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Tytuł artykułu

Design of self-leveling table for FFF additive technology

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The presented paper describes the conceptual design of a worktable intended mainly for use in combination with FFF additive technologies, calibrated using a gyroscope and accelerometer. The proposed system is based on a programmable Arduino platform that operates with three digital servomotors and a mechanical gyroscope. In the introduction, the theoretical assumptions, and definitions of basic concepts such as a gyroscope, electric motor, and RC servomotor are described. Subsequently, the contribution is devoted to the selection of suitable components, the schematic connection, and the design itself in the Autodesk Inventor program. In the conclusion, the anticipated benefits of using the technical solution when applied in FFF additive technologies are described.
Wydawca
Rocznik
Strony
109--117
Opis fizyczny
Bibliogr. 15 poz.
Twórcy
  • Technical University of Kosice Faculty of Manufacturing Technologies Sturova 31, 08001 Presov, Slovakia
  • Technical University of Kosice Faculty of Manufacturing Technologies Sturova 31, 08001 Presov, Slovakia
  • Technical University of Kosice Faculty of Manufacturing Technologies Sturova 31, 08001 Presov, Slovakia
  • Technical University of Kosice Faculty of Manufacturing Technologies Sturova 31, 08001 Presov, Slovakia
Bibliografia
  • [1] Steuben J, Van Bossuyt DL, Turner C. Design for fused filament fabrication additive manufacturing. In International Design Engineering Technical Conferences and Computers and Information in Engineering Conference 2015 Aug 2 (Vol. 57113, p. V004T05A050). American Society of Mechanical Engineers.
  • [2] Chin JC, Thapliyal H, Cultice T. CAN Bus: The Future of Additive Manufacturing (3D Printing). IEEE Consumer Electronics Magazine. 2022 Oct 25(99):1-6.
  • [3] Mitaľ G, Gajdoš I, Spišák E, Majerníková J, Jezný T. An Analysis of Selected Technological Parameters’ Influences on the Tribological Properties of Products Manufactured Using the FFF Technique. Applied Sciences. 2022 Apr 11;12(8):3853.
  • [4] Kaščak J, Gašpár Š, Paško J, Knapčíková L, Husár J, Baron P, Török J. Design of an atypical construction of equipment for additive manufacturing with a conceptual solution of a printhead intended for the use of recycled plastic materials. Applied Sciences. 2021 Mar 25;11(7):2928.
  • [5] Mascenik J, Coranic T. Experimental determination of the coefficient of friction on a screw joint. Applied Sciences. 2022 Nov 23;12(23):11987.
  • [6] Passaro VM, Cuccovillo A, Vaiani L, De Carlo M, Campanella CE. Gyroscope technology and applications: A review in the industrial perspective. Sensors. 2017 Oct 7;17(10):2284.
  • [7] Liu K, Zhang W, Chen W, Li K, Dai F, Cui F, Wu X, Ma G, Xiao Q. The development of micro-gyroscope technology. Journal of Micromechanics and Microengineering. 2009 Oct 16;19(11):113001.
  • [8] Ariffin NH, Arsad N, Bais B. Low cost MEMS gyroscope and accelerometer implementation without Kalman Filter for angle estimation. In2016 International Conference on Advances in Electrical, Electronic and Systems Engineering (ICAEES) 2016 Nov 14 (pp. 77-82). IEEE.
  • [9] Husar, J., Knapcikova, L., Balog, M. Implementation of material flow simulation as a learning tool. Advances in Design, Simulation and Manufacturing. Springer, 2019.
  • [10] Cao W, Mecrow BC, Atkinson GJ, Bennett JW, Atkinson DJ. Overview of electric motor technologies used for more electric aircraft (MEA). IEEE transactions on industrial electronics. 2011 Aug 18;59(9):3523-31.
  • [11] Hughes A, Drury B. Electric motors and drives: fundamentals, types and applications. Newnes; 2019 Aug 4.
  • [12] Meyer F, Spröwitz A, Berthouze L. Passive compliance for a RC servo-controlled bouncing robot. Advanced Robotics. 2006 Jan 1;20(8):953-61.
  • [13] Fedorov DS, Ivoilov AY, Zhmud VA, Trubin VG. Using of measuring system MPU6050 for the determination of the angular velocities and linear accelerations. Automatics & Software Enginery. 2015 Jan;11(1):75-80.
  • [14] Badamasi YA. The working principle of an Arduino. In2014 11th international conference on electronics, computer and computation (ICECCO) 2014 Sep 29 (pp. 1- 4). IEEE.
  • [15] Cameron N, Cameron N, Pao. Arduino Applied. Berkeley, CA: Apress; 2019.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-4b88e977-874e-428d-afde-a944ff2ff622
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