The studies currently on soft galloping (SG) and hard galloping (HG) are scarce. In this study, SG and HG of spring-mounted triangular prisms in a water channel are investigated experimentally. A power take-off system (PTO), a spring system, additional weights, and different triangular prisms were used to achieve the variations in damping coefficient c , system stiffness K , oscillation mass m and section aspect ratios α, respectively. The present paper proves that the VIV (vortex-induced vibration) lower branch can be observed in the SG response. In SG response, VIV branches are incomplete while the galloping branch is complete, and galloping can be self-initiated only in the self-excited region. On the contrary, in HG response, VIV branches are complete, the galloping branch is incomplete, and galloping can only be initiated by external excitation at a velocity exceeding the critical velocity. As c and m increase, or K and α decrease, the oscillation mode of a triangular prism gradually transitions from SG to CG (critical galloping), and continues to HG. The amplitude in VIV branch is the main reason causing the onset of galloping in SG response. A critical damping coefficient c c , which is dependent on m , K and α, is proposed to predict the occurrences of SG, CG and HG. When c < c c , SG occurs; when c > c c , HG occurs; when c = c c , CG occurs.
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机译:目前在软疾病(SG)和硬疾病(HG)上的研究是稀缺的。在本研究中,实验研究了水通道中的弹簧安装三角形棱镜的SG和HG。用于分别实现阻尼系数C,系统刚度K,振荡质量m和截面纵横比α的阻尼系数C,系统刚度K,振荡质量m和截面α的变化来实现电力消耗系统(PTO),弹簧系统,额外的重量和不同的三角形棱镜。本文证明了VIV(涡旋诱导的振动)下部分支可以在SG响应中观察。在SG响应中,VIV分支不完整,而疾驰分支是完整的,并且疾驰可以在自我激发地区自我启动。相反,在HG响应中,VIV分支完成,疾驰分支是不完整的,并且只能在超过临界速度的速度下通过外部激发开始疾驰。随着C和M增加,或k和α降低,三角棱镜的振荡模式逐渐从SG转变为CG(关键疾病),并继续到HG。 VIV分支中的幅度是导致SG响应中疾病开始的主要原因。提出了一种临界阻尼系数C C,其依赖于M,K和α,以预测SG,CG和HG的发生。当C C C时,HG发生;当C = C C时,发生CG。
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