Doświadczalne badania właściwości dynamicznych układów korpusowych obrabiarek. Wybrane zagadnienia

• Autorzy: Chodźko M. , Marchelek K.

Warianty tytułu

EN

Experimental investigations of machine tools body dynamics - selected problems

• Języki publikacji: PL

Abstrakty

PL

Zagadnienia modelowania systemu obrabiarka - proces skrawania są przedmiotem wielu prac badawczych. Obecnie obserwuje się silny rozwój technik modelowania, których celem jest realizacja koncepcji wirtualnej obrabiarki. Realizacja tej koncepcji wymaga poprawnie zbudowanych i zidentyfikowanych modeli systemu obrabiarka - procesy robocze. W artykule przedstawiono wyniki badań układów korpusowych obrabiarek pod kątem określenia ich właściwości dynamicznych. Przeanalizowano wybrane sposoby wymuszania drgań układów korpusowych oraz wykazano ich zalety oraz wady. Przytoczono wyniki przeprowadzonych badań, które potwierdziły wnioski z dokonanej analizy.

EN

Modeling machine tool - cutting process system is a subject of numerous research publications. Recently a development of modeling techniques focused on realization of virtual machine tool concept has been observed. The virtual machine tool concept necessitates accurate and identified models of machine tool and processes. The paper presents results of tests carried out to obtain dynamic properties of machine tools body system. Selected excitation methods are analyzed and their advantages and shortcomings are shown. Results of conducted tests that verify performed analyses are presented.

Słowa kluczowe

PL

dynamika; analiza modalna; wibrostabilność

EN

dynamics; modal analysis; vibrostability

• Wydawca: Wydawnictwo Wrocławskiej Rady FSNT NOT
• Czasopismo: Inżynieria Maszyn
• Rocznik: 2011
• Tom: R. 16, z. 1/2
• Strony: 67--81
• Opis fizyczny: Bibliogr. 33 poz.

Twórcy

autor

Chodźko M.

autor

Marchelek K.

• Instytut Technologii Mechanicznej, Zachodniopomorski Uniwersytet Technologiczny w Szczecinie

