High Accuracy Digital Pressure Gauge With Wide Temperature Compensation OEM ODM OBM

The high-precision digital pressure gauge is a high-end instrument used for precise pressure measurement and calibration. It features extremely low measurement error, excellent stability, and a wealth of intelligent functions. It is widely applied in laboratories, metrology calibration, aerospace, power, petrochemical, and other fields.

High-precision digital pressure gauges employ highly stable sensors (such as single-crystal silicon, ceramic thick film or diffused silicon), and through microprocessor signal processing and temperature compensation, ensure that measurement results are not affected by environmental changes. Some models support magnetic pen sensing for zero adjustment and digital calibration, eliminating the need for hardware adjustments.

1. Ultra-high Precision
   • The accuracy grades are typically 0.05, 0.025, and 0.02. Some high-end products can reach 0.005 (such as brands like Shanghai Mingkong and Siston).
   • The allowable error is extremely small. For example, a 0.05 grade gauge has an error of only ±5 kPa at a 10 MPa range.
2. Intelligent Functions
   • Multi-unit Switching: Supports over 10 units including kPa, MPa, bar, and psi.
   • Data Recording and Communication: Equipped with RS485, 4-20mA output or USB interface, allowing connection to PLC or data export.
   • Peak Recording and Linear Correction: Captures instantaneous pressure peaks and supports multi-point linear calibration.
3. Environmental Adaptability
   • Wide temperature compensation range (-10°C to 50°C), and explosion-proof type (ExiaIIBT4) suitable for hazardous environments.
   • Long battery life (5 to 7 years), with low power consumption design for long-term online monitoring.

1. Metrological calibration

   Used as a standard gauge to calibrate ordinary pressure gauges and transmitters, suitable for metrology institutes and enterprise laboratories.

2. Industrial precision control

   High-precision pressure monitoring in hydraulic systems, semiconductor manufacturing, and medical equipment (such as ventilators).

3. Scientific research and aerospace

   High-pressure material experiments, engine fuel system testing, etc.

• Integration of Internet of Things (IoT) and Edge Computing: The next generation of products will be equipped with LoRaWAN/NB-IoT modules to enable real-time transmission of pressure data to the cloud, supporting remote diagnosis and predictive maintenance. For instance, a smart factory reduced the response time for faults from 2 hours to 10 minutes by using wireless digital pressure gauges.
• AI Algorithms Empowering Machine Learning Models: Machine learning models can analyze historical data to automatically identify abnormal pressure patterns (such as leakage trends) and provide early warnings of equipment failures 3 to 6 months in advance. A chemical enterprise reduced unplanned downtime by 40% through this feature.
• Innovations in Materials Science: The application of ceramic sensors and graphene materials can enhance corrosion resistance and sensitivity, making them suitable for extreme media such as strong acids and high temperatures. A laboratory device extended the sensor's lifespan from 1 year to 3 years by applying a graphene coating.
• Multi-parameter Fusion Measurement: Integration of sensors for temperature, humidity, and micro-water content enables simultaneous monitoring of multiple physical quantities. For example, the Weifers WINFOSS-D6 model can output both pressure and micro-water content simultaneously, with an accuracy of ±3μL/L.