可折叠倒螺旋折纸结构液压减振器的研究

IF 1.9 Q3 ENGINEERING, MECHANICAL Vibration Pub Date : 2022-10-21 DOI:10.3390/vibration5040042
Jingchao Guan, Jingshun Zuo, Wei Zhao, Nobuyuki Gomi, Xilu Zhao
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引用次数: 2

摘要

用于工业机械和建筑结构的减振器通常是圆柱形的。本文提出了一种新颖的折纸型轴向自由折叠液压阻尼器,以改善传统的有效行程相对于总长度有限的圆柱体形状的结构特性。首先,推导了折纸液压减振器的基本设计方程,证明了折纸液压减振器的侧壁折线缸始终满足折纸液压减振器的可折叠条件,即α=π/n和π/2n≤β≤π/n;其次,分析了折纸液压阻尼器内部和流道内的流体流动特性;确定了折纸阻尼器的实际阻尼力与运动速度的平方成正比。考虑导出的阻尼力方程,建立了运动方程,并建立了基于Range-Kutta数值分析技术的振动分析方法。建立了折纸液压阻尼器在质量-弹簧振动系统中的验证试验系统,并利用实际地震波进行了振动试验,验证了折纸液压阻尼器的阻尼特性和有效性。此外,在振动试验中,折纸结构末端的孔直径以及内部流体的类型也发生了变化。分析了折纸液压阻尼器的主要组成部分对阻尼效果的影响,发现节流孔直径比内部流体对阻尼效果的影响更为显著。
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Study on Hydraulic Dampers Using a Foldable Inverted Spiral Origami Structure
Hydraulic dampers for the vibration damping of industrial machinery and building structures are typically cylindrical. This study proposes a novel, axially free-folding hydraulic damper of the origami type to improve the structural characteristics of the conventional cylinder shape with restricted effective stroke in relation to the overall length. First, the basic design equation of the proposed origami hydraulic damper was derived by demonstrating that the fold line cylinders on the sidewalls will always meet the foldable condition of the origami hydraulic damper, that is, α=π/n and π/2n≤β≤π/n. Next, the fluid flow characteristics inside the origami hydraulic damper and in the flow path were analyzed; it was determined that the actual damping force exerted on the origami damper was proportional to the square of the velocity of motion. Equations of motion were developed considering the derived damping force equation, and a vibration analysis method using the Range–Kutta numerical analysis technique was established. A validation test system with an origami hydraulic damper in a mass-spring vibration system was developed, and vibration tests were performed with actual seismic waves to verify the damping characteristics and effectiveness of the origami hydraulic damper. Furthermore, the orifice hole diameter at the end of the origami structure as well as the type of internal fluid, were varied in the vibration tests. The effect of the main components of the origami hydraulic damper on the damping effect was analyzed, revealing that the orifice hole diameter had a more significant effect than the internal fluid.
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CiteScore
3.20
自引率
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审稿时长
10 weeks
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