światłowodowe systemy czujników

Fluorescent fiber optic temperature sensing system

The fluorescent fiber optic temperature sensor consists of a multimode fiber optic and a fluorescent object (film) mounted on top of it. Its working principle is based on the fluorescence energy emitted by a fluorescent substance under specific wavelength (excitation spectrum) light excitation. After the excitation is cancelled, the persistence of the fluorescence afterglow is affected by factors such as the characteristics of the fluorescent substance and environmental temperature. The fluorescence usually decays exponentially, and the decay time constant is the fluorescence lifetime or fluorescence afterglow time (ns). Ponadto, the fluorescence afterglow decay varies at different environmental temperatures. Dlatego, the environmental temperature can be determined by measuring the fluorescence afterglow lifetime.

This sensing system has multiple advantages. Po pierwsze, the core technology lies in fluorescent substances and corresponding simulation algorithms. The technical principle and product structure are simple, i temperature measuring fluorescent material used is calcined at 1200 stopni Celsjusza, which has extremely long lifespan and stable and reliable working characteristics. It is very suitable for large-scale industrial mass production and widely used in the industrial field. Po drugie, pure fiber optic probes have the characteristics of intrinsic safety, izolacja wysokonapięciowa, i odporność na zakłócenia elektromagnetyczne; The system operates stably without drift and does not require calibration or verification throughout its entire lifespan; Adopting modular design, it can be flexibly networked and infinitely expanded at any time without causing resource waste; Equipped with digital and analog outputs, it is convenient for automated real-time control and data management; The probe and demodulator are compact and flexible, easy to install and maintain. It is widely used in various application fields. In the field of power grid, it can be used to monitor the temperature of hot spots such as switchgear and transformers, detect temperature anomalies in a timely manner, and ensure the safe and stable operation of power; In the field of laboratory research, it is possible to monitor the temperature changes of reaction systems in chemical experiments to ensure the accuracy of experimental results, and in biological experiments, możliwe jest monitorowanie rozkładu temperatury wewnątrz organizmu, co pomaga badaczom medycyny badać stabilność termiczną organizmów; W dziedzinie medycyny, Zmiany temperatury pacjentów można monitorować podczas operacji, aby zapewnić płynne działanie, i może być stosowany w ośrodkach rehabilitacyjnych do oceny stanu zdrowia pacjenta. Ponadto, ma unikalne zalety w wielu specjalnych scenariuszach, takich jak pomiar temperatury wewnętrznej nuggetsów z kurczaka w przemyśle spożywczym, aby upewnić się, że wnętrze jest ugotowane, a powierzchnia nie ulega spaleniu podczas procesu pieczenia; Gdy w przemyśle elektronicznym przeprowadza się precyzyjne łączenie małych elementów w środowisku mikrofalowym w celu monitorowania temperatury, tradycyjne termometry termoparowe nie mogą dokładnie mierzyć ze względu na wpływ mikrofal, while fluorescent fiber optic temperature sensors have obvious advantages of not being affected by electromagnetic interference. Experiments have shown that in this scenario, fiber optic thermometers read accurately and are not affected by external factors, while thermocouple thermometers have large errors.

Multi domain related application supplement

In addition to the common application areas mentioned earlier, fluorescencyjne światłowodowe czujniki temperatury also have important value in other industries. W przemyśle petrochemicznym, places such as refineries have flammable, materiał wybuchowy, i środowiska korozyjne. The intrinsic safety and corrosion resistance of fluorescent fiber optic temperature sensors enable them to effectively monitor the temperature of pipelines, reaction vessels, and other equipment, ensuring that the production process is carried out under appropriate temperature conditions and the safety of personnel and equipment is guaranteed. In the aerospace field, temperature detection can be performed on key components such as engines, which requires sensors to have high accuracy, odporność na wysoką temperaturę, i odporność na zakłócenia elektromagnetyczne. Fluorescent fiber optic temperature sensors can precisely meet these requirements and help improve the safety and reliability of aerospace equipment operation. In the field of new energy such as solar power generation, temperature measurement can be carried out on solar panels to optimize their energy conversion efficiency through temperature data acquisition. Once the temperature is too high and affects the power generation efficiency, timely adjustment measures can be taken. Krótko mówiąc, the characteristics of fluorescent fiber optic temperature sensors enable them to continuously open up new application scenarios in many fields with special requirements for temperature detection.

