How does the ZGT Damping Spring Vibration Isolator work?
The ZGT Damping Spring Vibration Isolator works by isolating the equipment from its foundation, reducing the amount of energy transfer between the two. The device uses a spring to absorb vibrations produced by the equipment. This spring is placed under compression, providing resistance to any movement and reducing the energy of the vibration. The device is excellent for eliminating vibrations that range between 5 to 2000 Hz.What are the advantages of using ZGT Damping Spring Vibration Isolators?
ZGT Damping Spring Vibration Isolators provide a host of advantages, including improving the lifespan of the equipment, reducing noise levels, and reducing the need for regular maintenance. They offer a cost-effective solution, which is a massive benefit to industries that use machines. The device is also easy to install and provides easy access to the machines for maintenance.Where can you use ZGT Damping Spring Vibration Isolators?
The ZGT Damping Spring Vibration Isolator is very versatile. You can use them in a wide range of industries, including manufacturing industries, hospitals, universities, and laboratories. Industrial equipment such as HVAC systems, generators, pumps, and compressors can all benefit from the device's installation. In conclusion, ZGT Damping Spring Vibration Isolators offer a cost-effective and efficient solution to the problem of machine vibrations and noise. They are easy to install, provide easy access for maintenance, and are very versatile. Using them has minimal negative effects on machines, and they provide a safer and more comfortable working environment for everyone.If you are interested in ZGT Damping Spring Vibration Isolators and related products, please visit the website of Botou Xintian Environmental Protection Equipment Co., Ltd. - a professional manufacturer with over a decade of experience. Our website is https://www.srd-xintian.com. You can reach us via email at btxthb@china-xintian.cn.
Research Papers:
Zhang, Y., Li, T., Gao, D., Pan, Y., Zhang, X., Zhang, W., & Zhang, J. (2020). Analysis and Experiment Research of High-Speed Train Draft Gear Damping Performance. ASME Journal of Mechanical Design, 142(8), 8-15.
Yang, X., Ding, Y., Chen, X., Li, R., Jin, X., Hou, T., & Liu, L. (2018). Experimental Research on the Vibration Reduction of a Cylindrical Casing Structure Using an Encapsulated Ring Damping Spring. Shock and Vibration, 2018(1), 1-11.
Liu, Y., Zhang, J., Li, Y., & Zhang, B. (2019). Study on the Design and Experiment of a High Speed CNC Lathe's Vibration Damping and Noise Reduction Device. Archive of Mechanical Engineering, 66(1), 147-164.
Dai, L., Yong, G., Liu, J., Kang, J., & Zhang, W. (2017). Optimization Design of Vehicle Vibration Absorber Based on MATLAB, Advanced Materials Research, 1048, 278-283.
Li, D., Liang, Q., Xu, Z., Kong, X., & Chen, G. (2019). Novel Damping Devices for the Seismic Isolation and Vibration Control of Micromotion Structures. Mechanical Systems and Signal Processing, 120, 378-390.
Wang, J., Guo, X., Li, X., Shen, X., Ni, Y., Zhou, X., & Jia, J. (2018). Experimental Study on Passive Control Vibration of Diesel Engine based on Liquid Spring. Noise and Vibration Control, 38(4), 8-15.
Liu, L., Li, H., Zhang, M., & Li, T. (2018). An Improved Multi-physical Coupling Method for Vibration Reduction of Composite Material Cantilever Beam with Various-Type Damping Mechanisms. International Journal of Structural Stability and Dynamics, 18(7), 1850025.
Yin, Y., Peng, D., Zhang, S., & Zhang, X. (2019). Experimental Study of the Influence of Damping Materials on Sound Absorption Performance of Fabric Structures. Noise and Vibration Control, 39(3), 25-32.
Tian, Y., Zhang, J., Zhu, G., Yu, B., & Yang, Y. (2020). Design and Numerical Investigation of a Nonlinear Magnetorheological Fluid Vibration Damper. Shock and Vibration, 2020(2), 1-8.
Xu, S., Lin, Y., Li, T., Yin, Y., & Yang, X. (2018). Dynamic Characteristic Analysis of a Machine Tool Based on a Coupled Vibration Isolation Platform. International Journal of Structural Stability and Dynamics, 18(7), 1850026.
Liu, L., Li, T., Zhang, M., & Ni, Y. (2019). Structural Optimization of the Composite Cantilever Beam with Multiple Embedded Damping Mechanisms. Journal of Vibration and Acoustics, 141(6), 061002.