Modes of Vibration in Basketball Rims and Backboards and the Energy Rebound Testing Device

IF 1.9 Q3 ENGINEERING, MECHANICAL
Vibration Pub Date : 2023-09-22 DOI:10.3390/vibration6040045
Daniel Winarski, Kip P. Nygren, Tyson Winarski
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Abstract

Six mode shapes, including bending and torsion, were documented for five different basketball rims and backboards at the United States Military Academy, West Point, New York, NY, USA. The frequency and damping ratio of each mode shape were also determined. The empirical process began with the time-domain excitation and response of each rim-backboard system. The impulse of excitation came from an impact hammer separately applied sequentially to each node. The sinusoidal response was gathered from an accelerometer at a fixed location (node 1). Each time-domain excitation response was then converted to a frequency-domain Bode plot for each node by a Brüel & Kjær 2034 Signal Analyzer, giving transfer functions of output/input versus frequency. Structural Measurements System (SMS) StarStruc software was used to fit mode shapes to the Bode plots. Each of the six mode shapes was fitted to the Bode plots of each node at a specific modal frequency. Each of the six mode shapes was a function of the locations of the nodes, and the Bode plots gathered at each node. The first and second modes were critical for showing that the Energy Rebound Testing Device statistically correlated with the energy transferred to the rim and backboard. A known perturbation mass was selectively attached to the rim to help isolate the dynamic masses and spring rates for the rim and backboard and to ascertain that the kinetic energy transferred to the rim had a 95.67% inverse correlation with rim stiffness.
篮球篮框和篮板的振动模式及能量回弹测试装置
在美国纽约西点军校,记录了五种不同篮球圈和篮板的六种模态,包括弯曲和扭转。确定了各振型的频率和阻尼比。经验过程从每个轮辋-背板系统的时域激励和响应开始。激励脉冲来自于一个冲击锤分别依次作用于每个节点。从固定位置(节点1)的加速度计收集正弦响应。每个时域激励响应然后通过br el &kk ær 2034信号分析仪,给出输出/输入随频率的传递函数。使用结构测量系统(SMS) StarStruc软件对波德图进行模态振型拟合。六个模态振型中的每一个都在特定模态频率处拟合到每个节点的波德图上。六个模态振型中的每一个都是节点位置的函数,并且在每个节点处聚集了波德图。第一种和第二种模式对于显示能量反弹测试装置与传递到篮筐和篮板的能量的统计相关性至关重要。将已知的扰动质量选择性地附加在轮辋上,有助于分离轮辋和背板的动力质量和弹簧速率,并确定传递给轮辋的动能与轮辋刚度呈95.67%的负相关。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.20
自引率
0.00%
发文量
0
审稿时长
10 weeks
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