Distributed Fiber Optic Sensing System

The rozproszony światłowód sensing network system is a network system that integrates sensing, kontrola, and other functions. It uses optical fiber as a sensing medium, which can sense external physical quantities by changing its characteristics such as wavelength, faza, and intensity. Naraz, optical fiber can be well integrated with optical fiber sensing network systems as a communication medium. This system has the characteristics of anti electromagnetic interference, wysoka niezawodność, and long-distance distributed monitoring, and has broad application value and market prospects.

From a technical perspective, nonlinear optical effects such as Raman and Brillouin effects in fiber optics are used to detect environmental temperature and pressure induced stress. Na przykład, Raman scattering is used for distributed temperature sensing (DTS), which can accurately determine the temperature at any given position along the fiber by measuring the difference in the intensity of backscattered light in the Stokes and anti Stokes bands; The principle of Brillouin scattering is similar, where the wavelength of backscattered light is influenced by external temperature and acoustic stimuli in a predictable manner. By combining this data with temperature background knowledge at the same point, the strain experienced by the fiber can be accurately determined, and which areas of the fiber are affected can be analyzed.

It plays an irreplaceable role in many fields. In terms of security monitoring, it is a highly eye-catching new device of fiber optic sensing technology, which can achieve perimeter monitoring and alarm for special locations such as airports, borders, podstawy, porty, itp; Safety monitoring of oil/gas pipelines and refinery oil pipelines; It can achieve tunnel excavation detection for special locations such as military bases, więzienia, banks, and nuclear power plants, and timely detect potential threats; The long-distance distributed monitoring capability for optical cables in government, banking, intelligence agencies, and other locations is beyond the reach of traditional sensors. And it also has applications in industrial monitoring, such as temperature scanning of grain warehouses and oil depots to comprehensively understand temperature distribution and achieve more accurate monitoring. It can also be used for distributed temperature and strain monitoring of various structures such as bridges, tamy, tunele, itp.

In terms of technical indicators and practical application characteristics, it is clearly reflected in a distributed fiber optic sensing early warning system. The single core positioning technology designed with a dual core optical path saves fiber resources and improves positioning accuracy compared to the international three core positioning technology; The system is divided into two types: fence type and buried type to adapt to different application scenarios of surface fences (such as wrought iron, wire mesh, fences, walls, itp.) and underground (such as grasslands, gravel layers, cement floors, and ordinary soil); The warning system surpasses similar foreign systems in key technologies such as light intensity, polarization state, polarization angle, optical signal frequency, faza, optical phase locking, chaotic neural network recognition algorithm, and fusion technology; It has the advantages of truly passive front-end sensing and transmission, easy construction, i niski koszt (using ordinary communication optical cables as sensors); There are also multiple monitoring methods available, which can display real-time time-domain waveforms of fiber optic cable disturbances, monitor interference sounds along the fiber optic cable, count the number of fiber optic cable disturbance events at different time periods or distances, accurately classify and identify fiber optic cable disturbances along the route, and display alarms on geographic information diagrams; There are corresponding parameters and requirements for technical indicators such as response time, odpowiedź częstotliwościowa, fiber optic service life, alarm probability, false alarm probability, monitoring distance, positioning accuracy, and working temperature.

Supplement to the New Application Trends of Distributed Fiber Optic Systems

With the further development of technology, the application scenarios of distributed fiber optic sensing systems are constantly expanding and extending. In the field of urban rail transit, the health status of subway tunnel structures can be monitored. By laying distributed fiber optic sensors inside or around the tunnel walls, changes in key parameters such as strain and temperature of the tunnel can be sensed in real time. If there are structural deformations (possibly caused by geological changes, trzęsienia ziemi, itp.) or temperature anomalies (such as fire hazards, itp.), the system can provide timely feedback data for the operator to take measures to prevent safety accidents from occurring. In the construction of smart grids, distributed fiber optic sensing systems can dynamically monitor ultra-high voltage transmission lines. They not only rely on traditional temperature monitoring to ensure the safe operation of the lines (as high line temperatures may increase line losses and make them prone to faults), but also monitor the mechanical properties of the lines (such as tension, napięcie, itp.) by reflecting changes in fiber optic characteristics caused by physical quantities through czujniki światłowodowe, making the entire power grid more intelligent and reliable. Ponadto, there are potential applications and development prospects in the field of ocean engineering, such as monitoring submarine cables and monitoring the structural health of offshore oil platforms, to safeguard the development and utilization of marine resources.

