Virtual simulation of a mechanical structure with 5DOF for induction hardening using Unity3D

  • Authors

    • Gal Ionel-Alexandru
    • Vladareanu Luige
    • Shuang Cang
    2018-05-16
    https://doi.org/10.14419/ijet.v7i2.28.12891
  • induction hardening, simulation, unity3D, virtual environment.

  • In this paper we propose a mechanical structure with 5 degrees of freedom, designed to be used for induction hardening of metallic profiles which are used in building framed structures. All 5 joints of the proposed mechanical structure are prismatic, required to move a metallic profile through the inducer. The simulation was achieved using Unity3D software which provides the virtual environment needed for our purposes. To use the virtual simulation of the structure, we have had to build software components to help us gain access to the simulated components during the simulation. More components were added to implement the user interface and also the management backbone of the entire simulation. All of the software components which are used to interact with the mechanical system or its joints have been configured individually, supplying environment or physical variables for each component.

     

     

  • References

    1. [1] Chauhan S., Verma V., Prakash U., Tewari P. C., & Khanduja D. “Studies on induction hardening of powder-metallurgy-processed Fe–Cr/Mo alloysâ€. International Journal of Minerals, Metallurgy, and Materials, 2017, 24(8), 918-925.

      [2] Li Z. C., & Ferguson B. L. “Induction Hardening Process With Preheat to Eliminate Cracking and Improve Quality of a Large Part With Various Wall Thicknessâ€. In ASME 2017 12th International Manufacturing Science and Engineering Conference collocated with the JSME/ASME 2017 6th International Conference on Materials and Processing (pp. V001T02A026-V001T02A026). (2017, June). American Society of Mechanical Engineers.

      [3] Habschied M., Dietrich S., Heussen D., & Schulze V. “Performance and Properties of an Additive Manufactured Coil for Inductive Heat Treatment in the MHz Rangeâ€. HTM Journal of Heat Treatment and Materials, (2016) 71(5), 212-217.

      [4] Dede E. J., Jordán J., & Esteve V. “The practical use of SiC devices in high power, high frequency inverters for industrial induction heating applicationsâ€. Power Electronics Conference (SPEC), 2016, pp. 1-5. IEEE.

      [5] [5] Phadungthin R., & Haema J., “High frequency induction heating of full bridge resonant inverter applicationâ€. Power Electronics, Electrical Drives, Automation and Motion (SPEEDAM), 2016 (pp. 1383-1387). IEEE.

      [6] [6] Porpandiselvi S., & Vishwanathan N., “Three-leg inverter configuration for simultaneous dual-frequency induction hardening with independent controlâ€. IET Power Electronics, 2015, 8(9), 1571-1582.

      [7] Neumeyer J., Groth C., Wibbeler J., & Hanke M. “FE-Simulation of Induction Hardening of a Calender Rollâ€. HTM-Journal Of Heat Treatment And Materials, 2016, 71(1), 43-50.

      [8] Mahayudin M. H., & Mat R. C. “Online 3D terrain visualisation using Unity 3D game engine: A comparison of different contour intervals terrain data draped with UAV imagesâ€. IOP Conference Series: Earth and Environmental Science, 2016, (Vol. 37, No. 1, p. 012002). IOP Publishing.

      [9] Ruzinoor C.M., Shariff A.R.M, Zulkifli A.N, Mohd Rahim M.S, Mahayudin M.H. “Web Based 3D Terrain Visualisation Using Game Engineâ€. 5th International Conference on Computing and Informatics (ICOCI 2015); 2015, Istanbul, Turkey.

      [10] Ruzinoor C.M., Zulkifli A.N., Nordin N., Mohd Yusof S.A. “A Review on Technique in Managing Oil Palm Plantation towards a Digitilized Online 3D Applicationâ€. Information Management and Business Review; 2013, 5(11):547-52.

      [11] Ruzinoor C.M., Zulkifli A.N., Nordin N., Mohd Yusof S.A. “Online 3D Oil Palm Plantation Management Based on Game Engine A Conceptual Ideaâ€. Jurnal Teknologi; 2016, 78(2-2).

      [12] Shin I-S, Beirami M., Cho S-J, Yu Y-H. “Development of 3D Terrain Visualisation for Navigation Simulation using a Unity 3D Development Toolâ€. Journal of the Korean Society of Marine Engineering; 2015, 39(5):570-6.

      [13] Chen K. C., Wang C. S., Shih H. Y., & Hsu K. S. “Development and Application of the Unity 3D Vehicle Testâ€. Journal of Internet Technology, 2015, 16(5), 841-846.

      [14] Meng W., Hu Y., Lin J., Lin F., & Teo R. “ROS+ unity: An efficient high-fidelity 3D multi-UAV navigation and control simulator in GPS-denied environmentsâ€. Industrial Electronics Society, IECON 2015 - 41st Annual Conference of the IEEE (pp. 002562-002567).

      [15] Bartneck C., Soucy M., Fleuret K., & Sandoval E. B. “The robot engine—Making the unity 3D game engine work for HRIâ€. Robot and Human Interactive Communication (RO-MAN), 2015 24th IEEE International Symposium on (pp. 431-437).

      [16] Li A., Zheng X., & Wang W. “Motion Simulation of Hydraulic Support Based on Unity 3Dâ€. First International Conference on Information Sciences, Machinery, Materials and Energy 2015. Atlantis Press.

      [17] Vladareanu L., Iliescu M., Bruja A., Vladareanu V., Gal I.A., Melinte O., Mititelu E., Margean A., Competitiveness Operational Programme (COP), European Project 2014-2020, Priority 1, Action 1.2.1. D, “Ecological and Sustainable Metal Buildings through Efficient Manufacturing Technologiesâ€, TOP MetEco AMBIENT project, ID P_39_383 / My SMIS 105188.

      [18] Vladareanu, L., Velea L. M., Munteanu R. I., Curaj A., Cononovici S., Sireteanu T., & Munteanu M. S.. “Real time control method and device for robot in virtual projectionâ€. Patent no. EPO-09464001, 18, 2009.

      [19] Vladareanu V., Dumitrache I., Vladareanu L., Sacala I. S., Tont G., & Moisescu M. A.. “Versatile intelligent portable robot control platform based on cyber physical systems principlesâ€. Stud. Informat. Control, 2015, 24(4), 409-418.

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  • How to Cite

    Ionel-Alexandru, G., Luige, V., & Cang, S. (2018). Virtual simulation of a mechanical structure with 5DOF for induction hardening using Unity3D. International Journal of Engineering & Technology, 7(2.28), 114-118. https://doi.org/10.14419/ijet.v7i2.28.12891