodes as sources of radiation need to be followed by stability monitoring of its polarization characteristics which may be violated both by the outer factors and by natural degradation of inner laser diode structure. This work is devoted to the issues of monitoring the radiation polarization characteristics of the serially manufacturing single-mode laser diodes.
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Dissertations / Theses on the topic "Laser manufacturing"

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Mikler, Calvin. "Laser Additive Manufacturing of Magnetic Materials." Thesis, University of North Texas, 2017. https://digital.library.unt.edu/ark:/67531/metadc1011873/.

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A matrix of variably processed Fe-30at%Ni was deposited with variations in laser travel speeds as well and laser powers. A complete shift in phase stability occurred as a function of varying laser travel speed. At slow travel speeds, the microstructure was dominated by a columnar fcc phase. Intermediate travel speeds yielded a mixed microstructure comprised of both the columnar fcc and a martensite-like bcc phase. At the fastest travel speed, the microstructure was dominated by the bcc phase. This shift in phase stability subsequently affected the magnetic properties, specifically saturation magnetization. Ni-Fe-Mo and Ni-Fe-V permalloys were deposited from an elemental blend of powders as well. Both systems exhibited featureless microstructures dominated by an fcc phase. Magnetic measurements yielded saturation magnetizations on par with conventionally processed permalloys, however coercivities were significantly larger; this difference is attributed to microstructural defects that occur during the additive manufacturing process.
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Hong, Zhihan, and Rongguang Liang. "IR-laser assisted additive freeform optics manufacturing." NATURE PUBLISHING GROUP, 2017. http://hdl.handle.net/10150/625522.

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Computer-controlled additive manufacturing (AM) processes, also known as three-dimensional (3D) printing, create 3D objects by the successive adding of a material or materials. While there have been tremendous developments in AM, the 3D printing of optics is lagging due to the limits in materials and tight requirements for optical applicaitons. We propose a new precision additive freeform optics manufacturing (AFOM) method using an pulsed infrared (IR) laser. Compared to ultraviolet (UV) curable materials, thermally curable optical silicones have a number of advantages, such as strong UV stability, non-yellowing, and high transmission, making it particularly suitable for optical applications. Pulsed IR laser radiation offers a distinct advantage in processing optical silicones, as the high peak intensity achieved in the focal region allows for curing the material quickly, while the brief duration of the lasermaterial interaction creates a negligible heat-affected zone.
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Foster, Moira. "Defect Detection in Selective Laser Melting." DigitalCommons@CalPoly, 2018. https://digitalcommons.calpoly.edu/theses/1874.

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Additively manufactured parts produced using selective laser melting (SLM) are prone to defects created during the build process due to part shrinkage while cooling. Currently defects are found only after the part is removed from the printer. To determine whether cracks can be detected before a print is completed, this project developed print parameters to print a test coupon with inherent defects – warpage and cracking. Data recorded during the build was then characterized to determine when the defects occurred. The test coupon was printed using two sets of print parameters developed to control the severity of warpage and cracking. The builds were monitored using an accelerometer recording at 12500 samples per second, an iphone recording audio at 48000 samples a second, and a camera taking a photo every build layer. Data was analyzed using image comparison, signal amplitude, Fourier Transform, and Wavelet Decomposition. The developed print parameters reduced warpage in the part by better distributing heat throughout the build envelope. Reducing warpage enabled the lower portion of the part to be printed intact, preserving it to experience cracking later in the build. From physical evidence on the part as well as time stamps from the machine script, several high energy impulse events in the accelerometer data were determined to be when cracking occurred in the build. This project’s preliminary investigation of accelerometers to detect defects in selective laser melting will be used in future work to create machine learning algorithms that would control the machine in real time and address defects as they arise.
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Pereira, M. F. V. T., M. Williams, and R. Bruwer. "Rapid die manufacturing using direct laser metal deposition." Journal for New Generation Sciences, Vol 7, Issue 3: Central University of Technology, Free State, Bloemfontein, 2009. http://hdl.handle.net/11462/542.

