Abstract
Affected by frequency, amplitude and some other factors, the dynamic mechanical properties of rubber bushing are nonlinear. In order to study the frequency dependence of the rubber bushing, a BP neural network optimized by genetic algorithm (GA-BP neural network) is applied to predict the dynamic stiffness and loss factor under frequency of 61–100 Hz. The training data refers to the test data under frequency of 1–60 Hz. And the algorithm is demonstrated by the elastomer test of rubber bushing under amplitudes 0.2 mm, 0.4 mm and 0.6 mm. The results show that the prediction error of dynamic stiffness is less than 1%, and the prediction error of loss factor is less than 3%. In order to apply the predicted results to the software for simulation, a five-parameter mathematical model (FPM) consisting of three elastic elements and two damping elements is developed, and the model parameters are identified by least squares method. According to the fitting results and test data, the fitting error of dynamic stiffness is less than 2%, and the fitting error of loss factor is less than 3%. The GA-BP neural network and FPM model predict the dynamic mechanical behaviour of rubber bushing without the performance of iterative experiments and the incurrence of a high computational cost, making it applicable to analyze full-size vehicles with numerous rubber bushings under various vibration load conditions.
Highlights
In order to verify the feasibility of the five-parameter mathematical model (FPM) model, the expected dynamic stiffness and loss factor under amplitude 0.4 mm and 0.6 mm are fitted by FPM model, and the fitting error is analyzed in the Figs. 23, 24, 25, 26
According to the loading displacement and force, the relationship between dynamic stiffness and loss factor with frequency is derived under different amplitudes in this paper
The results indicate that the dynamic stiffness and loss factor of the rubber bushing rise with the increase of frequency
Summary
The mechanical behaviour of rubber bushing is mainly manifested as force VS displacement (stiffness) and force VS velocity (damping), and the damping can be represented by loss factor. As a result, when the amplitude remain constant, with the rising frequency, the dynamic stiffness and loss factor of the rubber bushing trend to increase. In order to reduce cost and cycle, BP neural network is applied to predict frequency dependence of the rubber bushing. The GA-BP neural network is utilized to predict the mechanical performance of rubber bushing with frequency in this paper. The optimal weights and thresholds corresponding to the selected optimal fitness individuals are assigned to the BP neural network so as to reduce the errors of predicted stiffness, loss factor.
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