MPS3200 Pulse Radar Level Gauge

Main parameters

Measurement accuracy 3mm or 0.1%, whichever is greater

Process pressure -1 to 40 kgf/cm ²

Process temperature -40 ℃~400 ℃

Process connection flange

Application of general working condition liquid measurement

Product Features

No blind spots

High precision, two-wire technology is a substitute product for level instruments such as differential pressure, magnetostrictive, radio frequency admittance, and magnetic flap.

Not affected by pressure changes, vacuum, temperature changes, inert gases, smoke, steam and other environmental factors, the measurement results are stable and reliable.

Dual CPU, stronger hardware processing capability, smarter algorithms, and more stable system

Double compartment casing, standard magnetic buttons, high protection level

Specialized handheld device, supporting remote debugging and diagnosis

Standard surge protector, level 4 electromagnetic compatibility

Suitable for high temperature conditions, with a process temperature of up to 150 ℃. When using a high-temperature extension antenna, it can reach up to 350 ℃

The instrument graphic dot matrix LCD supports complex operations such as on-site waveform display and establishing false echoes. Reduce the difficulty of instrument operation and maintenance workload.

The LCD display unit can be externally connected to 50m (I2C) and 2km (HART) to form a tank side display operation unit. Reduce large tanks, high temperatures

The risks and labor intensity of daily inspection of instruments in high-risk areas such as high pressure and toxicity.

The instruments sold domestically come with pre installed Chinese menus, further reducing the difficulty of instrument debugging

The MPS3000 series pulse radar level gauge is a "top-down" measurement system based on the time travel principle. This instrument emits 1mW low-power microwave pulses from the radar antenna (such as a 26G frequency radar, which sends a △ t-1nS pulse and superimposes a 26GHz sine wave signal). This pulse propagates at the speed of light in space, contacts the surface of the measured medium, and some of its energy is reflected back and received by the same antenna. The time interval between transmitting and receiving pulses is proportional to the distance from the antenna to the surface of the measured medium.