Modal Stability Control of a Wheeled Heavy Machine

Stefan Chwastek

doi:10.4028/www.scientific.net/AMM.477-478.69

Paper Titles

Design of Flat Ends in Pressure Boilers with Circular and Elliptical Stress Relieve Grooves
p.49

Analytical Estimation of Maximal Fatigue Loads in Cylindrical Roller Bearings
p.54

Analysis on Stress and Contact Failure of BNC Connector Components
p.58

Qualitative Calculation of Fatigue Life for Turbine Rotor Blade
p.63

Modal Stability Control of a Wheeled Heavy Machine
p.69

Initial Temperature Influence to the Rectangular Plates Free Vibrations under Different Types of Boundary Conditions
p.73

Research on Analytic Calculation Method of the Dynamic Response of Buried Pipelines under Indirect Ground Shock
p.77

Dynamic Experimental Investigation on the Fundamental Frequency of Liquid Storage Tanks under Seismic Excitations
p.81

Design Principles of Controlling Vehicle Gear Whine Noise Based on Loudness Metric
p.86

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 477-478Modal Stability Control of a Wheeled Heavy Machine

Modal Stability Control of a Wheeled Heavy Machine

Abstract:

Mobile heavy machines as unsprung vehicles exhibit low dissipation ability, hence the ride even at low speeds may give rise to intensive vibration, or even to the galloping effect due to enhanced vertical and angular vibration causing the road wheels to break away from the roadway. As these are mostly low-frequency vibrations, energy dissipation in wheel tires will reduce the vibration intensity in a minor degree only. As a result, the speed of a travel has to be reduced, which adversely affects the cost-efficiency of those machines. Observations of an unsprung machine during its forward ride lead us to formulate the hypothesis of reduced machines stability while it moves in the vertical plane of symmetry. The work [2] confirms the view that the vertical motion of an unsprung heavy machine while it moves forward is implemented under the condition of stability limit, mostly due to stiffness of the dynamic system in the horizontal direction. Mobile machines are dynamic systems, governed by nonlinear and often non-stationary differential equations of motion. Their stability is also dependent on the intensity of acting excitations.