Abstract: In this paper it is presented in brief the design and manufacturing for a Delta robot with 3 degrees of freedom. Fusion 360 software was used to design the robotic system, and with the help of a 3D printer, the components of the robotic system were built. With the help of the ideaMaker program 3D printing was done. After assembling the robotic system and create control for this robot, the servo motors on the robot base were actuated for the final tests. With the help of these tests, the performance of the robotic system was validated.
Key words: Delta robotic system, degree of freedom, design, 3D printer, pick and place, manufacture.

Olawale, J., Oludele, A., Ayoudele, A., Development of a Microcontroller Based Robotic Arm, Proceedings of the 2007 Computer Science and IT Education Conference, pp. 550-557, 2007

Elfasakhany, R., Yanez, E., Baylon, K., Salgado, K., Design and Development of a Competitive Low-Cost Robot Arm with Four Degrees of Freedom, Modern Mechanical Engineering, vol. 1, pp. 47-55, doi: 10.4236/mme.2011.12007, 2011

Iordan, A.E., Interactive Software Design for Shaping Electrical Circuits utilizing Graphs, Annals of Faculty Engineering Hunedoara, vol. 13, pp. 175-178, ISSN 1584-2673, 2015

Iordan, A.E., Panoiu, M., Multimedia Educational Software for Producing Graphs of Mathematical Functions, International Journal of Computers, Comunications and Control, vol. 1, pp. 284-289, ISSN 1841-9836, 2006

Deteşan, O., The dynamic modelling of the robot mechanical structure using the symbolic computation in Matlab, Acta Tehnica Napocensis, Series: Applied Mathematics and Mechanics, vol. 56, Issue IV, ISSN 1221-5872, pp. 659-664, Cluj-Napoca, România, 2013

Schonstein, C., Kinematic control functions for a serial robot structure based on the time derivative jacobian matrix, Acta Tehnica Napocensis, Series: Applied Mathematics and Mechanics, vol. 61, Issue II, ISSN 1221-5872, pp. 253-660, Cluj-Napoca, România, 2018

Pandilov, Z., Dukovski, V., Comparison of the characteristics between serial and parallel robots, ACTA TECHNICA CORVINIENSIS – Bulletin of Engineering,

vol. 1, Issue VII, ISSN: 2067 – 3809, 2014

***, www.autodesk.com/products/fusion-360/students-teachers-educators

Timoftei, S., Brad, E., Sarb, A., Stan, O., Open-source software in robotics, Acta Tehnica Napocensis, Series: Applied Mathematics and Mechanics, vol. 61, Issue III, ISSN 1221-5872, pp. 519-626, Cluj-Napoca, România, 2018

***, raise3d.com/pages/ideamaker

Masood, S., Introduction to Advances in Additive Manufacturing and Tooling, Comprehensive Materials Processing. vol.10, Advances in Additive Manufacturing and Tooling, pp. 1–2, ISBN: 978-0-08-096533-8, 2014

Popescu, D., Popişter, F., Eles, A., Comes, R., Improving the quality of plastic parts obtained by 3d printing, Acta Tehnica Napocensis, Series: Applied Mathematics and Mechanics, vol. 58, Issue I, ISSN 1221-5872, pp. 25-30, Cluj-Napoca, România, 2015

***,allthat3d.com/pla-vs-abs/

Vertutt, J., Liegeois, A., General design criteria for manipulators, Mechanism and Machine Theory, vol. 16, Issue 1, pp. 65-70, doi.org/10.1016/0094-114X (81)90052-5, 1981

Drumright, R., Ruber, P., Henton, D., Polylactic acid technology, Advanced Materials, vol. 12, Issue 23, pp. 1841-1846, ISSN: 0935-9648, 2000