Relevant bibliographies by topics / Laser melting

Contents

  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers
  6. Reports

Academic literature on the topic 'Laser melting'

Author: Grafiati
Published: 4 June 2021
Last updated: 7 September 2024

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Journal articles on the topic "Laser melting"

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Bremen, Sebastian, Wilhelm Meiners, and Andrei Diatlov. "Selective Laser Melting." Laser Technik Journal 9, no. 2 (April 2012): 33–38. http://dx.doi.org/10.1002/latj.201290018.

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Hartmann-H'Lawatscheck, Tina. "Metal Laser Melting." Laser Technik Journal 12, no. 5 (November 2015): 41–43. http://dx.doi.org/10.1002/latj.201500027.

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Wiesner, Andreas. "Selective Laser Melting." Laser Technik Journal 5, no. 4 (June 2008): 54–55. http://dx.doi.org/10.1002/latj.200890048.

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Yasa, E., J. P. Kruth, and J. Deckers. "Manufacturing by combining Selective Laser Melting and Selective Laser Erosion/laser re-melting." CIRP Annals 60, no. 1 (2011): 263–66. http://dx.doi.org/10.1016/j.cirp.2011.03.063.

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C. Tseng, W., and J. N. Aoh. "Experimental Validation of a Laser Heat Source Model for Laser Melting and Laser Cladding Processes." Open Mechanical Engineering Journal 8, no. 1 (October 9, 2014): 370–81. http://dx.doi.org/10.2174/1874155x01408010370.

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Selective laser melting (SLM) and laser cladding are laser additive manufacturing methods that have been developed for application to the near-net-shape process and 3D printing. The temperature distributions and track profiles of SLM and clad layers require additional in-depth investigation to optimize manufacturing processes. This research involved developing a tailored laser heat source model that contains a comprehensive selection of laser beam characteristics and can be used in finite element analysis of the laser melting process. This paper presents a systematic experimental validation of the applicability of the proposed laser heat source model to single-track Nd:YAG and CO2 laser melting simulations. The evolution of the melt pool isotherms and the variation in track profiles caused by adjusting the laser power and scanning speed were numerically predicted and experimentally verified. Appropriate process parameters and the threshold power for continuous track layer formation were determined. The balling phenomenon on preplaced powder was observed at power levels below the threshold values. Nd:YAG laser melting resulted in a wide and shallow track profile, which was adequately predicted using the numerical simulation. CO2 laser melting resulted in a triangular track profile, which deviated slightly from the finite element prediction. The results indicated a high level of consistency between the experimental and the numerical results regarding track depth evolution, whereas the numerically predicted track width evolution deviated slightly from the experimentally determined track width evolution. This parametric laser melting study validated the applicability of the proposed laser heat source model in numerical analysis of laser melting processes such as SLM and laser cladding.
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Liu, Jin Hui, Rui Di Li, and Can Zhao. "Study on Fiber Laser Single Melting Track During Selective Laser Forming." Advanced Materials Research 97-101 (March 2010): 4020–23. http://dx.doi.org/10.4028/www.scientific.net/amr.97-101.4020.

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Melting tracks with and without powder materials were studied by varying the parameters in selective laser melting. Several characters of melting track such as melting width and gilled state stripes were analyzed combining the relationship between the powder materials and processing parameters. Connected with balling effects, thermal transmission and thermal physical properties of powder materials, the formation of above character were explained. The research result of this work would provide a basic foundation for the further investigation of the quality of end metal component manufactured by selective laser melting method.
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Aleksandrov, I. V., V. M. Strakhov, and Yu P. Udalov. "Laser porcelain-surface melting." Glass and Ceramics 46, no. 10 (October 1989): 410–12. http://dx.doi.org/10.1007/bf00678948.

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Verhoeven, J. C. J., J. K. M. Jansen, R. M. M. Mattheij, and W. R. Smith. "Modelling laser induced melting." Mathematical and Computer Modelling 37, no. 3-4 (March 2003): 419–37. http://dx.doi.org/10.1016/s0895-7177(03)00017-7.

