INNO 光ファイバー温度センサー ,温度監視システム.
- Dry-type transformer temperature monitoring systems utilize fluorescence fiber optic sensing technology for precise winding temperature measurement
- Fluorescence fiber optic measurement principle based on rare earth phosphor material afterglow lifetime relationship with temperature variations
- System completely resolves temperature monitoring challenges in high voltage and strong electromagnetic interference environments
- Intrinsically safe design suitable for all voltage level transformer temperature protection and monitoring applications
- Multi-channel fiber optic temperature sensor configuration supports comprehensive monitoring of transformer critical components
- Professional solutions meeting stringent power industry environmental and safety requirements
目次
- Dry-Type Transformer Monitoring Technology & Fluorescence Fiber Advantages
- Fluorescence Fiber Temperature Sensor Measurement Principles
- Fluorescence Temperature Sensor Technical Specifications
- Fiber Optic Sensor Structural Design & インストール
- Transformer Temperature Monitoring System Functions
- High Voltage Environment Fluorescence Fiber Monitoring Advantages
- Dry-Type Transformer Temperature Monitoring Solutions
- Temperature Monitoring System Deployment & Technical Services
- Fluorescence Fiber Temperature Sensor Technical FAQ
- Professional Technical Consultation & Custom Temperature Monitoring Solutions
Dry-Type 変圧器の温度監視 テクノロジー & 蛍光ファイバー 利点
Dry-type transformer temperature monitoring plays a crucial role in ensuring power system safety and reliability. Transformer winding temperature serves as a critical parameter reflecting equipment operational status. Accurate temperature monitoring effectively prevents equipment failures and extends transformer service life.
1.1 Traditional Temperature Sensors vs Fluorescence Fiber Optic Sensors Technology Comparison
| Comparison Criteria | Traditional Electronic Temperature Sensors | 蛍光ファイバー光温度センサー |
|---|---|---|
| 測定原理 | Resistance/thermoelectric potential changes | Fluorescence afterglow lifetime variations |
| 電磁妨害 | Susceptible to strong electromagnetic fields | 電磁干渉に対する完全な耐性 |
| Insulation Safety | Risk of insulation breakdown | 本質安全防爆, no breakdown risk |
| 測定精度 | 環境に大きく影響される | 高精度, 長期安定性 |
| インストールの複雑さ | Requires shielding and insulation measures | 簡単な取り付け, no special requirements |
| メンテナンス要件 | Regular calibration and maintenance needed | メンテナンスフリー, 25+ 年の寿命 |
| 応答速度 | Relatively slow response | Rapid temperature change response |
| 動作環境 | Limited by high voltage environments | Suitable for all harsh environments |
| Cost Investment | 初期費用が安い, high maintenance cost | One-time investment, long-term maintenance-free |
1.2 蛍光ファイバー温度センサー Advantages in 変圧器の監視
Fluorescence fiber optic temperature sensing technology is specifically designed for high voltage equipment monitoring, perfectly resolving technical bottlenecks of traditional temperature sensors in transformer applications, providing ideal solutions for dry-type transformer temperature monitoring.
Fluorescence Fiber Temperature Sensor Measurement Principles & 技術的特徴
2.1 Fluorescence Temperature Measurement Basic Operating Principle
Fluorescence fiber optic temperature measurement technology is based on temperature-sensitive characteristics of rare earth fluorescent materials. Excitation light transmits through optical fiber to the temperature sensing probe, exciting fluorescent material luminescence. 励起光が止まると, fluorescent material produces afterglow decay phenomenon, with decay time maintaining strict functional relationship with temperature.
2.2 Temperature and Fluorescence Afterglow Lifetime Relationship
蛍光体の残光減衰時間は温度変化とともに指数関数的に変化します. 気温が上がると, 蛍光寿命が短くなる; 気温が下がると, 蛍光寿命が延びる. 蛍光減衰時間曲線の正確な測定による, 測定点のリアルタイム温度を正確に計算できます.
2.3 光信号処理と温度計算
温度監視システムは、蛍光減衰信号のサンプリングと分析に高精度の時間デジタル変換技術を採用しています。. 高度なデジタル信号処理アルゴリズムにより、測定精度と長期安定性が保証されます。, 変圧器巻線温度の正確な監視を実現.
