TY - GEN
T1 - Determination of cutting conditions for the stable milling of flexible parts by means of a three-dimensional dynamic model
AU - Campa, F. J.
AU - De López Lacalle, L. N.
AU - Bravo, U.
AU - Herranz, S.
AU - Ukar, E.
PY - 2005
Y1 - 2005
N2 - In this paper, a three-dimensional dynamic model for the prediction of the stability lobes of high speed milling is presented considering the combined flexibility of both tool and workpiece. The aim is to avoid chatter vibrations in the finish milling of aeronautical parts that include thin walls and thin floors, taking into account the variation of the dynamic properties of the workpiece during machining. Hence, the accurate selection of both axial depth of cut and spindle speed can be accomplished. The model has been validated by means of a test device that simulates the behaviour of a thin floor. The following methodology is applied: first, a modal analysis of the test device is performed, second, stability lobes are calculated, and finally, a milling test validate the approach. Vibration signals from machining have been analysed to detect the chatter vibrations. The lobes diagrams obtained considering only the machine or only the tool are not in touch with reality; only through consideration of the relative frequency response function, the real borderline of stability can be obtained.
AB - In this paper, a three-dimensional dynamic model for the prediction of the stability lobes of high speed milling is presented considering the combined flexibility of both tool and workpiece. The aim is to avoid chatter vibrations in the finish milling of aeronautical parts that include thin walls and thin floors, taking into account the variation of the dynamic properties of the workpiece during machining. Hence, the accurate selection of both axial depth of cut and spindle speed can be accomplished. The model has been validated by means of a test device that simulates the behaviour of a thin floor. The following methodology is applied: first, a modal analysis of the test device is performed, second, stability lobes are calculated, and finally, a milling test validate the approach. Vibration signals from machining have been analysed to detect the chatter vibrations. The lobes diagrams obtained considering only the machine or only the tool are not in touch with reality; only through consideration of the relative frequency response function, the real borderline of stability can be obtained.
KW - Chatter
KW - Milling dynamics
KW - Milling low rigidity parts
KW - Stability lobes
KW - Thin floors
KW - Thin walls
UR - http://www.scopus.com/inward/record.url?scp=33645969873&partnerID=8YFLogxK
U2 - 10.1115/IMECE2005-80774
DO - 10.1115/IMECE2005-80774
M3 - Conference contribution
AN - SCOPUS:33645969873
SN - 0791842231
SN - 9780791842232
SN - 0791842231
SN - 9780791842232
T3 - American Society of Mechanical Engineers, Manufacturing Engineering Division, MED
SP - 667
EP - 674
BT - American Society of Mechanical Engineers, Manufacturing Engineering Division, MED
T2 - 2005 ASME International Mechanical Engineering Congress and Exposition, IMECE 2005
Y2 - 5 November 2005 through 11 November 2005
ER -