Sensor Structural Parts are designed with particularly thoughtful considerations when dealing with vibration to ensure the accuracy and reliability of the sensor. The following are some special design considerations:
The first is the shock-absorbing design. In order to reduce the impact of vibration on the sensor, shock-absorbing structures are often used in the design of structural parts, such as rubber isolation supports, spring shock absorbers, etc. These shock-absorbing structures absorb and disperse vibration energy, thereby reducing the amplitude of vibration experienced by the sensor.
The second is to increase structural damping. By adding damping materials, such as viscoelastic materials, to structural parts, the damping ratio of the structure can be increased, thereby reducing the resonance effect caused by vibration. This design can effectively suppress the transmission of vibration and protect the accuracy of the sensor.
Then there is the rigid support structure. In order to improve the vibration resistance of Sensor Structural Parts, a rigid support structure can be used to increase the stiffness and stability of the structural parts. This design can reduce the deformation of structural parts under vibration and maintain the accuracy of the sensor.
Next is isolating the source of vibration. If possible, install the sensor away from the vibration source, or use isolation trenches, isolation walls, and other facilities to isolate the sensor from the vibration source to reduce the impact of vibration on the sensor.
In addition, modal analysis and optimization are required. Through modal analysis, the natural frequency and modal shape of the structural part under vibration can be determined, thereby avoiding resonance between the working frequency of the sensor and the natural frequency of the structural part. At the same time, based on the results of modal analysis, structural parts can be optimized and designed to improve their anti-vibration performance.
Finally, rigorous experimental verification should be performed. After the design of Sensor Structural Parts is completed, strict experimental verification is required to confirm whether its anti-vibration performance meets the requirements. Through experimental data, the design can be further improved and optimized to improve the performance of the sensor in a vibration environment.
To sum up, when dealing with vibration, Sensor Structural Parts require special considerations and designs in terms of shock absorption design, increased structural damping, rigid support structure, isolation of vibration sources, modal analysis and optimization, and experimental verification. These design measures can effectively reduce the impact of vibration on the sensor and improve the accuracy and reliability of the sensor.
