1 / 55

Can nonlinear dynamics contribute to chatter suppression? Gábor Stépán

Can nonlinear dynamics contribute to chatter suppression? Gábor Stépán. Department of Applied Mechanics Budapest University of Technology and Economics. Contents. Motivation – high-speed milling

trung
Download Presentation

Can nonlinear dynamics contribute to chatter suppression? Gábor Stépán

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Can nonlinear dynamics contribute to chatter suppression?Gábor Stépán Department of Applied MechanicsBudapest University of Technology and Economics

  2. Contents • Motivation – high-speed milling • Physical background Periodically constrained inverted pendulum, and the swing Delayed PD control of the inverted pendulum Unstable periodic motion in stick-slip • Periodic delayed oscillators: delayed Mathieu equ. • Nonlinear vibrations of cutting processes • State dependent regenerative effect

  3. Motivation: Chatter ~ (high frequency)machine tool vibration “… Chatter is the most obscure and delicate of all problems facing the machinist – probably no rules or formulae can be devised which will accurately guide the machinist in taking maximum cuts and speeds possible without producing chatter.” (Taylor, 1907). (Moon, Johnson, 1996)

  4. Efficiency of cutting Specific amount of material cut within a certain time where w – chip width h – chip thickness Ω~cutting speed

  5. Modelling – regenerative effect Mechanical model τ – time period of revolution Mathematical model

  6. Milling Mechanical model: - number of cutting edgesin contact varies periodically with periodequal to the delay

  7. Contents • Motivation – high-speed milling • Physical background Periodically constrained inverted pendulum, and the swing Delayed PD control of the inverted pendulum Unstable periodic motion in stick-slip • Periodic delayed oscillators: delayed Mathieu equ. • Nonlinear vibrations of cutting processes • State dependent regenerative effect

  8. Stabilizing inverted pendula Stephenson (1908): periodically forced pendulum Mathematical background: Mathieu equation (1868) x = 0 can be stable inLjapunov sense for  < 0 .

  9. Contents • Motivation – high-speed milling • Physical background Periodically constrained inverted pendulum, and the swing Delayed PD control of the inverted pendulum Unstable periodic motion in stick-slip • Periodic delayed oscillators: delayed Mathieu equ. • Nonlinear vibrations of cutting processes • State dependent regenerative effect

  10. Contents • Motivation – high-speed milling • Physical background Periodically constrained inverted pendulum, and the swingDelayed PD control of the inverted pendulum Unstable periodic motion in stick-slip • Periodic delayed oscillators: delayed Mathieu equ. • Nonlinear vibrations of cutting processes • State dependent regenerative effect

  11. Balancing with reflex delay  instability

  12. Contents • Motivation – high-speed milling • Physical background Periodically constrained inverted pendulum, and the swing Delayed PD control of the inverted pendulumUnstable periodic motion in stick-slip • Periodic delayed oscillators: delayed Mathieu equ. • Nonlinear vibrations of cutting processes • Outlook: Act & wait control, periodic flow control

  13. Stick&slip – unstable periodic motion Experiments with brakepad-like arrangements(R Horváth, Budapest / Auburn)

  14. Contents • Motivation – high-speed milling • Physical background Periodically constrained inverted pendulum, and the swing Delayed PD control of the inverted pendulum Unstable periodic motion in stick-slip • Periodic delayed oscillators: delayed Mathieu equ • Nonlinear vibrations of cutting processes • State dependent regenerative effect

  15. The delayed Mathieu equation Analytically constructed stability chart for testing numerical methods and algorithms Time delay and time periodicity are equal: Damped oscillator Mathieu equation (1868) Delayed oscillator (1941– shimmy)

  16. The damped oscillator stable Maxwell(1865) Routh (1877) Hurwitz (1895) Lienard & Chipard (1917)

  17. Stability chart – Mathieu equation Floquet (1883) Hill (1886) Rayleigh(1887) van der Pol & Strutt (1928) Sinha (1992) Strutt – Ince (1956) diagramswing(2000BC) Stephenson’s inverted pendulum (1908)

  18. The damped Mathieu equation

  19. The delayed oscillator Hsu & Bhatt (1966) Stepan, Retarded Dynamical Systems (1989)

  20. Delayed oscillator with damping

  21. The delayed Mathieu – stability charts b=0 ε=1 ε=0

  22. Stability chart of delayed Mathieu Insperger, Stepan (2002)

  23. Contents • Motivation – high-speed milling • Physical background Periodically constrained inverted pendulum, and the swing Delayed PD control of the inverted pendulum Unstable periodic motion in stick-slip • Periodic delayed oscillators: delayed Mathieu equ • Nonlinear vibrations of cutting processes • State dependent regenerative effect

  24. Modelling – regenerative effect Mechanical model τ – time period of revolution Mathematical model

  25. Cutting force ¾ rule for nonlinear cutting force Cutting coefficient

  26. Linear analysis – stability Dimensionless time Dimensionless chip width Dimensionless cutting speed TobiasTlusty, Altintas, BudakGradisek, Kalveram, Insperger

  27. Stability and bifurcations of turning Subcritical Hopfbifurcation:unstable vibrations around stable cutting

  28. The unstable periodic motion Shi, Tobias (1984) – impactexperiment

  29. Case study – thread cutting m= 346 [kg] k=97 [N/μm] fn=84.1 [Hz] ξ=0.025 gge=3.175[mm]

  30. Stability of thread cutting – theory&exp. Ω=344 f/p Quasi-periodic vibrations: f1=84.5 [Hz] f2=90.8 [Hz]

  31. Machined surface D=176 [mm], τ =0.175 [s]

  32. Self-interrupted cutting

  33. High-speed milling Parametrically interrupted cutting Low number of edges Low immersion Highly interrupted

  34. Highly interruptedcutting Two dynamics: • free-flight • cutting with regenerative effect– like an impact

  35. Stability chart of H-S milling Sense of the period doubling (or flip) bifurcation? Linear model (Davies, Burns, Pratt, 2000)Simulation (Balachandran, 2000)

  36. Subcritical flip bifurcation

  37. Bifurcation diagram – chaos

  38. The fly-over effect

  39. Both period-2s unstable at b)

  40. Milling Mechanical model: - number of cutting edgesin contact varies periodically with periodequal to the delay

  41. Phase space reconstruction A – secondary B – stable cutting C – period-2 osc. Hopf (tooth pass exc.) (no fly-over!!!) noisy trajectory from measurement noise-free reconstructed trajectory cutting contact(Gradisek,Kalveram)

  42. The stable period-2 motion

  43. Lobes & lenses with =0.02 (Szalai, Stepan, 2006)

  44. with =0.0038 (Insperger, Mann, Bayly, Stepan, 2002)

  45. Phase space reconstruction at A Stable milling Unstable milling with (Gradisek et al.) stable period-2(?) or quasi-periodic(?) oscillation

  46. Bifurcation diagram (Szalai, Stepan, 2005)

  47. Stability of up- and down-milling Stabilization by time-periodic parameters! Insperger, Mann, S, Bayly (2002)

  48. Contents • Motivation – high-speed milling • Physical background Periodically constrained inverted pendulum, and the swing Delayed PD control of the inverted pendulum Unstable periodic motion in stick-slip • Periodic delayed oscillators: delayed Mathieu equ. • Nonlinear vibrations of cutting processes • State dependent regenerative effect

More Related