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Xiang, Zhaowei, Ran Yan, Xiaoyong Wu, Liuqing Du, and Qin Yin. "Surface morphology evolution with laser surface re-melting in selective laser melting." Optik 206 (March 2020): 164316. http://dx.doi.org/10.1016/j.ijleo.2020.164316.

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Zhao, Changlong, Xiaoyu Jia, Qinxiang Zhao, Hongnan Ma, and Haifeng Zhang. "Laser Melting and Surface Texture Technology: Effect on Friction Properties." Journal of Nanoelectronics and Optoelectronics 19, no. 4 (April 1, 2024): 415–22. http://dx.doi.org/10.1166/jno.2024.3581.

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This paper discusses the role of laser surface texturing and laser melting technology in enhancing surface lubrication and wear resistance under starved lubrication conditions. The aim is to enhance the wear resistance of laser surface texturing and to explore the role of surface texturing in enhancing lubrication. This paper observes the microstructure of the melting zone, transition zone and matrix of the base material Cr12MoV after laser melting and condensing, detects and analyses the metallographic composition, and tests the micro-hardness. The effects of laser surface texturing technology and laser melting technology on the coefficient of friction under different friction and wear environments were comparatively investigated. The laser melting zone consists of martensite with fine grain size and a large amount of residual austenite. After laser melting, the hardness reaches 1.4 times the hardness of the matrix. The laser surface texture increases lubrication significantly at low rpm. The fully fusion-coagulated treatment is wear-resistant in a variety of different frictional wear environments.
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Dissertations / Theses on the topic "Laser melting"

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Prashanth, Konda Gokuldoss. "Selective laser melting of Al-12Si." Doctoral thesis, Saechsische Landesbibliothek- Staats- und Universitaetsbibliothek Dresden, 2014. http://nbn-resolving.de/urn:nbn:de:bsz:14-qucosa-144245.

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Selective laser melting (SLM) is a powder-based additive manufacturing technique consisting of the exact reproduction of a three dimensional computer model (generally a computer-aided design CAD file or a computer tomography CT scan) through an additive layer-by-layer strategy. Because of the high degree of freedom offered by the additive manufacturing, parts having almost any possible geometry can be produced by SLM. More specifically, with this process it is possible to build parts with extremely complex shapes and geometries that would otherwise be difficult or impossible to produce using conventional subtractive manufacturing processes. Another major advantage of SLM compared to conventional techniques is the fast cooling rate during the process. This permits the production of bulk materials with very fine microstructures and improved mechanical properties or even bulk metallic glasses. In addition, this technology gives the opportunity to produce ready-to-use parts with minimized need for post-processing (only surface polishing might be required). Recently, significant research activity has been focused on SLM processing of different metallic materials, including steels, Ti-, Ni- and Al-based alloys. However, most of the research is devoted to the parameters optimization or to feasibility studies on the production of complex structures with no detailed investigations of the structure-property correlation. Accordingly, this thesis focuses on the production and structure-property correlation of Al-12Si samples produced by SLM from gas atomized powders. The microstructure of the as-prepared SLM samples consists of supersaturated primary Al with an extremely fine cellular structure along with the residual free Si situated at the cellular boundaries. This microstructure leads to a remarkable mechanical behavior: the yield and tensile strengths of the SLM samples are respectively four and two times higher than their cast counterparts. However, the ductility is significantly reduced compared with the cast samples. The effect of annealing at different temperatures on the microstructure and resulting mechanical properties of the SLM parts has been systematically studied by analyzing the size, morphology and distribution of the phases. In addition, the mechanical properties of the SLM samples have been modeled using micro- structural features, such as the crystallite and matrix ligament sizes. The results demonstrate that the mechanical behavior of the Al-12Si SLM samples can be tuned within a wide range of strength and ductility through the use of the proper annealing treatment. The Al-Si alloys are generally used as pistons or cylinder liners in automotive applications. This requires good wear resistance and sufficient strength at the operating temperature, which ranges between 373 – 473 K. Accordingly, the tensile properties of the SLM samples were also tested at these temperatures. Changing the hatch style during SLM processing vary the texture in the material. Hence, samples with different hatch styles were produced and the effect of texture on their mechanical behavior was evaluated. The results show that the hatch style strongly influences both the mechanical properties and the texture of the samples; however no direct correlation was observed between texture and mechanical properties. The wear properties of the Al-12Si material was evaluated using pin-on-disc and fretting wear experiments. These experiments show that the as-prepared SLM samples exhibit better wear resistance than their cast counterparts and the SLM heat-treated samples. Finally, the corrosion investigations reveal that the SLM samples have similar corrosion behavior as the cast specimens under acidic conditions. A major drawback for the wide application of SLM as an industrial processing route is the limited size of the products. This is a direct consequence of the limited dimensions of the available building chambers, which allow for the production of samples with volumes of about 0.02 m3. A possible way to overcome this problem would be the use of the welding processes to join the small SLM objects to form parts with no dimensional limitations. In order to verify this possibility, friction welding was employed to join Al-12Si SLM parts. The results indicate that friction welding not only successfully permits the join materials manufactured by SLM, but also helps to significantly improve their ductility. This work clearly demonstrates that SLM can be successfully used for the production of Al-12Si parts with an overall superior performance of the mechanical and physical properties with respect to the conventional cast samples. Moreover, the mechanical properties of the SLM samples can be widely tuned in-situ by employing suitable hatch styles or ex-situ by the proper heat treatment. This might help the development of SLM for the production of innovative high-performance Al-based materials and structures with controlled properties for automotive and aerospace applications.
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Lamb, M. "Laser surface melting of stainless steel." Thesis, Imperial College London, 1985. http://hdl.handle.net/10044/1/37753.

