Abstract

YANEZ-VALDEZ, Ricardo et al. Structural dynamics of a 3 DOF parallel kinematic machine. Ing. invest. y tecnol. [online]. 2021, vol.22, n.2.  Epub July 30, 2021. ISSN 2594-0732.  https://doi.org/10.22201/fi.25940732e.2021.22.2.013.

Milling is an intrinsically interrupted cutting operation; therefore, vibrations occur. There are both self-excited (chatter) and forced vibration. Vibrations in milling appear due to the lack of dynamic stiffness of some components in the machine tool-tool-workpiece system. If the vibrations are excessive, the machine stability is negatively affected. In this paper a parallel kinematic machine is modelled and structurally analyzed, considering vibrational parameters (mass, inertia, stiffness, and damping). Theoretical results are used to verify the model. The proposed model provides an effective guide to design milling machines with the best structural arrangement (architecture) and enhancing performance.

The value of this finding is in answering the research question: "Should the machine tool-tool-workpiece system be kept decoupled to mitigate the vibration generated during a cutting operation?" Two approaches were proposed to determine which option (coupled or decoupled bases) provides greater dynamic rigidity. The evidence shows that the decoupled base proposal maintains a cutting operation without displacement peaks due to greater operation times and better damping response.

Keywords : Cutting force; dynamic stiffness; natural frequency; parallel kinematic machine; vibration analysis.

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