Fiber Bragg Grating Temperature Sensing System

Fiber Bragg Grating sensing technology uses fiber Bragg gratings as sensing elements to measure physical quantities through optical fibers, and temperature sensing is a widely used sensing type. Siatka Bragga z włókna (FBG) is a frequency selective optical reflector made using the principle of fiber optics. Under the excitation of a light source, the optical signal reaches the grating through the fiber and is reflected back. The change in sensing quantity of the FBG can be determined from the reflected light intensity and wavelength distribution.

The principle of fiber optic grating temperature sensing is based on the change in grating Bragg wavelength caused by temperature changes. The reflected spectrum is captured by a CCD camera, and the reflected light signal is processed by a signal processor to achieve temperature measurement. In terms of control system, if a temperature control system is built based on fiber Bragg grating sensing technology, it mainly consists of four parts: signal acquisition, przetwarzanie sygnału, control module, and actuator. The fiber Bragg grating sensor in the signal acquisition process transmits the collected signals to the signal processing module for preprocessing; The signal processing module is based on the collected temperature and is controlled by an incremental PID controller for temperature related control; The control module can adopt an embedded system, which can communicate with the upper computer, achieve real-time monitoring of temperature and control standards, and be used for developing other advanced applications; The executing mechanism includes DC motor, variable frequency motor, stepper motor, itp.

Czujniki temperatury z siatką Bragga have multiple advantages. Po pierwsze, it has high sensitivity, which is related to its sensing technology principle and can accurately sense temperature changes; Po drugie, it does not require an external power supply and is not affected by electromagnetic interference. Ponadto, its probe can resist mechanical, electromagnetic, and chemical interference well, i może wiarygodnie mierzyć wielkości fizyczne w trudnych warunkach środowiskowych, takich jak poszukiwania ropy i gazu (często ze złożonymi zakłóceniami elektromagnetycznymi i możliwymi środowiskami korozji chemicznej), lotniczy (z różnymi złożonymi źródłami promieniowania i innymi zakłóceniami w przestrzeni oraz specjalnymi wymaganiami dotyczącymi masy sprzętu), diagnoza lekarska (z wieloma otaczającymi urządzeniami w środowiskach medycznych, złożone środowiska elektromagnetyczne i wysokie wymagania dotyczące bezpieczeństwa sprzętu detekcyjnego), i kontrola procesów przemysłowych (pod wpływem środowiska pola elektromagnetycznego i różnych substancji chemicznych w przemyśle); I ma cechy wysokiej stabilności, nie ma wpływu intensywność światła i plamy, a także zalety, takie jak mały rozmiar, lekka waga, szybki czas reakcji, przeciwdziałające zakłóceniom elektromagnetycznym, i silna odporność na korozję, which make it more competitive than other types of sensors in a wide range of application scenarios. Ponadto, the fiber Bragg grating temperature sensing technology based on phase sensitive detection is worth mentioning. This is a commonly used fiber Bragg grating temperature sensing technology, which uses an interferometer to coherently interfere the reflected light of FBG (włóknista siatka Bragga) with the reference light, thereby improving the sensitivity and stability of the sensor. It has achieved ultra-high sensitivity at the sub millikelvin level, making it particularly suitable for precise measurement of small temperature changes, such as in biomedical imaging, mikroprzepływy, and nanotechnology, and has broad application prospects.

Fiber Bragg Grating technology involves the supplementation of special materials

In the production and application of fiber Bragg grating temperature sensing systems, research and application of some special materials or structures are involved. The production of fiber optic gratings has special requirements, and the material composition of the fiber core and cladding needs to be precisely controlled in order to achieve the desired optical properties such as refractive index changes of the grating accurately. Na przykład, fibers doped with specific elements such as germanium can optimize the performance of gratings. In terms of sensing applications, research on coating materials on the surface of fiber Bragg gratings is also constantly deepening. Special coating materials can enhance the corrosion resistance of fiber Bragg gratings or improve their interaction with the detected substance. Na przykład, w niektórych scenariuszach zastosowań monitorowania środowiska korozyjnego, poprzez powlekanie odporną na korozję i przewodzącą ciepło powłoką polimerową, sama krata nie ulega korozji, a temperatura zewnętrzna może szybko przenieść się na obszar kraty, dzięki czemu pomiar jest dokładniejszy. Dochodzi także dobór i zastosowanie materiałów opakowaniowych do czujników. Odpowiednie materiały opakowaniowe mogą nie tylko chronić siatkę Bragga przed normalną pracą w złożonych środowiskach zewnętrznych (jak wysoka wilgotność, wysokie ciśnienie, itp.), ale także zminimalizować wpływ na przewodność cieplną podczas Pomiar temperatury siatki Bragga. Na przykład, materiały kompozytowe o dobrych właściwościach uszczelniających, odpowiedni współczynnik przewodzenia ciepła, a do pakowania można zastosować dobrą sztywność i wytrzymałość.

