Minor abnormalities in equipment vibration can become "signal flares" for safety hazards in reaction vessels in petrochemicals, ventilation systems in coal mines, or gearboxes in wind power equipment. Especially in hazardous environments with flammable and explosive gases or dust, exceeding vibration limits can not only cause equipment shutdown, but also potentially lead to explosion accidents. Anti knock vibration sensors, as the "sensory nerves" of industrial safety, can accurately capture vibration data and resist harsh environments and potential risks, becoming essential equipment for high-risk industrial scenarios.

In the field of flexible sensing and health monitoring, achieving a wide pressure range, ultra-high sensitivity, and long-term signal stability has always been a technical challenge. Traditional sensors are prone to structural hardening and signal drift under high loads, limiting their reliable application in dynamic biomechanical monitoring. Although some studies have improved performance through microstructure or gradient designs, most still face challenges such as complex fabrication, unstable interfaces, or uneven responses.

Wound infection is the main factor causing chronic wounds to be difficult to heal. Infection can cause inflammation, tissue necrosis, and delay the repair process. Traditional diagnosis relies on manual sampling and laboratory testing, which has problems such as long testing cycles, high costs, and poor real-time performance.

In the vast expanse of oceanic shipping, the ship's engine serves as the core power source, bearing the crucial mission of propelling the giant vessel through the waves. Sensors, acting as the "nerve endings" and "sensory organs" of the engine, establish an inseparable symbiotic relationship with it through precise data collection and real-time feedback, becoming the vital support for ensuring navigation safety and enhancing operational efficiency.

With the rapid development of artificial intelligence and human-computer interaction technologies, tactile sensing technology, as a key tool for converting mechanical stimuli into readable signals, has garnered widespread attention.

Pressure resistant and waterproof acceleration sensors have become a "sensing tool" in extreme scenarios. This type of sensor achieves a dual breakthrough in protective performance and measurement accuracy through material innovation and structural optimization, providing a reliable solution for data acquisition in complex environments.