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Published Article
Global issues such as energy and climate changes have impacted on both the automotive and aerospace industries, forcing them to adopt measures to produce products that consume fewer combustibles and emit less carbon dioxide. Making vehicles lighter is one of the logical ways of reducing fuel consumption. The need for light components, able to fulfil technical and quality specifications, led to market growth for tooling that is able to mass produce parts using manufacturing processes such as high pressure die casting. Competitive pressures to reduce the lead time required for tooling-up has also increased dramatically. For this reason research into various methods, techniques and approaches to tool manufacture is being undertaken globally. This paper highlights the work undertaken at the CSIR on the issue of rapid die manufacturing through the application and evaluation of a rapid prototyping technique and coating technologies applied to die components of a high pressure casting die for the production of aluminium components. Criteria for determining suitability were developed against which the technique was evaluated that included time, cost and life-expectancy. Results of accelerated testing procedures to evaluate the die material produced by the rapid prototyping technique and surface coatings and treatments of die materials for their resistance to washout, erosion, heat checking and corrosion in a high pressure die casting environment, are presented. The outcomes of this research will be used for further development and application of specific techniques, design principles and criteria for this approach.
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Lee, Yousub. "Simulation of Laser Additive Manufacturing and its Applications." The Ohio State University, 2015. http://rave.ohiolink.edu/etdc/view?acc_num=osu1440360229.

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Shannon, Geoff. "Laser welding of sheet steel." Thesis, University of Liverpool, 1993. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.240883.

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Murphy, M. L. "Rapid prototyping by laser surface cladding." Thesis, University of Liverpool, 1995. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.284268.

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In recent years rapid prototyping technology has been implemented in many spheres of industry, particularly the field of product development. Existing process provide the capability to rapidly produce a tangible solid part, directly from three dimensional CAD data, from a range of nonmetallic materials. In many situations the desired end product of a development cycle is a metallic object, whether a component or a tool. The development of a system capable of the direct manufacture of fully dense, metal parts is therefore seen as an important landmark in the evolution of rapid prototyping technology. A unique experimental project has been carried out to investigate the potential of laser surface cladding by pneumatic powder delivery to form the basis for such a process. A layered manufacturing part building strategy is proposed, in which laser cladding is used to deposit the near net shape of each layer. Conventional machining techniques are then used to trim each layer to the exact dimensions specified by the CAD data. A multi-kilowatt carbon dioxide laser was integrated with a four axis machine tool to create an opto-mechanical workstation on which to perform the process. A detailed study of the effects of cladding process parameters on the geometry of the deposited metal was carried out and quantitative relationships derived. These relationships are used to select process parameters appropriate to the geometry of the deposition required. A numerical method to fully describe the deposited clad geometry was developed in order that efficient cutter paths could be generated for the back machining cycle. These relationships are also used to determine the minimum size of deposited bead from which the required layer section may be machined, in order to optimise process efficiency. The application of the technique to the generation of a variety of simple geometries was investigated and the potential problems identified. A preliminary investigation into the process accuracy is made, relating specifically to the predictability of the geometry of multiple layer depositions and the distortion of parts as subsequent layers are deposited. The limits of geometrical complexity possible with the current apparatus, and the unsatisfactory build times involved, suggest that the most attractive application of this technique is as part of a hybrid process, adding a novel additive dimension to existing automated fabrication techniques.
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Iravani, Ebrahim. "Laser and eddy current measuring techniques for agile manufacturing." Doctoral thesis, KTH, Production Engineering, 2002. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-3312.

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Poonjolai, Erasenthiran. "Laser cutting, machining and welding for layered manufacturing applications." Thesis, University of Liverpool, 1999. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.399289.

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Bourchas, Konstantinos. "Manufacturing Effects on Iron Losses in Electrical Machines." Thesis, KTH, Elektrisk energiomvandling, 2015. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-172373.

