High-Reliability Pressure Measurement for Petrochemical Process Control

Core technology

　　The petrochemical industry is a critical sector that affects both the national economy and people’s livelihoods. Pressure sensors have become integral to every key stage of petrochemical production, with their measurement data directly used for process control, safety interlocks, equipment protection, and operational optimization. The production processes associated with these sensors are characterized by extreme conditions, including high temperatures, high pressures, strong corrosivity, vibration, and flammability/explosiveness. As a core process parameter, the reliability, accuracy, and stability of pressure measurements directly impact production safety, efficiency, and product quality. However, conventional pressure measurement solutions often suffer from insufficient stability, short service life, and frequent maintenance requirements when confronted with harsh conditions such as corrosion and vibration. Even minor deviations can trigger cascading risks, leading to substantial losses.

　　Based on a deep understanding of industry pain points, SunoMeng, as a leader in high-performance nanofilm pressure sensors, leverages its proprietary core technologies and a comprehensive certification system to provide end-to-end solutions—from individual sensors to system integration. Our products boast ultra-high reliability, exceptional environmental robustness, and intrinsic safety certifications, aiming to deliver precise and trustworthy data foundations for the stable operation, process optimization, and safety early warning in modern petrochemical production, thereby enabling our customers to confidently tackle even the most daunting challenges.

Product Advantages

Service Guarantee

Core technology

　　The nano-film technology independently developed by Sensor Nobleman integrates several core technologies, including specialized metallic elastomers, novel sensitive materials, and vacuum atomic film deposition. Sensors built on this technology achieve atomic-level bonding between the sensing element and the elastomer, fundamentally overcoming the zero-point drift issue commonly encountered in traditional sensors due to structural slippage. These sensors boast exceptional characteristics such as high accuracy, minimal temperature drift, a wide operating temperature range, excellent stability, and robust resistance to vibration and shock, enabling them to operate reliably over extended periods in a variety of harsh environments.