Przegląd systemów czujników światłowodowych

Fiber optic sensor system is a sensing system based on optical fibers, including various types such as fluorescent fiber optic temperature sensing system, rozproszony system detekcji światłowodowej, fiber optic grating temperature sensing system, itp. Each type has different characteristics in terms of principle, struktura, wydajność, itp. to adapt to different application scenarios.

W zasadzie, it is to use the modulation of some characteristics of light (such as wavelength, intensywność, faza, itp.) by the fiber itself or the substances inside the fiber when light propagates in the fiber to reflect the information of external environmental changes, thus achieving the purpose of sensing and measurement. Na przykład, the fluorescence fiber temperature sensing mentioned earlier is based on the relationship between fluorescence afterglow lifetime and temperature; Distributed fiber optic sensing utilizes phenomena such as Raman scattering and Brillouin scattering to measure physical quantities such as temperature or strain through differences in light intensity or wavelength changes; Fiber Bragg grating temperature sensing relies on temperature induced changes in grating Bragg wavelength to sense temperature.

Structurally, although there are differences among the systems, they are generally built around fiber optics. Fluorescencyjny fiber temperature sensing system consists of a fluorescent material module at the top of the fiber, a fiber transmission part, and a signal demodulator to achieve temperature sensing and other functions; The entire network construction of the distributed fiber optic sensing system includes the fiber optic network layout in the operation, module components connected to the fiber optic network for different functions (such as acquisition, przetwarzanie, itp.), itp. The structure should ensure the ability to achieve continuous long-distance distributed measurement functions; The fiber optic grating temperature sensing system is built around the fiber optic grating, the relevant optical components for collecting and analyzing the reflected light from the grating, and the structure of the entire temperature sensing control system through additional circuit modules.

In terms of performance, the three systems face different evaluation metrics. The fluorescence fiber optic temperature sensing system focuses on the accuracy of measurement in different temperature ranges, the stability of the entire system (such as the important stability advantage of not requiring calibration and verification throughout the entire life), and the various properties of the probe (such as insulation, odporność na korozję, bezpieczeństwo, itp.); The rozproszone wykrywanie światłowodowe system requires positioning accuracy, monitoring distance, odpowiedź częstotliwościowa, itp. for long-distance measurement, so that it can play a role in application scenarios such as long-distance and large-scale safety monitoring; The fiber Bragg grating temperature sensing system mainly focuses on the sensitivity and anti-interference performance of the sensor (such as electromagnetic interference, chemical environmental interference, itp.), as well as the convenience of using the sensor in different target application fields (such as the influence of size and weight on installation and use in special environments, itp.).

Fiber optic sensor systems have a wide range of applications in various fields such as industrial manufacturing, energia, komunikacja, security and safety, lotniczy, biomedicine, itp. due to their inherent ability to resist electromagnetic interference, feasibility of measuring multiple physical quantities, and adaptability in different environments. Na przykład, in industrial manufacturing, monitoring the temperature, napięcie, and other conditions of equipment in complex electromagnetic field environments can be achieved using fiber optic sensor systems, thereby ensuring the automation of industrial production processes and timely warning and maintenance needs for monitoring equipment usage status; In the field of energy, monitoring and ensuring the safe operation of facilities such as oil and gas pipelines and power transmission lines can be improved through fiber optic sensor systems; In terms of security and safety, fiber optic sensing systems can be deployed around the perimeter and key facilities (such as nuclear power facilities) to enhance defense and monitoring capabilities.

