Продукты
Решения
Инженерные услуги
Образование
Поддержка
Компания
Вход в систему
SEL-T400L
Обзор
Документация
Поддержка
SEL-T400L
Toggle Dropdown
Обзор
Документация
Поддержка
Документация
Рекомендуемые
Инструкция по эксплуатации
SEL-T400L Time Domain Line Protection
Лист технических данных
SEL-T400L Time-Domain Line Protection
Рекламный листок
SEL‑T400L: Защита линии, основанная на анализе сигналов во временной области
Литература о товаре
Документы отсортированы по новизне.
Показать публикации на английском языке
Литература о товаре
Информационные листы
SEL‑T400L: Защита линии, основанная на анализе сигналов во временной области
Листы технических данных
На английском языке
SEL-T400L Time-Domain Line Protection
Спецификации
На английском языке
SEL-T400L Time-Domain Line Protection
SEL-T400L Time-Domain Line Protection
Инструкции по эксплуатации
На английском языке
SEL-T400L Time Domain Line Protection
Шаблоны маркировки
На английском языке
SEL-T400L Custom Label Instructions
Related Material
SEL-T400L, SEL-T401L, and SEL-TWFL Custom Label Template (Letter)
SEL-T400L, SEL-T401L, and SEL-TWFL Custom Label Template (A4)
Файлы для скачивания
На английском языке
SEL-T400L DNP Device Profile Information
Публикации
Руководства по применению
На английском языке
Double-Ended Traveling-Wave Fault Locating Using the SEL RTAC as a DNP3 Client
Related Material
fb_TWFaultLocation.xml
Using an SEL RTAC to Integrate the SEL-T400L Relay With SCADA
Технические документы
На английском языке
Case Study: Traveling-Wave Fault Locating for an HVdc Transmission Line
Dependability of Transient-Based Line Protection Elements and Schemes
Energy and Power Measurements on a Nonsinusoidal 345 kV System Using Three-Phase Megahertz Time-Series Data
Megahertz-Sampled Observations of AC Level 2 Onboard Electric Vehicle Charging
Getting the Lines Crossed—How a Three-Phase Series Fault Caused a Sequence of Relay Operations
Evaluating Phasor-Based and Time-Domain Elements for Short Line Applications
Correlating Traveling-Wave Arrival Times to the Bewley Diagram—A New Systematic Approach for Offline Traveling-Wave Fault Locating
UHS Relay Testing for Optimal Protection of a Long 345 kV Line With Series Compensation
An Unlikely Pair? Combining Traveling Waves and Phasors for Reclosing on Hybrid Lines
Finding Faults Fast Saves Money and Improves Service
A Method for Evaluating Loadability of Incremental-Quantity Distance Elements
Evaluation of Ultra-High-Speed Line Protection, Traveling-Wave Fault Locating, and Circuit Breaker Reignition Detection on a 220 kV Line in the Kalahari Basin, Namibia
Traveling-Wave Overcurrent – A New Way to Protect Lines Terminated on Transformers
Double-Ended Traveling-Wave Fault Locating Without Relay-to-Relay Communications
Distance Protection: Why Have We Started With a Circle, Does It Matter, and What Else Is Out There?
Line Length and Fault Distance Considerations in Traveling-Wave Protection and Fault-Locating Applications
Circuit Breaker Ratings – A Primer for Protection Engineers
Preventing Line Faults With Continuous Monitoring Based on Current Traveling Waves
Locating Faults Before the Breaker Opens – Adaptive Autoreclosing Based on the Location of the Fault
Application of Ultra-High-Speed Protection and Traveling-Wave Fault Locating on a Hybrid Line
Improving Line Crew Dispatch Accuracy When Using Traveling-Wave Fault Locators
Practical Experience With Ultra-High-Speed Line Protective Relays
Mystery Solved: Five Surprises Discovered With Megahertz Sampling and Traveling-Wave Data Analysis
Field Experience With an Ultra-High-Speed Line Relay and Traveling-Wave Fault Locator
Traveling-Wave Fault Locating for Multiterminal and Hybrid Transmission Lines
Testing Traveling-Wave Line Protection and Fault Locators
Testing Superimposed-Component and Traveling-Wave Line Protection
Accurate and Economical Traveling-Wave Fault Locating Without Communications
Sharing Direct Fiber Channels Between Protection and Enterprise Applications Using Wavelength Division Multiplexing
Directional Elements – How Fast Can They Be?
Performance Comparison Between Mho Elements and Incremental Quantity-Based Distance Elements
Practical Setting Considerations for Protective Relays That Use Incremental Quantities and Traveling Waves
Defining and Measuring the Performance of Line Protective Relays
Performance of Time-Domain Line Protection Elements on Real-World Faults
Speed of Line Protection – Can We Break Free of Phasor Limitations?
Locating Faults by the Traveling Waves They Launch
Схемная документация
AutoCAD
На английском языке
i6353e Rear View
i9340d Dimensional View
i6352f Front View
PDF
На английском языке
i6352f Front View
i6353e Rear View
i9340d Dimensional View