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Otsu, David Takeo. "Preliminary Investigations into Selective Laser Melting." DigitalCommons@CalPoly, 2017. https://digitalcommons.calpoly.edu/theses/1758.

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Selective laser melting is a promising metallic additive manufacturing process with many potential applications in a variety of industries. Through a gracious donation made by Lawrence Livermore National Laboratory, California Polytechnic State University received and installed an SLM 125 HL selective laser melting machine in February 2017. As part of the initial setup effort, a preliminary machine verification study was conducted to evaluate the general print quality of the machine with default parameter settings. Coincidentally, the as-printed microstructure of SLM components was evaluated through nil strength fracture surface examination, an alternative to conventional polish-and-etch metallography. A diverse set of components were printed on the SLM 125 HL to determine the procedural best practices and inherent constraints. Additionally, the mode and mechanism of failure for a defective Lawrence Livermore National Laboratory component fabricated at their facility was investigated. From these studies, extensive documentation in the form of standard operating procedures, guidelines, templates, and summary reports was generated with the intent of facilitating future selective laser melting research at Cal Poly and strengthening the learning of students interfacing with the novel technology.
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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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Buchbinder, Damien [Verfasser]. "Selective Laser Melting von Aluminiumgusslegierungen / Damien Buchbinder." Aachen : Shaker, 2013. http://d-nb.info/104938167X/34.

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Khan, Mushtaq. "Selective Laser Melting (SLM) of gold (Au)." Thesis, Loughborough University, 2010. https://dspace.lboro.ac.uk/2134/6163.