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In this master thesis, the magnetic properties of SiFe laminations after cutting and welding are studied. The permeability and the iron loss density are investigated since they are critical characteristics for the performance of electrical machines. The magnetic measurements are conducted on an Epstein frame for sinusoidal variations of the magnetic ux density at frequencies of 50, 100 and 200 Hz, according to IEC 404-2. Mechanical cutting with guillotine and cutting by means of ber and CO2 laser are performed. The inuence of the ber laser settings is also investigated. Especially the assisting gas pressure and the power, speed and frequency of the laser beam are considered. In order to increase the cutting e ect, the specimens include Epstein strips with 1, 2 and 3 additional cutting edges along their length. It is found that mechanical cutting degrades the magnetic properties of the material less than laser cutting. For 1.8% Si laminations, mechanical cutting causes up to 35% higher iron loss density and 63% lower permeability, compared to standard Epstein strips (30 mm wide). The corresponding degradation for laser cut laminations is 65% iron loss density increase and 65% permeability drop. Material of lower thickness but with the same Si-content shows lower magnetic deterioration. Additionally, laser cutting with high-power/high-speed characteristics leads to the best magnetic characteristics among 15 laser settings. High speed settings have positive impact on productivity, since the cutting time decreases. The inuence of welding is investigated by means of Epstein measurements. The test specimens include strips with 1, 3, 5 and 10 welding points. Experiments show an iron loss increase up to 50% with a corresponding 62% reduction in the permeability. A model that incorporates the cutting e ect is developed and implemented in a FEMbased motor design software. Simulations are made for a reference induction motor. The results indicate a 30% increase in the iron losses compared to a model that does not consider the cutting e ect. In case of laser cut core laminations, this increase reaches 50%. The degradation prole considers also the deteriorated magnetizing properties. This leads to increased nominal current up to 1.7% for mechanically cut laminations and 3.4% for laser cut la
I detta examensarbete studeras hur de magnetiska egenskaperna hos SiFe-plat paverkas av skarning och svetsning. Permeabilitet och jarnforlustdensitet undersoks eftersom de ar kritiska variabler for elektriska maskiners prestanda. De magnetiska matningarna genomfordes pa en Epstein ram med en odesfrekvens pa 50, 100 och 200 Hz, enligt IEC 404-2. E ekterna av mekanisk skarning med giljotin samt skarning med ber- och CO2-laser studerades. Inverkan av olika berlaserinstallningar undersoktes ocksa genom att variera gastrycket, skarhastigheten samt frekvensen och e ekten av laserstralen. For att oka skare ekten inkluderades Epsteinremsor med ytterligare 1, 2 och 3 langsgaende skarsnitt. Det visas att mekanisk skarning har en mindre paverkan pa de magnetiska egenskaperna hos materialet an vad laserskarning har. Matningar pa plat med 1.8% Si visar att da prov med tre extra langsgaende giljotinklipp anvands kan permeabiliteten reduceras med upp till 63% och jarnforlusterna kan oka med upp till 35%. Motsvarande resultat for laserskurna platar visar en permeabilitetsreduktion pa upp till 65% och en jarnforlustokning pa upp till 65%. Ur studien av de tva studerade skarprocesserna framkommer aven att tunnare plat paverkas mindre negativt an tjockare plat. Ett antal olika installningar har provats for att utreda hur olika parametrar paverkar e ekterna av laserskarning. Studien indikerar att skarning med hog e ekt och hog hastighet ger den minsta paverkan pa materialets magnetiska egenskaper. Vilket aven har en positiv inverkan pa produktiviteten vid laserskarning. Epsteinprover har aven utforts for att undersoka vilka e ekter som introduceras da SiFe-plat svetsas. Provstyckena bestod av remsor med en, tre, fem och 10 svetspunkter. Experimenten visar en jarnforlustokning med upp till 50% samt en permeabilitetsreduktion upp till 62% da platarna svetsats samman tva och tva. En modell for att studera e ekterna av de forandrade materialegenskaperna vid skarning pa en induktionsmotor utvecklas och implementeras i en FEM-baserad mjukvara. Resultaten tyder pa en jarnforlustokning med 30% da skare ekten orsakad av giljotin beaktas. Vid simulering av laserskuren plat kan denna okning vara sa stor som 50%. Det framkommer aven att laserskarningen kan reducera e ektfaktorn sa mycket som 2.6%.
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Books on the topic "Laser manufacturing"

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Davim, J. Paulo. Laser in manufacturing. London: ISTE Ltd., and John Wiley & Sons, 2012.

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Crafer, R. C., and P. J. Oakley, eds. Laser Processing in Manufacturing. Dordrecht: Springer Netherlands, 1993. http://dx.doi.org/10.1007/978-94-011-1570-4.

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C, Crafer R., and Oakley P. J, eds. Laser processing in manufacturing. London: Chapman & Hall, 1993.

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Lugomer, Stjepan. Laser technology: Laser driven processes. Englewood Cliffs, N.J: Prentice Hall, 1990.

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1932-, Yu Heji, ed. Ji guang zhi zao gong yi li xue: Laser manufacturing technology. Beijing: Guo fang gong ye chu ban she, 2012.

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Bian, Linkan, Nima Shamsaei, and John M. Usher, eds. Laser-Based Additive Manufacturing of Metal Parts. Boca Raton: CRC Press, Taylor & Francis, 2018.: CRC Press, 2017. http://dx.doi.org/10.1201/9781315151441.

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Hu, Anming, ed. Laser Micro-Nano-Manufacturing and 3D Microprinting. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-59313-1.

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Gu, Dongdong. Laser Additive Manufacturing of High-Performance Materials. Berlin, Heidelberg: Springer Berlin Heidelberg, 2015. http://dx.doi.org/10.1007/978-3-662-46089-4.

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International Congress on Applications of Lasers and Electro-optics (1991 San Jose, Calif.). ICALEO '91: Laser materials processing. Orlando, Fla: LIA--Laser Institute of America, 1992.