蛍光温度センサー 技術的パラメータ & パフォーマンス指標
| 技術的パラメータ | 仕様値 | アプリケーションの説明 |
|---|---|---|
| 動作環境温度 | -20℃~+55℃ | 機器の使用環境温度の監視 |
| Environmental Humidity Range | ≤95% (25℃) | Relative humidity adaptation capability |
| System Supply Voltage | AC220V (+10%, -15%) | Standard AC power supply |
| Power Operating Frequency | 50Hz/60Hz (±2Hz) | Grid frequency adaptation range |
| 温度測定範囲 | -30.0°C ~ 240.0°C | Covers all transformer operating conditions |
| Measurement System Accuracy | ±1%FS (Class B sensor) | High-precision temperature monitoring |
| Temperature Display Resolution | 0.1℃ | Fine temperature display |
| センサープローブの直径 | ≤3mm | Small size flexible installation |
| Control Output Capacity | 5A/250VAC | Alarm control output capability |
| System Power Consumption | ≤8W | Low power energy-efficient design |
光ファイバーセンサー Structural Design & インストール構成
4.1 Sensor Modular Structural Design
Fluorescence fiber optic temperature sensors employ modular design, including fiber transmission units, fluorescence temperature sensing probes, and protection devices. Sensor structure is compact, adapting to complex installation environments inside transformers, ensuring reliable temperature monitoring performance.
4.2 光ファイバー 繋がり & Protection Technology
Systems utilize standard ST-type fiber optic connectors, ensuring optical connection stability. Special material fiber protective sheaths feature high-temperature resistance and anti-aging performance. Temperature sensing probes include protective sleeves preventing physical damage during installation and operation.
変圧器の温度監視 システム機能 & アプリケーション
5.1 マルチチャンネル 温度センサー Monitoring Functions
Temperature monitoring systems support multiple fluorescence fiber optic sensors operating simultaneously, achieving synchronous temperature monitoring of multiple critical transformer components. Each sensor channel operates independently, ensuring accurate and reliable monitoring data.
5.2 Real-Time Temperature Data 取得 & Processing
Systems feature high-speed data acquisition capabilities, real-time tracking of transformer winding temperature changes. Rapid response characteristics promptly reflect load change impacts on temperature, providing accurate data support for transformer operational status assessment.
5.3 Temperature Limit Alarm & Protection Mechanisms
Built-in multi-level temperature protection functions immediately activate protective measures when monitored temperatures exceed set thresholds. Alarm functions include audio-visual alerts, remote signal transmission, and automatic control outputs, ensuring transformer safe operation.
High Voltage Environment Fluorescence Fiber Temperature Monitoring Technology Advantages
6.1 Complete Electrical Isolation Safety Protection
Fluorescence fiber optic sensors utilize insulating materials, achieving complete electrical isolation from measured equipment. Even in ultra-high voltage environments, no insulation breakdown risk exists, ensuring personnel and equipment safety.
6.2 Superior Electromagnetic Interference Immunity Performance
Optical measurement principles make temperature monitoring systems naturally immune to electromagnetic interference. Strong electromagnetic fields generated during transformer operation have no impact on measurement results, ensuring authentic and accurate temperature data.
6.3 Intrinsically Safe Explosion-Proof Design Characteristics
Systems contain no spark-generating components, meeting intrinsically safe explosion-proof requirements. Completely safe for use in flammable and explosive environments, satisfying strict power industry safety standards.
6.4 Long-Term Stable Maintenance-Free Operation
Fiber optic temperature sensors feature simple structures with no moving parts, service life exceeding 25 年. System operation remains stable with extremely low maintenance requirements, significantly reducing operational maintenance costs.
Dry-Type 変圧器の温度監視 ソリューション
7.1 Scientific Monitoring Point Layout Strategy
Based on dry-type transformer structural characteristics and hotspot distribution patterns, develop temperature monitoring point layout schemes. Focus monitoring on transformer winding high-temperature zones and critical components, comprehensively understanding transformer thermal status.
7.2 マルチチャンネル 温度センサー Configuration Schemes
Systems support multi-channel fluorescence fiber optic sensor configurations, determining monitoring point quantities based on transformer capacity and importance levels. Each phase winding includes independent temperature monitoring channels, achieving phase-separated monitoring and protection functions.
7.3 監視システム 統合 & コミュニケーション
Temperature monitoring systems integrate with transformer protection devices and SCADA systems, achieving data sharing and coordinated control. Support multiple communication protocols, facilitating integration with existing power automation systems.