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Selective Laser Melting (SLM) is a laser based Solid Freeform Fabrication (SFF process which uses laser energy to melt a thin layer of metal powder. This process is repeated to produce a 3-dimensional metallic part. SLM is capable of producing intricate parts which are otherwise difficult to produce with conventional manufacturing techniques. As compared to traditional manufacturing processes, SLM can also produce parts with higher density. Before a material is processed using SLM, suitable processing parameters are first identified. Over the years, different materials have been processed using the SLM process. However, very little work has been done on SLM of bio-compatible precious metals such as gold and its alloys. Gold and its alloys have been used for manufacturing of dental crowns for centuries. The SLM process could be used to produce intricate metallic substructures for porcelain fused to metal dental restorations. This research work was focused on understanding the processing parameters for SLM of 24 carat gold powder. The gold powder was analyzed for Particle Size Distribution (PSD), apparent density and tap density before identifying suitable processing parameters for SLM. The gold powder particles were found to be spherical in nature but smaller particles stuck to each other and formed larger powder agglomerates. From the apparentdensity experiments, the gold powder was found to be cohesive and non-flowing in nature which hindered powder flowability during the powder deposition process with the existing system. This issue was resolved by designing a new powder deposition system which could allow the gold powder to flow evenly over the substrate. The tap density of the gold powder was found by Constant Weight Tap Density (CWTD) and Constant Volume Tap Density (CVTD) techniques. The difference in results from these two techniques was negligible. Diffuse Reflectance Infrared Fourier Transform Spectroscopy (DRIFTS) of gold powder showed it to be more than twice as reflective as other commonly processed metal powders such as stainless steel and H13 tool steel. This analysis proved useful in understanding the laser processing of gold powder. Due to the high cost and small quantity of material available for this work, a very small build platform was designed to optimise material utilisation and reduce wastage. Single scans were performed on a single layer of gold powder to identify the good melting region. Five different regions i.e. balling, good melting, unstable melt, weak sintering and very little sintering were observed in the processing window. The balling phenomenon was observed at low and high scan speeds, which was due to the melt pool instability at these parameter settings. The size of droplets (balling) also increased with decreasing scan speed and increasing laser power which was due to an increase in the break up time of the molten metal. In the good melting region, the gold powder was found to be completely melted and continuous beads were successfully produced. The unstable melt region showed the melt pool spreading unevenly in different directions whereas in the weak sintering and very little sintering regions the gold powder did not melt completely. Single layers were produced on a layer of gold powder, which showed the parameters in the good melting regions to be suitable for multiple layer parts manufacturing. Gold cubes were produced using the suitable processing parameters identified from single scan and single layer experiments and then analyzed for their internal porosity. The porosity in the gold cubes was found to be at a minimum for parameters obtained in the good melting region. The internal porosity was found to be mostly inter-layer porosity; this indicated less heat transferred to the region between the two layers which could be associated with the high reflectivity of gold. The inter-layer porosity in gold cubes was further reduced by reducing the layer thickness. This could be due to the thinner layers requiring less energy to melt and be fused to the previous layers. The hatch distance had a negligible effect on the inter-layer porosity of gold cubes. The reduction in hatch distance increased the energy delivered but it was still not enough to completely melt the gold powder and fuse it to the previous layer. A pre-scan technique was also tested to be used for pre-heating the powder bed. However, due to the rapid drop in temperature, this technique was not found suitable to be used as a powder bed pre-heating technique. The gold cubes were checked for their mechanical properties i.e. hardness and modulus. The hardness of gold cubes was found to be higher than expected for 24 carat gold. The modulus was found to be less than 24 carat gold. This variation in the mechanical properties of gold cubes could be due to the rapid heating and cooling of material during the laser processing or presence of internal porosity in these gold cubes. After single scans and single layers manufacturing, gold dental parts (premolar and molar) were also manufactured using the optimum processing parameters. These gold dental parts were also analyzed for their internal porosity, which was found to be less than that observed in gold cubes. This difference in porosity could be due to the difference in structure of gold cubes and premolar part, where the latter was a thin wall structure.
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Tsopanos, Sozon. "Micro Heat Exchangers by Selective Laser Melting." Thesis, University of Liverpool, 2008. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.507633.

