Moetsi oa Fiber Optic Temperature Sensor, Sistimi ea Tlhokomelo ea Mocheso, Setsebi OEM / ODM Feme, Morekisi, Mofani.itekisitswe.

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Distributed Fiber Optic Stress Sensor Monitoring System

Sensor ea mocheso oa fiber optic, Mokhoa o bohlale oa ho beha leihlo, E ajoa ka moetsi oa fiber optic Chaena

Tekanyo ea mocheso oa fiber optic ea fluorescent Sesebelisoa sa ho lekanya mocheso oa fiber optic oa fluorescent Sistimi ea ho lekanya mocheso oa fiber optic ea fluorescence

Litšobotsi tsa distributed fiber optic stress sensing system

The characteristics of the distributed fiber optic stress real-time monitoring system are large sensing range, high accuracy, zero electrical noise, and high reliability, which can achieve multi-directional simultaneous measurement of the measured object.

Composition of Distributed Fiber Optic Stress System

The distributed fiber optic system mainly consists of detection optical cables, distributed fiber optic stress analyzers, and backend computer monitoring and alarm systems. Distributed fiber optic sensors use detection optical cables directly laid on the measured object to achieve signal acquisition; Then, the signal is transmitted to a distributed fiber optic stress analyzer through optical cables. The distributed fiber optic temperature analyzer transmits signals to the computer after program processing, and the computer system implements data processing, fault diagnosis, alarm and control.

Principle of Distributed Fiber Optic Stress Sensing System

The main principle of the distributed fiber optic stress real-time monitoring system is to utilize the sensitivity of Brillouin scattering light to temperature and strain, which can detect temperature and strain changes at different positions along the fiber optic cable. When the temperature along the fiber changes or there is axial strain, the frequency of the reverse Brillouin scattering light in the fiber will drift. The frequency drift has a good linear relationship with the changes in fiber strain and temperature. Ka hona, by measuring the frequency drift of the natural Brillouin scattering light from the square system in the fiber, the distribution information of temperature and strain along the fiber can be obtained. Suitable for stress and temperature measurement of oil, gas, and petrochemical pipelines, as well as temperature and stress monitoring of dam structures, bridge and railway structures, overhead cables, submarine cables, and offshore platform lifting device structures.

Characteristics of Distributed Fiber Optic Systems

1. Measuring distance enables remote monitoring
2. Multiple measurement channels, bophara ba tekanyo e pharaletseng
3. High spatial resolution
4. High distance resolution
5. Large dynamic range
6. Provide high reliability necessary for long-term accurate measurement
7. High speed data processing
8. Can measure multiple data points simultaneously

 

Application areas of distributed fiber optic stress

1. Natural and civil structures

2. Conduct collapse detection on slopes and tunnels on both sides of highways, national highways, and railways to prevent disasters.

3. Artificial river building structures

4. Monitor the long-term changes of bridges, buildings, ships, airplanes, spacecraft, and important cultural heritage, and promptly repair them before they collapse or are damaged.

 

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