Supplementary Development Trends of Fiber Optic Sensor Systems

With the development of materials science, optical technology and other related fields, fiber optic sensor systems are moving towards higher sensitivity, większa dokładność, larger scale networking, and stronger adaptability to complex environments. New fiber optic materials are constantly being developed, which have advantages such as lower losses and higher optical performance, greatly improving the performance of fiber optic sensor systems in all aspects. Na przykład, the development of special optical fibers enables sensors to work accurately and stably in extremely harsh environments such as high temperatures and strong corrosion. In terms of multifunctional integration, future fiber optic sensor systems may not be limited to measuring a single physical quantity (such as temperature or strain). A sensor system can simultaneously detect multiple physical quantities and perform comprehensive analysis to obtain more useful information. This requires further development in corresponding technologies such as integrated optics and intelligent algorithms. In terms of large-scale networking applications, with the development of new generation communication technologies such as 5G and the Internet of Things, światłowodowe systemy czujników, as a monitoring method that can provide a large amount of raw data and has more advantages than traditional sensors, will play an increasingly important role in the construction of sensor networks for large-scale networking such as smart factories and smart cities in the future.

Comparison of various fiber optic sensor systems

 

1、 Comparison of Principle Characteristics

Fluorescent fiber optic temperature sensing system: With the help of fluorescent substances, the light characteristics of their fluorescence afterglow depend on temperature after being excited by specific light. The change in environmental temperature will cause a change in the decay mode of fluorescence afterglow, and temperature measurement can be achieved by detecting the length of fluorescence afterglow lifetime. This principle is based on the energy conversion and radiation characteristics between fluorescent substances and light, which is quite unique. Fiber optics mainly serve as channels for excitation light transmission and fluorescence transmission, and do not rely on the optical scattering or reflection phenomena of the fiber itself for sensing, unlike the other two systems. The sensitivity of the system under this principle can be adjusted according to the specific fluorescent substance selection and optimization algorithm, but in contrast, its response to temperature changes depends more on the inherent characteristics of the fluorescent substance, and the theoretical physical mechanism is directly related to the microscopic interaction between light and matter.
Distributed fiber optic sensing system: w pełni wykorzystując właściwości samego światłowodu jako medium ciągłego monitorowania, wykorzystujące nieliniowe efekty optyczne, takie jak rozpraszanie Ramana i rozpraszanie Brillouina w światłowodach. W ramach mechanizmu rozpraszania Ramana, Mierzy się różnicę w natężeniu światła rozproszonego wstecz pomiędzy pasmami Stokesa i anty-Stokesa w celu określenia temperatury w określonym miejscu włókna; Kiedy następuje rozproszenie Brillouina, opiera się na wpływie czynników zewnętrznych (takie jak temperatura i obciążenie) na długości fali wstecznie rozproszonej fali świetlnej, aby uchwycić wielkości fizyczne, takie jak naprężenie światłowodu. Zasada ta oparta na naturalnym zjawisku rozpraszania włókien optycznych umożliwia ciągłe i rozproszone monitorowanie wielkości fizycznych wzdłuż światłowodu bez konieczności dodawania do światłowodu dodatkowych substancji lub struktur czujnikowych. Zasada ta określa, że ​​jego monitorowanie jest metodą ciągłego pozyskiwania informacji rozprowadzanych wzdłuż światłowodu, i może mierzyć większe odległości. Jednakże, zasada fizyczna określa, że ​​na ogólną dokładność będą miały wpływ takie czynniki, jak słabe rozproszone sygnały i szum.
Fiber Bragg Grating Temperature Sensing System: Działa w oparciu o zasadę, że zmiany temperatury powodują zmianę długości fali Bragga światłowodowej siatki Bragga. Ta zmiana długości fali jest bardzo precyzyjna, and temperature changes can be perceived by measuring the wavelength or spectral changes of reflected light. The core component, włóknista siatka Bragga, is a periodic refractive index changing structure artificially manufactured in optical fibers. It is precisely this structure that produces specific reflection patterns for light and is significantly affected by temperature. The principle of wavelength modulation of light reflection based on specific optical structures enables sensors to have high accuracy and stability, and can be integrated with other optical systems to achieve higher sensitivity detection. Jednakże, due to the complexity and stability requirements of grating structure fabrication, the system may face certain application limitations in terms of large-scale production costs or harsh environments (where Bragg wavelength is affected by external factors and there is a risk of non temperature induced deviation).

