Flexibly adjustable quasi-zero rigidity vibration attenuation platform

A quasi-zero stiffness, platform technology, applied in the field of vibration reduction platforms, can solve the problems of increased deformation of elastic components, weakened system carrying capacity, low stiffness, etc., to facilitate replacement, solve inherent contradictions, and solve low-frequency vibration transmissibility. Effect of High Frequency Vibration Attenuation Rate

Active Publication Date: 2015-11-18
ANHUI UNIVERSITY OF TECHNOLOGY AND SCIENCE
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  • Abstract
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AI Technical Summary

Problems solved by technology

The low stiffness of the system will lead to increased deformation of the elastic elements, resulting in weakened system load capacity and new contradictions
At the same time, due to the needs of production development and scientific experiments, precision mechanical systems have higher and higher requi

Method used

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  • Flexibly adjustable quasi-zero rigidity vibration attenuation platform
  • Flexibly adjustable quasi-zero rigidity vibration attenuation platform
  • Flexibly adjustable quasi-zero rigidity vibration attenuation platform

Examples

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Embodiment Construction

[0033] The specific embodiment of the present invention will be described in further detail by describing the embodiments below with reference to the accompanying drawings, the purpose is to help those skilled in the art to have a more complete, accurate and in-depth understanding of the concept and technical solutions of the present invention, and contribute to its implementation.

[0034] Such as Figure 1 to Figure 7 As shown, the present invention provides a flexibly adjustable quasi-zero stiffness vibration damping platform, including a fixed platform, a moving platform 6, a vibration damping assembly and a thrust assembly. The damping assembly is connected with the fixed platform and the moving platform 6, the thrust assembly is arranged on the fixed platform, and the thrust assembly is used to apply thrust to the moving platform 6, and there are multiple thrust assemblies around the moving platform 6.

[0035] Specifically, the moving platform 6 is vertically movable r...

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Abstract

The invention discloses a flexibly adjustable quasi-zero rigidity vibration attenuation platform. The flexibly adjustable quasi-zero rigidity vibration attenuation platform comprises a fixed platform, a moving platform, a vibration attenuation component and thrust components, wherein the vibration attenuation component is connected with the fixed platform and the moving platform; the thrust components are arranged on the fixed platform and used for exerting a thrust force on the moving platform; the multiple thrust components are arranged around the moving platform. According to the flexibly adjustable quasi-zero rigidity vibration attenuation platform, quasi-zero rigidity in a static balance position and nonlinearity rigidity nearby a static balance position of the vibration attenuation platform can be achieved; the problem of failure in low frequency or ultra-low frequency vibration isolation in terms of traditional linear vibration isolation systems can be solved; inherent contradictions which restrict the traditional vibration isolation systems can be eliminated; problems in low frequency vibration transmission rate and high frequency vibration attenuation rate can be solved.

Description

technical field [0001] The invention belongs to the technical field of mechanical engineering, relates to vibration reduction and vibration isolation technology in mechanical engineering, in particular to a vibration reduction platform with quasi-zero stiffness. Background technique [0002] According to the vibration theory, the initial vibration isolation frequency of the traditional passive vibration isolation system is the natural frequency of the system itself. times. If you want to achieve low-frequency, ultra-low-frequency and wide-frequency vibration isolation in the range of 0.5-70Hz, you can only reduce the natural frequency of the system itself, but the natural frequency of the system is related to the stiffness, and reducing the natural frequency requires reducing the system stiffness. The low stiffness of the system will lead to the increase of the deformation of the elastic elements, resulting in the weakening of the bearing capacity of the system and the eme...

Claims

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Application Information

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IPC IPC(8): F16F7/00
CPCF16F7/00
Inventor 时培成聂高法李震肖平何芝仙高洪潘道远唐冶李仁军姜忠宇韦山
Owner ANHUI UNIVERSITY OF TECHNOLOGY AND SCIENCE
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