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Selective Laser Melting (SLM), a layer-based Solid Freeform Fabrication (SFF) process, was used to fabricate micro cross-flow heat exchangers from 316L stainless steel, bronze (Cu 90%, Sn 10%) and Inconel 718 powder. Their mechanical and thermal properties were determined using solid blocks of SLM material prior to the fabrication of the micro cross flow heat exchangers. Initially the process parameters for the fabrication of high density (>97%) parts for the different materials were defined. The mechanical and thermal properties of SLM parts were then measured. The tensile test results exhibited yield strength values superior to the parent metals, but also showed low tensile strength and ductility as a result of the inherent residual porosity (2-4%). Results obtained from the thermal conductivity of the stainless steel material system were in good agreement with the bulk material values. The heat transfer performance of the heat exchangers with either micro channels or lattice structures as heat exchange surfaces was investigated experimentally and the results were evaluated in terms of geometry and materials. The performance of the micro heat exchangers was found to be dependent not only on the choice of material but also on the heat exchanger media geometry.
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Folkes, Janet Ann. "Laser surface melting and alloying of titanium alloys." Thesis, Imperial College London, 1987. http://hdl.handle.net/10044/1/38315.

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Chen, Zhen-da. "Laser surface melting and alloying of cast irons." Thesis, Imperial College London, 1987. http://hdl.handle.net/10044/1/38260.

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Fateri, Miranda [Verfasser]. "Selective Laser Melting of Glass Powders / Miranda Fateri." München : Verlag Dr. Hut, 2018. http://d-nb.info/1155056159/34.

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Books on the topic "Laser melting"

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Wischeropp, Tim Marten. Advancement of Selective Laser Melting by Laser Beam Shaping. Berlin, Heidelberg: Springer Berlin Heidelberg, 2021. http://dx.doi.org/10.1007/978-3-662-64585-7.

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Lau, Marcus. Laser Fragmentation and Melting of Particles. Wiesbaden: Springer Fachmedien Wiesbaden, 2016. http://dx.doi.org/10.1007/978-3-658-14171-4.

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Wang, Jin Jimmy. Melting in Superheated Silicon Films Under Pulsed-Laser Irradiation. [New York, N.Y.?]: [publisher not identified], 2016.

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Wong, Vernon. 2-D Melting in Excimer-Laser Irradiated Polycrystalline Silicon Films. [New York, N.Y.?]: [publisher not identified], 2021.

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Choi, Min Hwan. Pulsed-Laser-Induced Melting and Solidification of Thin Metallic Films. [New York, N.Y.?]: [publisher not identified], 2012.

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Sing, Swee Leong. Selective Laser Melting of Novel Titanium-Tantalum Alloy as Orthopaedic Biomaterial. Singapore: Springer Singapore, 2019. http://dx.doi.org/10.1007/978-981-13-2724-7.

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Colloque international sur le soudage et la fusion par faisceaux d'électrons et laser (5e 1993 La Baule, Loire-Atlantique, France). 5ème Colloque international sur le soudage et la fusion par faisceaux d'électrons et laser =: 5th International Conference on Welding and Melting by Electron and Laser Beams, La Baule, 14-18 juin 1993. [Saclay]: Commissariat à l'énergie atomique, 1993.

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Glazer, Nathan. Beyond the melting pot: Thirty years later. Toronto: Robert F. Harney Professorship and Program in Ethnic, Immigration and Pluralism Studies, University of Toronto, 1991.

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Selective Laser Melting. MDPI, 2020. http://dx.doi.org/10.3390/books978-3-03928-579-2.

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Wischeropp, Tim Marten. Advancement of Selective Laser Melting by Laser Beam Shaping. Springer Berlin / Heidelberg, 2022.

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Book chapters on the topic "Laser melting"

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Bäuerle, Dieter. "Surface Melting." In Laser Processing and Chemistry, 177–98. Berlin, Heidelberg: Springer Berlin Heidelberg, 2011. http://dx.doi.org/10.1007/978-3-642-17613-5_10.

