Your search keyword '"Stawicka-Morawska, Natalia"' showing total 2 results

1. The clamping selection method to reduce the vibration of large-size workpieces during the face milling process.

Author

KALIŃSKI, Krzysztof J., GALEWSKI, Marek A., STAWICKA-MORAWSKA, Natalia, JEMIELNIAK, Krzysztof, and MAZUR, Michał R.

Subjects

WORKPIECES, ROOT-mean-squares, CUTTING force, MODAL analysis

Abstract

The article introduces a method for selecting the best clamping conditions to obtain vibration reduction during the milling of large-size workpieces. It is based on experimental modal analysis performed for a set of assumed, fixing conditions of a considered workpiece to identify frequency response functions (FRFs) for each tightening torque of the mounting screws. Simulated plots of periodically changing nominal cutting forces are then calculated. Subsequently, by multiplying FRF and spectra of cutting forces, a clamping selection function (CSF) is determined, and, thanks to this function, vibration root mean square (RMS) is calculated resulting in the clamping selection indicator (CSI) that indicates the best clamping of the workpiece. The effectiveness of the method was evidenced by assessing the RMS value of the vibration level observed in the time domain during the real-time face milling process of a large-sized exemplary item. The proposed approach may be useful for seeking the best conditions for fixing the workpiece on the table. [ABSTRACT FROM AUTHOR]

Published

2024

2. A method of predicting the best conditions for large-size workpiece clamping to reduce vibration in the face milling process.

Author

Kaliński, Krzysztof J., Stawicka-Morawska, Natalia, Galewski, Marek A., and Mazur, Michał R.

Subjects

*PROBLEM solving, *ROOT-mean-squares, *WORKPIECES, *CUTTING force, *FORECASTING

Abstract

The paper presents an innovative method of solving the problem of vibration suppression during milling of large-size details. It consists in searching for the best conditions for clamping the workpiece based on a rapid modal identification of the dominant natural frequencies only and requires repetitive changes in the tightening torque of the clamping screws. Then, by estimating the minimum work of the cutting forces acting in the direction of the width of the cutting layer, it is possible to predict the best fixing of the workpiece. Application of the method does not require the creation and identification of a computational model of the process or preliminary numerical simulations. The effectiveness of this method was confirmed by the evaluation of the Root Mean Square (RMS) of the vibration level in the time domain observed during the actual face milling process. The worst results were obtained for the configuration of supports tightened with a torque of 90–110 Nm, and the best—with a torque of 50 Nm. [ABSTRACT FROM AUTHOR]

Published

2021