温度監視システム Deployment Implementation & Technical Services
8.1 Professional Installation and Commissioning Services
System installation requires professional technician operation, strictly following process requirements. Includes sensor calibration, communication testing, and functional verification, ensuring system reliability after commissioning.
8.2 User Training & メンテナンスサポート
Provides complete technical documentation and operation manuals, offering professional user training. Establishes regular inspection and maintenance schedules, ensuring long-term stable operation of temperature monitoring systems.
Fluorescence Fiber Temperature Sensor Common Technical FAQ
What is the service life of fluorescence fiber optic sensors?
Fluorescence fiber optic temperature sensors utilize inorganic fluorescent materials and quartz optical fibers, featuring excellent long-term stability. Under normal operating conditions, sensor service life exceeds 25 年, requiring no replacement or calibration during this period, achieving truly maintenance-free operation.
What temperature range does the system operate within?
Fluorescence fiber optic temperature monitoring systems measure temperatures from -30°C to 240°C, completely covering dry-type transformer normal operating temperatures and overload conditions. Systems maintain high-precision measurements throughout the entire temperature range, satisfying various application requirements.
How is measurement accuracy and stability ensured?
Systems employ advanced digital signal processing technology and temperature compensation algorithms, ensuring measurement accuracy remains unaffected by environmental factors. Fluorescence decay time measurements utilize high-precision time-to-digital conversion technology with nanosecond-level measurement resolution, guaranteeing high accuracy and long-term stability.
What happens when fiber optic cables break?
When fiber optic cables experience breaks or loose connections, systems immediately detect optical signal anomalies and issue fault alarms. Monitoring software accurately identifies fault types and locations, facilitating rapid positioning and resolution. Systems feature self-diagnostic functions, distinguishing between sensor faults and fiber optic faults.
What communication interfaces does the system support?
Temperature monitoring systems include multiple communication interfaces, including RS485, イーサネット, Modbus, and other standard protocols. Support local display and remote monitoring functions, seamlessly integrating with SCADA systems and DCS systems, achieving data sharing and remote management.
Professional Technical Consultation & カスタム 温度監視ソリューション
We possess professional technical teams and extensive project experience, providing comprehensive technical support and solution services for customers. From solution design to system commissioning, from personnel training to after-sales maintenance, we provide professional and timely technical support.
Based on customer specific requirements and site conditions, we provide customized temperature monitoring solutions. Fully considering transformer models, installation environments, 監視要件, およびその他の要因, we design optimal sensor configurations and system architectures. Free technical consultation services include solution feasibility analysis, technical parameter confirmation, and cost-benefit evaluation.
Southeast Asian Market Applications & ケーススタディ
Our fluorescence fiber optic temperature monitoring systems have been successfully deployed across Southeast Asian power utilities and industrial facilities. で タイ, major power generation companies have implemented our solutions for critical 115kV and 230kV dry-type transformer monitoring, 達成する 99.9% system reliability and zero false alarms over 3+ 稼働年数.
Malaysia’s leading palm oil processing facilities utilize our temperature sensing technology for monitoring high-capacity distribution transformers in harsh tropical environments. The intrinsically safe design and electromagnetic immunity have proven essential for operations in electrically noisy industrial settings with ambient temperatures exceeding 45°C.
で シンガポール, data center operators have standardized on our fluorescence fiber monitoring systems for mission-critical transformer temperature surveillance. メンテナンスフリーの運用と、 25+ 年間の耐用年数は、施設の稼働時間要件および総所有コストの目標と完全に一致します。.
インドネシアの 地熱発電所では、高湿度での変圧器監視に当社のソリューションが採用されています, 従来の電子センサーが数か月以内に故障する腐食環境. 当社の光学技術は、次のような環境でも確実に動作し続けます。 95%+ 二酸化硫黄にさらされる湿度条件.
フィリピン 電力会社は、島内の電力網ネットワーク全体に当社のシステムを導入しています。, リモート監視機能と最小限のメンテナンス要件が運用効率にとって重要な場合. 長距離光ファイバー通信により、本土の管制センターから集中監視が可能.
信頼性の高い乾式変圧器温度監視ソリューションをお探しの場合, 当社の技術専門家にお問い合わせください. We will provide the most suitable fluorescence fiber optic temperature sensor products and services based on your specific requirements, ensuring safe and stable transformer operation. Contact us immediately for professional technical solutions and quotation information.
光ファイバー温度センサー, インテリジェント監視システム, 中国の分散型光ファイバーメーカー
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