Bibliografia

• [1] ABELE E., 2010, Machine tool spindle units, CIRP Annals - Manufacturing Technology, 59/781-802.
• [2] ALLEMANG R., 2002, The modal assurance criterion - Twenty years of use and abuse, the 20th International Modal Analysis Conference, Los Angeles, CA, February 2002.
• [3] AHMADIAN H., 2010, Tool point dynamics prediction by a three-component model utilizing distributed joint interfaces, International Journal of Machine Tools & Manufacture, 50, 998-1005.
• [4] ALTINTAS Y., 2005, Virtual machine tool, CIRP Annals - Manufacturing Technology, 54/2/115-138.
• [5] ALTINTAS Y., 2004, Chatter stability of metal cutting and grinding, CIRP Annals - Manufacturing Technology, 53/2/619-642.
• [6] CATANIA G., 2010, Theoretical-experimental modeling of milling machines for the prediction of chatter vibration, International Journal of Machine Tools and Manufacture, In Press, Corrected Proof.
• [7] CHANAL H.: 2009, Reduction of a parallel kinematics machine tool inverse kinematics, Mechanism and Machine Theory, 44/1371-1385.
• [8] CHLEBUS E., 1999, Modelling and calculation of properties of sliding guideways, International Journal of Machine Tools and Manufacture, 39/12/1823-1839.
• [9] ERTURKA A., 2006, Analytical modeling of spindle-tool dynamics on machine tools using Timoshenko beam model and receptance coupling for the prediction of tool point FRF, International Journal of Machine Tools & Manufacture, 46/1901-1912.
• [10] FUJITA T., 2011, Experimental characterization of disturbance force in a linear drive system with high-precision rolling guideways, International Journal of Machine Tools and Manufacture, 51/2/104-111.
• [11] HUO D., 2010, A holistic integrated dynamic design and modelling approach applied to the development of ultraprecision micro-milling machines, International Journal of Machine Tools & Manufacture, 50/335-343.
• [12] IGLANTOWICZ T., 1983, Doświadczalne badania dynamicznych właściwości obrabiarek przy użyciu sygnałów zdeterminowanych, rozprawa habilitacyjna, Politechnika Warszawska.
• [13] JASTRZĘBSKI D., 2010, Modelowanie wpływu błędów geometrii tocznych podzespołów prowadnicowych na ich charakterystyki statyczne, Advances in Manufacturing Science and Technology, 34/4/23-33.
• [14] JĘDRZEJEWSKI J., 2005, High-speed precise machine tools spindle units improving, Journal of Materials Processing Technology, 162-163/615-621.
• [15] JĘDRZEJEWSKI J., 1985, Selected diagnostic methods for machine tools acceptance tests, CIRP Annals - Manufacturing Technology, 34/1/343-346.
• [16] JEMIELNIAK K., 1989, The development of frequency and amplitude of chatter vibration, International Journal of Machine Tools and Manufacture, 29/2/249-256.
• [17] JEMIELNIAK K., 1989, Numerical simulation of non-linear chatter vibration in turning, International Journal of Machine Tools and Manufacture, 29/2/239-247.
• [18] JEMIELNIAK K., 2010, Advanced monitoring of machining operations, CIRP Annals - Manufacturing Technology, 59/2/717-739.
• [19] JÖNSSON A., 2005, A virtual machine concept for real-time simulation of machine tool dynamics, International Journal of Machine Tools and Manufacture, 45/7-8/795-801.
• [20] KADIR A., 2010, Virtual machine tools and virtual machining - A technological review, Robotics and Computer-Integrated Manufacturing, 494-508
• [21] KONO D., 2010, Evaluation of modelling approaches for machine tool design, Precision Engineering 34/399-407.
• [22] LAMB M., 2008, Some issues when using Fourier analysis for the extraction of modal parameters, 7th International Conference on Modern Practice in Stress and Vibration Analysis, Journal of Physics: Conference Series 181/1-8
• [23] LUTTERVELT C.A., 1998, Present situation and future trends in modelling of machining operations progress. Report of the CIRP Working Group 'Modelling of Machining Operations', CIRP Annals - Manufacturing Technology, 47/2/587-626.
• [24] MARCHELEK K., 1991, Dynamika obrabiarek, WNT, Warszawa.
• [25] OSYPIUK R., 2009, A low-cost Hexa platform for efficient force control systems using industrial manipulator, Solid State Phenomena, Vol.: Mechatronic systems and materials, 147-149, 1-6.
• [26] ÖZSAHIN O., 2010, Analysis and compensation of mass loading effect of accelerometers on tool point FRF measurements for chatter stability predictions, International Journal of Machine Tools & Manufacture, 50/585-589.
• [27] RAHMAN M., 2010, A multiprocess machine tool for compound micromachining, International Journal of Machine Tools and Manufacture, 50/4/344-356.
• [28] SALAHSHOOR M., 2009, Continuous model for analytical prediction of chatter in milling, International Journal of Machine Tools and Manufacture, 49/14/1136-1143.
• [29] TOMKÓW J., 1997, Wibrostabilność obrabiarek, WNT, Warszawa.
• [30] WANG Z., 2001, A study on workspace, boundary workspace analysis and workpiece positioning for parallel machine tools, Mechanism and Machine Theory, 36/5/605-622.
• [31] WECK M., 1989, The originating mechanisms of wheel regenerative grinding vibration, CIRP Annals - Manufacturing Technology, 38/1, 381-384.
• [32] WECK M., 1994, CAD assisted chatter-free NC tool path generation in milling, International Journal of Machine Tools and Manufacture, 34/6, 879-891.
• [33] ZAEH M., 2007, A new method for simulation of machining performance by integrating finite element and multibody simulation for machine tools, CIRP Annals - Manufacturing Technology, 56/1/383-386.