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International Congress on Applications of Lasers and Electro-optics (1996 Detroit, Mich.). Proceedings of the Lasers and Electro-optics for Automotive Manufacturing Conference: ICALEO'96. Orlando, FL: Laser Institute of America, 1996.

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Book chapters on the topic "Laser manufacturing"

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Wu, Benxin, and Tuğrul Özel. "Micro-Laser Processing." In Micro-Manufacturing, 159–95. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2011. http://dx.doi.org/10.1002/9781118010570.ch6.

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Teixidor, Dani, Inés Ferrer, Luis Criales, and Tuğrul Özel. "Laser Machining." In Modern Manufacturing Processes, 435–57. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2019. http://dx.doi.org/10.1002/9781119120384.ch18.

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Amara, El-Hachemi, Karim Kheloufi, Toufik Tamsaout, Farida Hamadi, Samia Aggoune, Kada Bougherara, and Kamel Bourai. "Laser Additive Manufacturing." In ICREEC 2019, 423–29. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-5444-5_53.

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Duggirala, Aparna, Bappa Acherjee, and Souren Mitra. "Laser Welding of Materials." In Futuristic Manufacturing, 143–62. London: CRC Press, 2023. http://dx.doi.org/10.1201/9781003270027-8.

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Delgado, Jordi, Lidia Serenó, Karla Monroy, and Joaquim Ciurana. "Selective Laser Sintering." In Modern Manufacturing Processes, 481–99. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2019. http://dx.doi.org/10.1002/9781119120384.ch20.

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Lewis, Gary K. "Rapid Manufacturing." In Handbook of Laser Technology and Applications, 71–79. 2nd ed. 2nd edition. | Boca Raton: CRC Press, 2021– |: CRC Press, 2021. http://dx.doi.org/10.1201/9781315310855-6.

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Kumar, Sanjay. "Laser Powder Bed Fusion." In Additive Manufacturing Processes, 41–63. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-45089-2_3.

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Ukar, Eneko, Ivan Tabernero, Silvia Martínez, Aitzol Lamikiz, and Asier Fernández. "Laser-assisted Machining Operations." In Modern Manufacturing Processes, 459–80. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2019. http://dx.doi.org/10.1002/9781119120384.ch19.

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Bernhard, Robert, Philipp Neef, Henning Wiche, Volker Wesling, Christian Hoff, Jörg Hermsdorf, and Stefan Kaierle. "Laser Cladding – Additive Manufacturing." In Laser Cladding of Metals, 1–8. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-53195-9_1.

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Nakano, Takayoshi. "Selective Laser Melting." In Multi-dimensional Additive Manufacturing, 3–26. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-7910-3_1.

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Conference papers on the topic "Laser manufacturing"

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La Rocca, Aldo V., Luciano Borsati, and Maichi Cantello. "Latest developments in laser manufacturing." In Europto High Power Lasers and Laser Applications V, edited by Eckhard Beyer, Maichi Cantello, Aldo V. La Rocca, Lucien D. Laude, Flemming O. Olsen, and Gerd Sepold. SPIE, 1994. http://dx.doi.org/10.1117/12.184781.

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Seyfarth, Brian, Lisa Schade, Gabor Matthäus, Tobias Ullsperger, Nils Heidler, Enrico Hilpert, and Stefan Nolte. "Laser powder bed fusion of glass: a comparative study between CO2 lasers and ultrashort laser pulses." In Laser 3D Manufacturing VII, edited by Henry Helvajian, Bo Gu, and Hongqiang Chen. SPIE, 2020. http://dx.doi.org/10.1117/12.2545863.

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Li, Lijun. "Three-dimensional laser micromachining." In Microelectronic Manufacturing, edited by Fusen E. Chen and Shyam P. Murarka. SPIE, 1994. http://dx.doi.org/10.1117/12.186058.

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Delrot, Paul, Damien Loterie, Jorge Andres Madrid Wolff, and Christophe Moser. "Intelligent volumetric additive manufacturing." In Laser 3D Manufacturing VIII, edited by Henry Helvajian, Bo Gu, and Hongqiang Chen. SPIE, 2021. http://dx.doi.org/10.1117/12.2576886.

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Johnson, Trevor A. "Flexible Laser Manufacturing Systems." In 1986 Quebec Symposium, edited by Walter W. Duley and Robert W. Weeks. SPIE, 1986. http://dx.doi.org/10.1117/12.938883.

