SZRD810 high-frequency radar level gauge Introduction: The radar level gauge antenna emits narrow microwave pulses, which propagate at the speed of light in space. When they encounter the surface of the measured medium, some of their 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, thus calculating the distance from the antenna to the surface of the measured medium. characteristic: 1. Small beam angle (5 degrees), concentrated energy, and strong anti-interference ability 2. The antenna size is small, making it easy to install and install antenna protective devices such as dust covers; 3. The measurement blind spot is small, and good results can also be achieved for measuring small cans; 4. Short wavelength, suitable for level measurement of small particulate matter. 5. Equipped with a microprocessor and EchoDiscovery echo processing, the radar level gauge can be applied to complex working conditions. 6. Adopting pulse working mode, the radar level gauge has low transmission power and can be installed in metal and non-metal containers without harm to human body and environment. Technical parameters: Features: Multiple antennas, anti condensation, crystallization, hanging, dust, beam concentration. Application: Suitable for solids, storage containers, process containers, or environments with strong dust, easy crystallization, and condensation Range: 75m Measurement accuracy: ± 15mm Antenna material: (1) Stainless steel 316L horn/PTFE oscillator (2) Stainless steel 316L/PTFE oscillator Antenna structure: (1) Cone shaped oscillator, anti condensation material difference (2) Cone oscillator, anti condensation material Process temperature: (-40~60) ° C Process pressure: (-0.1~1.6) MPa Frequency range: 26GHz Signal output: (4-20) mA/HART Power supply: two-wire/four wire system
Introduction: The radar level gauge antenna emits narrow microwave pulses, which propagate at the speed of light in space. When they encounter the surface of the measured medium, some of their 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, thus calculating the distance from the antenna to the surface of the measured medium.
