Modelling and numerical analysis of assembly system

• Autorzy: Budniak Z.

Identyfikatory

DOI

10.1515/ama-2015-0024

• Języki publikacji: EN

Abstrakty

EN

The present articles covers a concept of the creation and testing of assembly systems with the use of modern CAD and CAE systems on the example of an assembly system designed for joining parts with circular surfaces that are fitted with positive clearance. The numerical investigations were based on the constructed spatial skeleton pattern of the system. The purpose of the simulation tests was to determine the impact of the measurement and angular inaccuracies of all the elements of the assembly system as well as the inaccuracy of the positioning of the robot’s drives on the positioning accuracy of the parts joined taking into consideration the conditions of assembly in automatic assembly.

Słowa kluczowe

EN

modeling; numerical analysis; assembly manipulator; chain dimensional; assembly system; CAD/CAE

PL

modelowanie; manipulator montażowy; system montażowy; CAD/CAE; analiza numeryczna

• Wydawca: Oficyna Wydawnicza Politechniki Białostockiej
• Czasopismo: Acta Mechanica et Automatica
• Rocznik: 2015
• Tom: Vol. 9, no. 3
• Strony: 145--150
• Opis fizyczny: Bibliogr. 20 poz., rys., tab., wykr.

Twórcy

autor

Budniak Z.

• Faculty of Mechanical Engineering, Koszalin University of Technology, ul. Raclawicka 15-17, 75-612 Koszalin, Poland

Bibliografia

• 1. Ahn K., Cho D. (2013), Proposition for a Volumetric Error Model Considering Backlash in Machine Tools, The International Journal of Advanced Manufacturing Technology, Vol. 15, Issue 8, 554-561.
• 2. Bil T. (2010), Kinematic analysis of a universal spatial mechanism containing a higher pair based on tori. Mechanism and Machine Theory. Vol.46, Issue 4, 412–424.
• 3. Bil T. (2012), Analysis of the Bennett linkage in the geometry of tori. Mech. & Mach. Theory, Elsevier, Vol.53, 122-127.
• 4. Budniak Z. (2013), Modeling of spatial dimension chains of mounting systems using techniques CAD/CAE. Pomiary Automatyka Kontrola, vol. 59, 652-655.
• 5. Budniak Z. (2014), Mountability parts of machine with rotating surface, fitted with positive clearance. Zeszyty Naukowe Politechniki Śląskiej. Transport, 83, 29-38.
• 6. Budniak Z., Bil T. (2012), Simulation of the movement of four-bar spatial linkage. International Journal of Applied Mechanics and Enginering, vol.17, No.4, 723-732.
• 7. Chang K-H. Motion Simulation and Mechanism Design with SolidWorks Motion 2011. Schroff Development Corporation, 1-19.
• 8. Chen Y., Xie F., Liu X., Zhou Y. (2014), Error modeling and sensitivity analysis of a parallel robot with SCARA (selective compliance assembly robot arm) motions. Chinese Journal of Mechanical Engineering, Vol. 27, Issue 4, 693-702.
• 9. Huang S., Tsai J. (2005), Robotic automatic assembly system for random operating condition, The International Journal of Advanced Manufacturing Technology, Vol. 27, Issue 3, 334-344.
• 10. Kacalak W., Majewski M., Budniak Z. (2015), Worm Gear Drives With Adjustable Backlash, Journal of Mechanisms and Robotics, Vol.8, Issue 1, p.7.
• 11. Kuźmierowski T. (2010), Analysis of the geometrical accuracy of the positioning of the effector of the parallel manipulator spatial type triplanar. Acta Mechanica et Automatica, Vol.4 no.1, 56-60.
• 12. Liu J., Zhang Z., Liu Y. (2012), Universal mechanism modeling method in virtual assembly environment. Chinese Journal of Mechanical Engineering, Vol. 25, Issue 6, 1105-1114.
• 13. Liu Z., Nakamura T. (2007), Combination of robot control and assembly planning for a precision manipulator. The International Journal of Advanced Manufacturing Technology, Vol. 31, Issue 7-8, 797-804.
• 14. Storch B., Wierucka I. (2007), Optyczne pomiary zarysów powtarzalnych wykorzystaniem technik przetwarzania obrazu, Acta Mechanica et Automatica, Vol.1, nr 2, 59-62.
• 15. Tabara I., I. Dugaesescu I. (2013), The Analysis of Part Positioning and Orientation in Robotic Assembly by Insertion. New Trends in Mechanism and Machine Science Mechanisms and Machine Science, Vol. 7, 509-517.
• 16. Yun Y., Li Y. (2010), Design and analysis of a novel 6-DOF redundant actuated parallel robot with compliant hinges for high precision positioning. Nonlinear Dynamics, Vol. 61, Issue 4, 829-845.
• 17. Żebrowski-Kozioł M., Tarnowski W. (2009), Diagnozowanie stanu luzów w połączeniach przegubowych przedniego zawieszenia samochodu, Acta mechanica et automatica, vol.3 no.2, 122-124.
• 18. Zhu W., Mei B., Yan G., Ke Y. (2014), Measurement error analysis and accuracy enhancement of 2D vision system for robotic drilling. Robotics and Computer-Integrated Manufacturing, Vol. 30, Issue 2, 160-171.
• 19. Żurek J., Ciszak O., Cieślak R., Suszyński M. (2011), Assessment and choice of an industrial robot with the use of AHP method. Archives of Mechanical Technology and Automation, Vol. 31, nr 2, 201-211.
• 20. Żurek J., Wiśniewski M. (2013), The methodology and research conditions of Fanuc M-16iB industrial robot positioning accuracy and repeatability. Technologia i Automatyzacja Montażu, 2013, Vol.1, 31-34.