Dynamic stability of an axially moving paper board with added subsystems

Mathematical Problems in Engineering

2019

This study investigates the thermoelastic coupling vibration and stability of rotating annular sector plates. Based on Hamilton's principle and thermal conduction equation with deformation effect, the differential equation of transverse vibration for a rotating annular sector plate is established. The differential equation of vibration and corresponding boundary conditions are discretized by the differential quadrature method. Then, the thermoelastic coupling transverse vibrations under three different boundary conditions are calculated. The change curve of the first three order dimensionless complex frequencies of the rotating annular sector plate with the dimensionless angular speed are analyzed in the case of the thermoelastic coupling and uncoupling. The effects of the dimensionless angular speed, the ratio of inner to outer radius, the sector angle, and the dimensionless thermoelastic coupling coefficient on transverse vibration and stability of the annular sector plate are discussed. Finally, we obtained the type of instability and corresponding critical speed of the rotating annular sector plate in the case of the thermoelastic coupling and uncoupling.

Section: Solution Ofmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Thermoelastic Coupling Vibration and Stability Analysis of Rotating Annular Sector Plates

Yang

Mathematical Problems in Engineering

2019

“…Yang et al 15 applied the finite element method to study the linear free vibration and nonlinear forced vibration of axially moving viscoelastic plates. Wang et al 16 studied the dynamic characteristics and stability of a paperboard with elastic point support and elastic edge constraint. The extended Hamilton principle was used to establish the equation of the system, and the meshless Galerkin method was used to discretize equation.…”

Section: Introductionmentioning

confidence: 99%

Nonlinear forced vibration of a moving paper web with varying density

Shao

Advances in Mechanical Engineering

et al. 2019

Self Cite

The study investigates the forced nonlinear vibration characteristics of an axially moving printing paper web with variable density in the lateral direction. The nonlinear governing equations of the web can be obtained by the von Karman large deflection thin plate theory. The vibration equations are discretized using the Bubnov-Galerkin method. The fourthorder Runge-Kutta technique is used to solve the differential equations of the nonlinear system. The phase-plane diagrams, time histories, bifurcation graphs, Poincare maps, and power spectrum are employed to analyze the influence of density coefficient, velocity, and aspect ratio on the nonlinear dynamic behavior of the moving paper web. The stable working region and the divergence instability region of the web are obtained. The research provides a theoretical foundation for improving the dynamic stability of a moving paper web.

“…Some research work on a high-order partial differential equation had been carried out by the Galerkin method and finite element method. 1,3,7,8,11,12,22 Yayli 23–27 used the Fourier sine series and Stoke transformation to analyze the high-order partial differential equation of vibration. The computation in these methods is complicated.…”

Section: Introductionmentioning

confidence: 99%

Thermoelastic coupling vibration and stability analysis of rotating circular plate in friction clutch

Yang

Journal of Low Frequency Noise, Vibration and Active Control

2018

Rotating friction circular plates are the main components of a friction clutch. The vibration and temperature field of these friction circular plates in high speed affect the clutch operation. This study investigates the thermoelastic coupling vibration and stability of rotating friction circular plates. Firstly, based on the middle internal forces resulting from the action of normal inertial force, the differential equation of transverse vibration with variable coefficients for an axisymmetric rotating circular plate is established by thin plate theory and thermal conduction equation considering deformation effect. Secondly, the differential equation of vibration and corresponding boundary conditions are discretized by the differential quadrature method. Meanwhile, the thermoelastic coupling transverse vibrations with three different boundary conditions are calculated. In this case, the change curve of the first two-order dimensionless complex frequencies of the rotating circular plate with the dimensionless angular speed and thermoelastic coupling coefficient are analyzed. The effects of the critical dimensionless thermoelastic coupling coefficient and the critical angular speed on the stability of the rotating circular plate with simply supported and clamped edges are discussed. Finally, the relation between the critical divergence speed and the dimensionless thermoelastic coupling coefficient is obtained. The results provide the theoretical basis for optimizing the structure and improving the dynamic stability of friction clutches.