{"title":"表面生长力学在增材制造问题中的应用","authors":"A. V. Manzhirov","doi":"10.1109/MCSI.2017.22","DOIUrl":null,"url":null,"abstract":"Additive Manufacturing (AM) technologies are an exciting area of the modern industry and have applications in instrumentation, engineering, medicine, electronics, aerospace industry, and other fields. AM enables cost-effective production of customized geometry and parts by direct fabrication from 3D data and mathematical models. They include electrolytic deposition, thermal and laser-based 3D printing, stereolithography, 3D-IC fabrication technologies, etc. and are booming nowadays owing to their ability to fabricate products with unique characteristics that cannot be made with traditional fabrication techniques. Despite much progress in the area of AM technologies, problems of mechanical design and analysis for AM fabricated parts yet remain to be solved. So far, three main problems can be isolated: (i) the onset of residual stresses, which inevitably occur in the manufacturing process and can lead to failure of the parts, (ii) the distortion of the final shape of AM fabricated parts, and (iii) the development of technical and technological solutions aimed at improving existing AM technologies and creating new ones. This paper deals with an approach to modeling AM processes in solid.Additive Manufacturing (AM) technologies are an exciting area of the modern industry and have applications in instrumentation, engineering, medicine, electronics, aerospace industry, and other fields. AM enables cost-effective production of customized geometry and parts by direct fabrication from 3D data and mathematical models. They include electrolytic deposition, thermal and laser-based 3D printing, stereolithography, 3D-IC fabrication technologies, etc. and are booming nowadays owing to their ability to fabricate products with unique characteristics that cannot be made with traditional fabrication techniques. Despite much progress in the area of AM technologies, problems of mechanical design and analysis for AM fabricated parts yet remain to be solved. So far, three main problems can be isolated: (i) the onset of residual stresses, which inevitably occur in the manufacturing process and can lead to failure of the parts, (ii) the distortion of the final shape of AM fabricated parts, and (iii) the development of technical and technological solutions aimed at improving existing AM technologies and creating new ones. This paper deals with an approach to modeling AM processes in solid.","PeriodicalId":113351,"journal":{"name":"2017 Fourth International Conference on Mathematics and Computers in Sciences and in Industry (MCSI)","volume":"28 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"2017-08-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"4","resultStr":"{\"title\":\"Application of Mechanics of Surface Growth to Problems of Additive Manufacturing\",\"authors\":\"A. V. Manzhirov\",\"doi\":\"10.1109/MCSI.2017.22\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Additive Manufacturing (AM) technologies are an exciting area of the modern industry and have applications in instrumentation, engineering, medicine, electronics, aerospace industry, and other fields. AM enables cost-effective production of customized geometry and parts by direct fabrication from 3D data and mathematical models. They include electrolytic deposition, thermal and laser-based 3D printing, stereolithography, 3D-IC fabrication technologies, etc. and are booming nowadays owing to their ability to fabricate products with unique characteristics that cannot be made with traditional fabrication techniques. Despite much progress in the area of AM technologies, problems of mechanical design and analysis for AM fabricated parts yet remain to be solved. So far, three main problems can be isolated: (i) the onset of residual stresses, which inevitably occur in the manufacturing process and can lead to failure of the parts, (ii) the distortion of the final shape of AM fabricated parts, and (iii) the development of technical and technological solutions aimed at improving existing AM technologies and creating new ones. This paper deals with an approach to modeling AM processes in solid.Additive Manufacturing (AM) technologies are an exciting area of the modern industry and have applications in instrumentation, engineering, medicine, electronics, aerospace industry, and other fields. AM enables cost-effective production of customized geometry and parts by direct fabrication from 3D data and mathematical models. They include electrolytic deposition, thermal and laser-based 3D printing, stereolithography, 3D-IC fabrication technologies, etc. and are booming nowadays owing to their ability to fabricate products with unique characteristics that cannot be made with traditional fabrication techniques. Despite much progress in the area of AM technologies, problems of mechanical design and analysis for AM fabricated parts yet remain to be solved. So far, three main problems can be isolated: (i) the onset of residual stresses, which inevitably occur in the manufacturing process and can lead to failure of the parts, (ii) the distortion of the final shape of AM fabricated parts, and (iii) the development of technical and technological solutions aimed at improving existing AM technologies and creating new ones. 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Application of Mechanics of Surface Growth to Problems of Additive Manufacturing
Additive Manufacturing (AM) technologies are an exciting area of the modern industry and have applications in instrumentation, engineering, medicine, electronics, aerospace industry, and other fields. AM enables cost-effective production of customized geometry and parts by direct fabrication from 3D data and mathematical models. They include electrolytic deposition, thermal and laser-based 3D printing, stereolithography, 3D-IC fabrication technologies, etc. and are booming nowadays owing to their ability to fabricate products with unique characteristics that cannot be made with traditional fabrication techniques. Despite much progress in the area of AM technologies, problems of mechanical design and analysis for AM fabricated parts yet remain to be solved. So far, three main problems can be isolated: (i) the onset of residual stresses, which inevitably occur in the manufacturing process and can lead to failure of the parts, (ii) the distortion of the final shape of AM fabricated parts, and (iii) the development of technical and technological solutions aimed at improving existing AM technologies and creating new ones. This paper deals with an approach to modeling AM processes in solid.Additive Manufacturing (AM) technologies are an exciting area of the modern industry and have applications in instrumentation, engineering, medicine, electronics, aerospace industry, and other fields. AM enables cost-effective production of customized geometry and parts by direct fabrication from 3D data and mathematical models. They include electrolytic deposition, thermal and laser-based 3D printing, stereolithography, 3D-IC fabrication technologies, etc. and are booming nowadays owing to their ability to fabricate products with unique characteristics that cannot be made with traditional fabrication techniques. Despite much progress in the area of AM technologies, problems of mechanical design and analysis for AM fabricated parts yet remain to be solved. So far, three main problems can be isolated: (i) the onset of residual stresses, which inevitably occur in the manufacturing process and can lead to failure of the parts, (ii) the distortion of the final shape of AM fabricated parts, and (iii) the development of technical and technological solutions aimed at improving existing AM technologies and creating new ones. This paper deals with an approach to modeling AM processes in solid.
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