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Bertrand, Ph, and I. Smurov. "Laser assisted direct manufacturing." In International Conference on Lasers, Applications, and Technologies '07, edited by Vladislav Y. Panchenko, Oleg A. Louchev, and Sergei Malyshev. SPIE, 2007. http://dx.doi.org/10.1117/12.751902.

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La Rocca, Aldo V. "Second generation laser manufacturing systems." In Fifth International Conference on Industrial Laser and Laser Applications '95, edited by Vladislav Y. Panchenko and Vladimir S. Golubev. SPIE, 1996. http://dx.doi.org/10.1117/12.234190.

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Fu, Eliana, Roland Spiegelhalder, Sabrina Vogt, and Marco Goebel. "The best kept secret in laser additive manufacturing: green lasers, a unique innovation." In Laser 3D Manufacturing IX, edited by Henry Helvajian, Bo Gu, and Hongqiang Chen. SPIE, 2022. http://dx.doi.org/10.1117/12.2614548.

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Yuan, Kaixin, Feng Geng, Qinghua Zhang, and Yaguo Li. "Properties of femtosecond laser modified atomic layer deposition SiO2 films and their resistance to nanosecond ultraviolet lasers." In Advanced Laser Processing and Manufacturing VI, edited by Yuji Sano, Minghui Hong, Rongshi Xiao, and Jianhua Yao. SPIE, 2022. http://dx.doi.org/10.1117/12.2646242.

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Ogita, Yoh-Ichiro, Hiroshi Shinohara, Tsuyoshi Sawanobori, and Masaki Kurokawa. "Silicon wafer subsurface characterization with blue-laser/microwave and UV-laser/millimeter-wave photoconductivity techniques." In Microelectronic Manufacturing, edited by Sergio A. Ajuria and Tim Z. Hossain. SPIE, 1998. http://dx.doi.org/10.1117/12.324421.

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Reports on the topic "Laser manufacturing"

1

Gillespie, L. K. Femtosecond Laser Manufacturing Experiments. Office of Scientific and Technical Information (OSTI), January 2000. http://dx.doi.org/10.2172/750300.

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Campbell, J. H., T. Suratwala, S. krenitsky, and K. Takeuchi. Manufacturing laser glass by continuous melting. Office of Scientific and Technical Information (OSTI), July 2000. http://dx.doi.org/10.2172/15002236.

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Smith, Peter F., and Russell R. Mitchell. Materials Development and Evaluation of Selective Laser Sintering Manufacturing Applications. Office of Scientific and Technical Information (OSTI), January 1997. http://dx.doi.org/10.2172/770483.

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Moser, Daniel. Multi-fidelity thermal modeling of laser powder bed additive manufacturing. Office of Scientific and Technical Information (OSTI), September 2021. http://dx.doi.org/10.2172/1820523.

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Hibbard, R., and M. Bono. A Manufacturing Process for Precision Gold Support Rings for Laser Targets. Office of Scientific and Technical Information (OSTI), March 2004. http://dx.doi.org/10.2172/15009804.

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Phifer, Carol Celeste, Erik David Spoerke, Terry J. Garino, Steven John Lockwood, James A. Voigt, Pin Yang, Julie T. Gibson, and Diana Lynn Moore. Development of a manufacturing capability for production of ceramic laser materials. Office of Scientific and Technical Information (OSTI), October 2007. http://dx.doi.org/10.2172/926379.

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Lienert, Thomas J., and Stuart Andrew Maloy. Laser Additive Manufacturing of F/M Steels for Radiation Tolerant Nuclear Components. Office of Scientific and Technical Information (OSTI), November 2017. http://dx.doi.org/10.2172/1407859.

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Weaver, Jordan S., Alec Schlenoff, David C. Deisenroth, and Shawn P. Moylan. Inert Gas Flow Speed Measurements in Laser Powder Bed Fusion Additive Manufacturing. National Institute of Standards and Technology, October 2021. http://dx.doi.org/10.6028/nist.ams.100-43.

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MUSTALESKI, T., and M. RICHEY. DEVELOPMENT OF ADVANCED PHOTOLYTIC IODINE LASER (PIL) CUTTING AND JOINING TECHNOLOGIES FOR MANUFACTURING. Office of Scientific and Technical Information (OSTI), September 1998. http://dx.doi.org/10.2172/3367.

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Sabau, Adrian S., Yuan Lang, Narendran Raghavan, Srdjan Simunovic, John A. Turner, and Vipul K. Gupta. Fluid Dynamics Effects on Microstructure Prediction in Single Laser Tracks for Additive Manufacturing. Office of Scientific and Technical Information (OSTI), October 2018. http://dx.doi.org/10.2172/1505324.

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