2、 Comparison of structural complexity

Fluorescent fiber optic temperature sensing system: The structure is relatively simple. It mainly consists of three parts: sonda (multimode fiber and top fluorescent material), transmission fiber, and signal demodulator. Fluorescent substances exist solely at the top of the optical fiber, directly receiving excitation light from the transmission fiber and transmitting the excited fluorescence to the demodulator through the fiber. This type of device structure is relatively simple and functionally clear, with clear modularity between different parts and a simple and straightforward manufacturing process. Although it also involves integrating fluorescent substances and attaching them to fiber ends, the overall complexity is not high. The large-scale production process is relatively easy to control, has good compatibility, and can be flexibly combined with different probes for use. It is convenient to layout probes for measurement in various simple or complex environments.
Distributed fiber optic sensing system: structurally more complex. The system has built a multifunctional detection and analysis system around fiber optic networks. From the selection and laying of optical fibers themselves (considering the differences in fiber properties in different environments, including the use of ordinary communication optical cables and other resource utilization methods), to the distributed installation of numerous sensing and monitoring area positioning and analysis modules along the fiber optic cables. It not only includes basic signal generation and transmission, but also involves complex optical signal detection, optical wave signal demodulation and analysis under the influence of various physical quantities. Na przykład, optical path modules that require splitting and interference processing, as well as complex electronic signal processing parts that involve high-speed DSP processing and analysis of vibration signals to achieve precise positioning and event judgment, multiple functional modules in the entire network system work together to achieve distributed monitoring and analysis of various physical quantities such as temperature and strain over long distances across regions. Dlatego, the structural complexity is relatively high. Once a fault or performance degradation occurs in a certain link of this structure, the troubleshooting and repair process is relatively cumbersome, ale po pomyślnym zbudowaniu, może pełnić potężną funkcję monitorowania rozproszonego.
Fiber Bragg Grating Temperature Sensing System: Struktura jest średnio złożona. Rdzeń stanowi element siatki światłowodowej, a sama produkcja siatek światłowodowych wymaga specjalistycznych procesów, takich jak fotolitografia. Jednakże, w porównaniu z rozproszonymi światłowodowymi systemami detekcji, jego struktura jest stosunkowo prosta, ponieważ nie wymaga skomplikowanych mechanizmów wielopunktowego przetwarzania rozproszonego monitorowania. Jednakże, podczas tworzenia kompletnego systemu wykrywania temperatury, konieczna jest także współpraca ze źródłem światła oraz urządzeniami do przetwarzania i analizy światła odbitego (takich jak kamery CCD, procesory sygnałowe, oraz inny sprzęt używany do zbierania i przetwarzania zmian sygnału świetlnego w oparciu o odbicie siatki w celu uzyskania informacji o temperaturze). Ponadto, podczas budowy systemu kontroli temperatury, konieczne jest dodanie komponentów, takich jak moduły sterujące i siłowniki, aby uzyskać ogólne funkcje sterujące. Chociaż liczba komponentów nie jest tak duża, jak w przypadku rozproszonych światłowodowych systemów czujnikowych, ogólna struktura wymaga dokładnego dopasowania i współpracy pomiędzy elementami optycznymi związanymi z siatką Bragga i sterowaniem obwodami pomocniczymi, wykrywanie, i inne linki. Istnieją również pewne wymagania dotyczące złożoności podczas integracji systemu i debugowania.