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Bäuerle, Dieter. "Surface Melting." In Laser Processing and Chemistry, 152–69. Berlin, Heidelberg: Springer Berlin Heidelberg, 1996. http://dx.doi.org/10.1007/978-3-662-03253-4_10.

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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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Fritsch, G. "Melting and Surfaces." In Interfaces Under Laser Irradiation, 41–53. Dordrecht: Springer Netherlands, 1987. http://dx.doi.org/10.1007/978-94-017-1915-5_3.

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Metev, Simeon M., and Vadim P. Veiko. "Laser Melting and Microwelding." In Laser-Assisted Microtechnology, 132–56. Berlin, Heidelberg: Springer Berlin Heidelberg, 1998. http://dx.doi.org/10.1007/978-3-642-87271-6_5.

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Metev, Simeon M., and Vadim P. Veiko. "Laser Melting and Microwelding." In Laser-Assisted Microtechnology, 132–56. Berlin, Heidelberg: Springer Berlin Heidelberg, 1998. http://dx.doi.org/10.1007/978-3-642-97327-7_5.

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Yilbas, Bekir Sami, and Shahzada Zaman Shuja. "Laser Melting of Two Layer Materials." In Materials Forming, Machining and Tribology, 59–80. Berlin, Heidelberg: Springer Berlin Heidelberg, 2013. http://dx.doi.org/10.1007/978-3-642-36629-1_4.

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von Allmen, Martin, and Andreas Blatter. "Melting and Solidification." In Laser-Beam Interactions with Materials, 68–114. Berlin, Heidelberg: Springer Berlin Heidelberg, 1995. http://dx.doi.org/10.1007/978-3-642-57813-7_4.

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von Allmen, Martin. "Melting and Solidification." In Laser-Beam Interactions with Materials, 83–145. Berlin, Heidelberg: Springer Berlin Heidelberg, 1987. http://dx.doi.org/10.1007/978-3-642-97007-8_4.

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Williamson, S., and G. Mourou. "Genesis of Melting." In Laser Surface Treatment of Metals, 125–31. Dordrecht: Springer Netherlands, 1986. http://dx.doi.org/10.1007/978-94-009-4468-8_13.

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Conference papers on the topic "Laser melting"

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Streek, André, and Horst Exner. "Laser micro melting." In ICALEO® 2015: 34th International Congress on Laser Materials Processing, Laser Microprocessing and Nanomanufacturing. Laser Institute of America, 2015. http://dx.doi.org/10.2351/1.5063237.

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Thombansen, U., and Peter Abels. "Observation of melting conditions in selective laser melting of metals (SLM)." In SPIE LASE, edited by Friedhelm Dorsch and Stefan Kaierle. SPIE, 2016. http://dx.doi.org/10.1117/12.2213952.

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M, Jegatheesan, Aurabinda Swain, Soumen Kole, Prasenjit Rath, and Anirban Bhattacharya. "Melting and solidification of metal matrix nanocomposites during laser melting." In Proceedings of the 26thNational and 4th International ISHMT-ASTFE Heat and Mass Transfer Conference December 17-20, 2021, IIT Madras, Chennai-600036, Tamil Nadu, India. Connecticut: Begellhouse, 2022. http://dx.doi.org/10.1615/ihmtc-2021.760.

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West, Connor, and Xuan Wang. "Modeling of selective laser sintering/selective laser melting." In SPIE LASE, edited by Bo Gu, Henry Helvajian, Alberto Piqué, Corey M. Dunsky, and Jian Liu. SPIE, 2017. http://dx.doi.org/10.1117/12.2256539.

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Brüning, Heiko. "Robusteness of the laser melting process." In ICALEO® 2013: 32nd International Congress on Laser Materials Processing, Laser Microprocessing and Nanomanufacturing. Laser Institute of America, 2013. http://dx.doi.org/10.2351/1.5062978.

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Koss, Sabrina, André Edelmann, and Ralf Hellmann. "Efficient Selective Laser Melting of AlSi10Mg0.5." In MultiScience - XXXI. microCAD International Multidisciplinary Scientific Conference. University of Miskolc, 2017. http://dx.doi.org/10.26649/musci.2017.020.

