Based on the attitude of science discovery, an industrial induction motor silencer is designed and developed, and the performance of this silencer is evaluated experimentally in this paper. The basic principle of the silencer was used as the parabola principle. During the experiment, the performance of the proposed silencer is preliminary researched using software simulation method, test analogy method, and some other methods to infer experiment was conducted to evaluate the experiment. During the simulation experiment, 25dB level can be reduced in the 12,500∼16,000Hz range. More than 35dB level was reduced in the 2,500∼5,000Hz range. When we used the silencer, the noise in the high frequency bands above 1,000Hz are reduced. In particular, 1,600Hz band is greatly reduced on average by 5dB. Some effective conclusions are obtained from the analysis of the experiment results, despite some uncertain factors in the experiment
The object of this paper is investigate noise source at metal material product manufacturing plant and create noise map for predict noise. The plant is located close to a residential area, and residents noise exposure damage expected. Through this research 68 points noise sources were measured. And according to analysis result, 30 percent of noise sources are measured above 90dB(A). Based on this measurement results were create a noise map, and comparison between the predicted noise and the background noise. The noise maps were calculated by noise prediction software using measurement data, GIS data, ESRI SHP files and actual survey data. As a analysis result, metal material products manufacturing plants are will have an effect by noise on the nearby residential area.
The present authors recently gave an analytical method for estimating three spring constants Kr, Ks, and Kt, for sidewall stiffnesses of radial tires. These represent the radial, lateral, and in-plane rotational directions respectively. The method is based on netting theory with special consideration to stiffness of the rubber matrices in the sidewall These theoretical results were verified by experiment to have sufficient accuracy. In order to confirm the availability of these spring constants, the twisting stiffness Rt of a radial tire has been analyzed in the present paper by using a spring-supported ring model. An explicit formula for Rt, expressed in terms of the three components of the spring constant, was obtained. Experiments were conducted on a 175SR14 radial tire by increasing the inflation pressure while keeping the tread circumference constant. The theoretical results agreed well with the experimental results. A related problem is also referred to; this is the forced lateral vibration with fundamental eigen-modes of the inflated sidewall-rim system when the tread is fixed. Eigen-frequencies calculated by using those spring constants coincide well with the experimental results.