ADDITIVE TECHNOLOGIES FOR 3D PRINTING WITH METALS

被引:0
|
作者
Latypova, M. A. [1 ]
Turdaliev, A. T. [2 ]
机构
[1] Karaganda Ind Univ, Republ Ave 30, Temirtau 101400, Kazakhstan
[2] M Auezov South Kazakhstan Univ, Tauke Khan Ave 5, Shymkent 160012, Kazakhstan
来源
USPEKHI FIZIKI METALLOV-PROGRESS IN PHYSICS OF METALS | 2024年 / 25卷 / 02期
关键词
selective laser melting; additive technologies; microstructure; microstruc- ture control; heat treatment; POWDER BED FUSION; MECHANICAL-PROPERTIES; STRESS-FIELDS; LASER; MICROSTRUCTURE; TEMPERATURE; STEEL; TI-6AL-4V; ALLOY; DEPOSITION;
D O I
10.15407/ufm.25.02.386
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
Additive 3D printing technologies dynamically developing at a rapid pace are used in progressive industries. There are several types of additive technologies based on diffused deposition modelling (FDM), lamination object manufacturing (LOM), etc. They are all united by one technological principle - the production of items through layerby-layer construction. Similar to traditional shaping methods, each type of additive tech nology has advantages and disadvantages. The principal materials traditionally used for functional products of various purposes are metals and alloys. Two main technologies for fabrication of metal products are currently well developed worldwide: SLM and EBM. Despite the high accuracy and decent quality of the products obtained by means of these technologies, they have several disadvantages, including the high cost of both the technological equipment and the raw materials used.
引用
收藏
页码:386 / 415
页数:30
相关论文
共 50 条
  • [1] 3D PRINTING AND ADDITIVE TECHNOLOGIES IN EDUCATION
    Vlkova, Iva
    Hajnys, Jiri
    [J]. 13TH INTERNATIONAL TECHNOLOGY, EDUCATION AND DEVELOPMENT CONFERENCE (INTED2019), 2019, : 859 - 864
  • [2] Additive Manufacturing Technologies: 3D Printing in Organic Synthesis
    Rossi, Sergio
    Puglisi, Alessandra
    Benaglia, Maurizio
    [J]. CHEMCATCHEM, 2018, 10 (07) : 1512 - 1525
  • [3] Modification of agar hydrogels for additive 3D printing technologies
    Zakharova, V. A.
    Kildeeva, N. R.
    Kalugina, D. S.
    Sheviakova, E. I.
    Burtseva, A-m. a.
    Zhirnov, S. V.
    Senatov, F. S.
    Gordeev, V. V.
    [J]. EUROPEAN POLYMER JOURNAL, 2024, 210
  • [4] Additive Manufacturing Technologies Used for 3D Metal Printing in Dentistry
    Revilla-León M.
    Özcan M.
    [J]. Current Oral Health Reports, 2017, 4 (3) : 201 - 208
  • [5] Inhalation exposure to metals during additive processes (3D printing)
    Beisser, R.
    Buxtrup, M.
    Fendler, D.
    Hohenberger, L.
    Kazda, V.
    von Mering, Y.
    Niemann, H.
    Pitzke, K.
    Weiss, R.
    [J]. GEFAHRSTOFFE REINHALTUNG DER LUFT, 2017, 77 (11-12): : 487 - 496
  • [6] 3D printing with metals
    Ribeiro, F
    [J]. COMPUTING & CONTROL ENGINEERING JOURNAL, 1998, 9 (01): : 31 - 38
  • [7] 3D Printing of Metals
    Gupta, Manoj
    [J]. METALS, 2017, 7 (10):
  • [8] 3D printing of microwave passive components by different additive manufacturing technologies
    Perigaud, Aurelien
    Bila, Stephane
    Tantot, Olivier
    Delhote, Nicolas
    Verdeyme, Serge
    [J]. 2016 IEEE MTT-S INTERNATIONAL MICROWAVE WORKSHOP SERIES ON ADVANCED MATERIALS AND PROCESSES FOR RF AND THZ APPLICATIONS (IMWS-AMP), 2016,
  • [9] 3D MICROSTRUCTURAL ARCHITECTURES FOR METAL AND ALLOY COMPONENTS FABRICATED BY 3D PRINTING/ADDITIVE MANUFACTURING TECHNOLOGIES
    Martinez, E.
    Murr, L. E.
    Amato, K. N.
    Hernandez, J.
    Shindo, P. W.
    Gaytan, S. M.
    Ramirez, D. A.
    Medina, F.
    Wicker, R. B.
    [J]. PROCEEDINGS OF THE 1ST INTERNATIONAL CONFERENCE ON 3D MATERIALS SCIENCE, 2012, : 73 - 78
  • [10] Disruptive Technologies: 3D Printing
    Mody, Bharat M.
    [J]. JOURNAL OF INDIAN ACADEMY OF ORAL MEDICINE AND RADIOLOGY, 2021, 33 (04) : 350 - 351
12345