• Title/Summary/Keyword: Distance Between Gear Shafts

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A Study on the Vibration/Noise Reduction of a Gear Driving System by Adjusting the Distance between Gear Shafts (기어열의 축간거리 조절을 통한 진동/소음 저감에 대한 연구)

  • Kim, Chea-Sil;Lee, Won-Chang;Lee, Jong-Pan
    • Transactions of the Korean Society for Noise and Vibration Engineering
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    • v.16 no.7 s.112
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    • pp.697-703
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    • 2006
  • This article proposes a new technique for the reduction of vibration and noise in the geared system by adjusting the distance between gear shafts. The vibration and noise may be produced by the abnormal force applied to the tooth face. And the force may be the cause of ununiform velocity in the driven shaft. If the velocity is obtained to be uniform by adjusting the distance between shafts. the vibration and noise may be reduced to some extent. In order to review, a dynamic analysis model for the gear train used in a mill turret and a test rig are developed. The velocities in the driven shaft are calculated by dynamic simulations for the model and noises in the test rig are measured with varying of the distance between shafts. The comparison of simulation and test data shows that the distance between shafts at the most uniform velocity has the lowest level of noise.

Design of a Reducer Gear for Small Electric Vehicles (소형 전기자동차용 감속기 설계)

  • Lee, Jae-gu;Kim, Sung-Hoon;Han, Sung-Gil;Shin, Yoo-In;Song, Chul Ki
    • Journal of the Korean Society of Manufacturing Process Engineers
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    • v.19 no.9
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    • pp.116-121
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    • 2020
  • In recent times, fuel economy enhancement and environmental regulation compliance have become the main topics of interest in the automobile industry. Electric vehicles are desirable alternatives to the existing cars that employ internal combustion engines. Specifically, electric vehicles are equipped with inverters, motors, and a gearbox instead of engines and transmission mechanisms. The gearbox is a key component, used to transmit power from the electric motor to the wheel. Therefore, the design of the gearbox is critical. However, most engineers design gears based only on their experience because no standards pertaining to the design factor exist, other than those for the gear ratios. To overcome this problem, the structural stabilities must be examined considering the design factors of the gears. In this study, we considered the module and number of teeth as the main factors. The constraints corresponded to the final gear ratio and fixed distance between each axle of the shafts. Moreover, a structural analysis was conducted, and the variation trend of the maximum equivalent stress against changes in the gear module and number of teeth was examined. By performing such an analysis, the structural stability in the design of a gear system could be effectively investigated.