3、 Porównanie wskaźników wydajności

Fluorescent fiber optic temperature sensing system:
Dokładność pomiaru: Dokładność pomiaru systemu można dostosować do różnych potrzeb, a powszechnie stosowany zakres dokładności obejmuje ± 0.05 ℃ – ± 1 ℃. Różne produkty, scenariusze zastosowań, itp. przyjmą różne poziomy dokładności, ale ogólnie, it can meet the needs of many industries and some special scenarios within a certain range. Jednakże, its accuracy still depends relatively on factors such as the stability of the fluorescent substance and the degree of optimization of the measurement algorithm. Compared with fiber Bragg grating sensors, there may be a gap of 1 in the high-precision field.
Zakres pomiarowy: The temperature measurement range is relatively wide, divided into four sections: -40 ℃ -+80 ℃- 40℃ – +250℃；- 40℃ – +400℃；+ 20 ℃ -+60 ℃ (medyczny), able to adapt to temperature range requirements from cold to high temperature, from ordinary civilian environments to special medical and health environments, and many other usage scenarios.
Skuteczność przeciwzakłóceniowa: Strong anti electromagnetic interference ability. Ze względu na izolację elektryczną samego światłowodu oraz fakt, że wewnętrzna luminescencja i zasada detekcji substancji fluorescencyjnych nie są związane z zakłóceniami elektromagnetycznymi, może nadal pracować stabilnie nawet w środowiskach wysokiego napięcia i złożonych pól elektromagnetycznych (takie jak monitorowanie temperatury sprzętu w pobliżu urządzeń wysokiego napięcia wewnątrz podstacji elektroenergetycznych). Naraz, Sonda światłowodowa może dostosować się do różnych środowisk korozyjnych, ponieważ nie powoduje korozji żadnych części metalowych. Ta zaleta przeciwzakłóceniowa sprawia również, że można go łatwo dostosować do różnych urządzeń elektrycznych, magnetyczny, i środowiska chemiczne, takich jak pomiar temperatury materiału w warsztatach chemicznych.
Distributed fiber optic sensing system:
Dokładność pomiaru: Pod względem dokładności, it is relatively limited due to its complex physical mechanisms such as Raman and Brillouin scattering, as well as various factors such as environmental noise and changes in fiber performance. In temperature measurement, although long-distance and large-scale monitoring can be achieved, the accuracy is relatively poor compared to specialized high-precision temperature sensors. Na przykład, in the safety monitoring of long-distance oil pipelines, the main requirement for temperature accuracy is to detect a large range of temperature anomalies, and the requirement for absolute accuracy of temperature numerical accuracy is not a necessary condition.
Zakres pomiarowy: It can have a large adaptability range in temperature and strain monitoring, but the specific values often depend on various factors such as the type of optical fiber, the light source used in the system, and the detection device. Na przykład, it can be used to monitor structural strain and temperature strain caused by relevant parameters in industrial environments ranging from room temperature to a certain high temperature or low temperature.
Skuteczność przeciwzakłóceniowa: The ability to resist electromagnetic interference is an important advantage, as it can work in strong electromagnetic field environments without interference. Naraz, optical fiber itself is a passive sensing and transmission medium, so it can work safely in some dangerous areas (such as underground coal mines for monitoring tunnel structures and temperature to prevent gas explosions and other hazards, without electrical risks such as electric sparks). Jednakże, relatively speaking, it is more sensitive to damage to the fiber itself or environmental interference (such as excessive stretching and bending of the fiber, large fluctuations in local environmental temperature along the fiber, and measurement effects on scattered signals). Although there are many methods in design to reduce this impact, stability remains a challenge in performance evaluation.

Fiber Bragg Grating Temperature Sensing System:

Dokładność pomiaru: It has high measurement accuracy, which is based on the principle of extremely precise temperature modulation of fiber Bragg grating wavelength. Na przykład, it can demonstrate its advantages in scenarios that require high precision, such as precision equipment and temperature monitoring of small areas within living organisms. It can achieve ultra-high sensitivity detection at sub millikelvin level, and provide accurate data in temperature monitoring of precision instruments and equipment, as well as detection scenarios where temperature changes are extremely subtle in the biomedical field.
Zakres pomiarowy: Although it can meet the needs in many scenarios, it poses significant challenges to the stability of optical materials and grating structures in extreme high or low temperature conditions, and its measurement range is not as wide as that of fluorescent fiber temperature sensing systems. Jednakże, special manufacturing and optimized design for different fiber Bragg gratings can partially expand the measurement range to meet the needs of more types of scenarios.
Skuteczność przeciwzakłóceniowa: Strong anti electromagnetic interference ability, due to its current not requiring external connection and stable optical reflection measurement principle, it is less affected by external electromagnetic interference. Capable of monitoring temperature stability in normal industrial environments, środowiska elektroniczne sprzętu medycznego, oraz niektóre środowiska badań podstawowych, w których współistnieje wiele urządzeń elektromagnetycznych. Jednakże, ze względu na jego stosunkowo bardziej precyzyjną konstrukcję, światłowodowe siatki Bragga mogą wpływać na jakość pomiarów w pewnych warunkach zewnętrznych (jak znaczące uderzenie fizyczne lub naprężenie, które może uszkodzić konstrukcję kraty). Jednakże, w normalnych okolicznościach, pod warunkiem uniknięcia oczywistego ryzyka szkód fizycznych, ogólna zdolność przeciwzakłóceniowa jest silna.

Światłowodowy czujnik temperatury, Inteligentny system monitorowania, Producent rozproszonych światłowodów w Chinach