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Chen, Z. D., D. R. F. West, and W. M. Steen. "Laser melting of alloy cast irons." In ICALEO® ‘86: The Changing Frontiers of Laser Materials Processing. Laser Institute of America, 1986. http://dx.doi.org/10.2351/1.5057865.

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Izumitani, Tetsuro. "Continuous melting of phosphate laser glass." In Solid State Lasers for Application to Inertial Confinement Fusion (ICF), edited by Michel Andre and Howard T. Powell. SPIE, 1995. http://dx.doi.org/10.1117/12.228289.

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Zier, Tobias, Eeuwe S. Zijlstra, and Martin E. Garcia. "Laser-induced nonthermal melting in Si." In High Intensity Lasers and High Field Phenomena. Washington, D.C.: OSA, 2012. http://dx.doi.org/10.1364/hilas.2012.jt2a.39.

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Romanov, Eugeny L., Vadim G. Tokarev, Yuliya V. Novitskaya, Ivan A. Bezrukov, and Vladimir N. Filimonenko. "Software for Selective Laser Melting Syste." In 2018 Global Smart Industry Conference (GloSIC). IEEE, 2018. http://dx.doi.org/10.1109/glosic.2018.8570086.

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Reports on the topic "Laser melting"

1

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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Gibson, Brian, and Richard Lowden. Process Development for Selective Laser Melting of Molybdenum. Office of Scientific and Technical Information (OSTI), October 2018. http://dx.doi.org/10.2172/1484987.

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Hodge, N., R. Ferencz, and J. Solberg. Implementation of a Thermomechanical Model in Diablo for the Simulation of Selective Laser Melting. Office of Scientific and Technical Information (OSTI), October 2013. http://dx.doi.org/10.2172/1108835.

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Gupta, Mool C., Chen-Nan Sun, and Tyson Baldridge. Preparation of Oxidation-Resistant Ultra High Melting Temperature Materials and Structures Using Laser Method. Fort Belvoir, VA: Defense Technical Information Center, June 2009. http://dx.doi.org/10.21236/ada583075.

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Zhirnov, Ivan, Igor Yadroitsev, Brandon Lane, Sergey Mekhontsev, Steven Grantham, and Ina Yadroitsava. Influence of optical system operation on stability of single tracks in selective laser melting. Gaithersburg, MD: National Institute of Standards and Technology, August 2019. http://dx.doi.org/10.6028/nist.ams.100-27.

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6

Vrancken, B. Influence of Process Parameters and Alloy Composition on Crack Mitigation in Selective Laser Melting. Office of Scientific and Technical Information (OSTI), September 2020. http://dx.doi.org/10.2172/1661041.

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7

Geist, G. A., and R. F. Wood. Modeling of complex melting and solidification behavior in laser-irradiated materials (a description and users guide to the LASER8 computer program). Office of Scientific and Technical Information (OSTI), November 1985. http://dx.doi.org/10.2172/6265998.

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Fisher, Karl A., Jim V. Candy, Gabe Guss, and M. J. Mathews. Evaluating Acoustic Emission Signals as an in situ process monitoring technique for Selective Laser Melting (SLM). Office of Scientific and Technical Information (OSTI), October 2016. http://dx.doi.org/10.2172/1342013.

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9

Nitzler, J. A Novel Constitutive Model for Ti-6Al-4V Selective Laser Melting Based on a Microstructural Material Representation. Office of Scientific and Technical Information (OSTI), June 2018. http://dx.doi.org/10.2172/1559417.

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10

Anderson, A., and Jean-Pierre Delplanque. Development of Physics-Based Numerical Models for Uncertainty Quantification of Selective Laser Melting Processes - 2015 Annual Progress Report. Office of Scientific and Technical Information (OSTI), October 2015. http://dx.doi.org/10.2172/1226942.

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