Currently, the vibration aging technology has been widely applied in fields such as construction, machinery, and equipment manufacturing. Compared to natural aging and heat aging technologies, vibration aging technology boasts low energy consumption and high efficiency.Our products offer advantages such as high efficiency, low cost, and environmental friendliness. With the advancement of product manufacturing technology, there is an increasing demand for component performance. New time-effectivity processes and theories are also continuously evolving accordingly.Previous research results indicate that there are still issues with vibration aging technology that warrant further in-depth exploration and investigation.

Microscopic mechanism of stress regulation.

We need to investigate the mechanisms of how to utilize the frequencies, powers, and durations of vibrations or creep to break, weaken, or enhance the inter-lattice constraint forces, as well as study the propagation of high-energy sound waves within materials with strong amplitudes.The relationship between the locally induced temperature rise and the work done by material crystal atoms to overcome dislocation resistance. *Ultimately, effective regulation and control of residual stress is achieved by effectively controlling the inter-lattice constraints and relaxation states.Stress.

Vibration Aging Effect Detection Technology

Parameter curve observation method and precision stability detection method both belong to qualitative detection techniques, making it difficult to obtain quantitative data. Residual stress measurement method, although a quantitative detection technique, involves various detection methods.Certain drawbacks are present, such as insufficient detection accuracy and large errors, particularly in the detection of residual stress with low amplitude, which does not meet the required capabilities.

(3) Development of a closed-loop residual stress control device.

While regulating residual stress through vibration, simultaneously detect the residual stress within the regulated area, and use the residual stress values as feedback signals to the regulation system, enabling the system to promptly judge.Next-generation regulatory instructions are implemented, thereby achieving local in-situ quantitative closed-loop control of components. Currently, there is no such closed-loop device available domestically or internationally. The development and production of this device will significantly benefit the mechanical manufacturing industry.The manufacturing process and in-service component safety have a profound impact, offering promising application prospects.