Protection&Control Transmission Line Protection Busbar Protection Transformer Protection Circuit Breaker Protection Generator Protection Feeder Protection Capacitor Protection Motor Protection Transfer & Synchronization Arc Protection
Digital Substation PCS-221S Merging Unit PCS-221 Merging Unit PCS-222 Circuit Breaker Controller PCS-9250 AC Electronic CT/VT
Automation PCS-9700 Automation System PCS-9700 HMI Software PCS-9705 Bay Control Unit PCS-9705S Bay Control Unit PCS-9799 Station Manager PCS-9799S Station Manager PCS-9710 Remote Terminal Unit PCS-9710S Remote Terminal Unit PCS-9794 Protocol Converter PCS-9785 Satellite-Synchronized Clock PCS-9882 Ethernet Switch PCS-9882Rx DIN Rail Managed Ethernet Switch PCS-9882XD Managed Ethernet Switch PCS-9884 Managed Ethernet Switch Supporting HSR and PRP MUX-2M/64 Communication Interface
Phasor Measurement PCS-997S Fault Line Locator PCS-996S-G Phasor Data Concentrator PCS-996 Phasor Measurement Unit
Disturbance Fault Recording PCS-996RC Disturbance Fault Recorder PCS-996R Disturbance Fault Recorder PCS-986 Disturbance Fault Recorder PCS-9013 DFR Management System
Stability Control System PCS-992 Power Stability Control System PCS-993 Out-of-Step Controller PCS-994 Frequency & Voltage Controller PCS-994S Frequency and Voltage Controller
Power Grid Monitoring and Control PCS-9000 Energy Management System PCS-9000 Distribution Management System
Configuration Tool PCS-Torch MOT Tool PCS-Studio Configuration Tool PCS-Explorer IED Configuration & Debugging Tool PCS-SCD Configuration Tool PCS-COMM Configuration & Debugging Tool
Accessories MD1501 Series Auxiliary Relays MD1701 Series Test Blocks MD1701S Test Block
FACTS PCS-9580 Static Var Compensator PCS-9583 Static Synchronous Compensator PCS-9570 Series Compensation PCS-9590 DC De-Icer PCS-9578 Controllable Shunt Reactor PCS-8200 Unified Power Flow Controller PCS-9571 Fault Current Limiter PCS-9564A Dynamic Voltage Restorer PCS-9569 Shore Power System
HVDC PCS-8600 UHVDC Converter Valve System PCS-9550 LCC-HVDC Control and Protection System PCS-8100 VSC-HVDC IGBT Valve PCS-9520 VSC-HVDC Control and Protection System PCS-9510 Cooling System PCS-8300 High-voltage DC Circuit Breaker PCS-9250 DC Electronic CT/VT
PV & Wind Power Grid-Connection PCS-9700 Renewable Energy SCADA PCS-9726 Generation Management Unit PCS-9700F Power Forecast System PCS-9700R AGC/AVC
Battery Energy Storage System PCS-9567MV-10000 Medium Voltage Skid PCS-9567MV-7000 Medium Voltage Skid PCS-9567MV-5000 Medium Voltage Skid PCS-9567MV-3500 Medium Voltage Skid PCS-9567-2500 Twin Power Conversion Systems PCS-9567-2500 電力変換システム PCS-9567-1750 Power Conversion System PCS-9567-1750 電力変換システム PCS-9567 Power Conversion System Vulnerability Disclosure Policy パワーコンディショナー脆弱性開示ポリシー
Microgrid PCS-9617MG Microgrid Controller
Static Frequency Converter PCS-9575 Static Frequency Converter
Protection,Automation&Control DMS EMS Stability Control & WAMS Digital Substation
HVDC & FACTS De-Icing Unified Power Flow Controller (UPFC) Series Compensation Static Synchronous Compensator(STATCOM) Static Var Compensator (SVC) LCC-HVDC Transmission VSC-HVDC Transmission
Renewable & Microgrid Energy Storage System Microgrid PV Generation SFC
Power Generation Pumped Storage Power Plant Nuclear Power Plant Hydro Power Plant Thermal Power Plant
Transmission System AC Transmission LCC-HVDC Transmission VSC-HVDC Transmission
Distribution System Distribution Network
Industrial Consumer Urban Track Traffic Electrified Railway Oil & Petrochemical Metals & Mining
On June 17, the Ejina wide area large grid with high penetrated renewable energy power system of Inner Mongolia Power Grid was formally formed when the 220 kV Tai'e line zero power flow was disconnected. The off grid system was connected to the main grid, on June 19 after 49 hours of safe and stable operation. This experiment fully verified that NR grid-forming energy storage technology can play the role of traditional synchronous generator voltage source support, and has the ability to build a 100% renewable energy regional power grid.
In the first phase of the test on May 26th, the Ejina regional power grid successfully conducted the first 100% renewable energy black start test in a wide area grid environment across three voltage levels of 110 kV, 35 kV, and 10 kV. During the black start process, 30 grid supported energy storage PCSs operated in parallel and stably, enduring harsh operating conditions such as single circuit 110 kV line energizing and 20 MVA main transformer energizing without load.

Ejina is a vast territory and a total area of 114,600 square kilometers. The power supply scope covers about 490 kilometers from east to west and 324 kilometers from north to south in Ejina. The total length of transmission lines in the region is 950 kilometers, and the largest load scale in history is 75 MW. The installed capacity of wind and solar power reaches 110MW. The regional power grid is only connected to the main grid through a 440 kilometer single circuit long chain 220 kV line, without conventional synchronous voltage source support. Once the 220 kV transmission line is repaired or trips due to faults, it will cause the entire regional power grid to lose power.
NR provided Ejina grid with the innovating grid-forming technology as the core, proposing an integrated solution for source, grid, load, and storage. It provides 30 sets of equipment with a total capacity of 25 MW/25 MWh grid-forming energy storage, stability control, coordination control, and energy management system, fully realizing the flexible and optimal control of regional grid source, grid, load, and storage integration.
The Ejina regional power grid has experienced a high proportion of 94.94% of renewable energy operation tests for 49 consecutive hours, with 100% of renewable energy and 100% of power electronic equipment operating for 22 consecutive hours. During this period, it also experienced severe tests such as 10 kV line grounding faults, large load bidirectional large range fluctuations with a range exceeding 30% of the total load power, and wind power high wind speed shutdown. The grid keeps continuous and stable, and the user's power supply is completely normal.
This experiment has proven the high feasibility of the integrated solution of source, grid, load, and storage based on grid-forming technology by NR. It can meet the requirements of adverse operating conditions such as bidirectional random fluctuations of renewable energy and load, high load power supply of renewable energy, extreme heat and no wind, and no light at night peak. It can achieve rapid recovery of frequency and voltage in transient situations and precise control of frequency and voltage in steady-state situations. At the same time, the strong adaptability of grid supported energy storage to multiple operating modes and complex operating conditions under wide coverage and large renewable energy startup conditions was verified.
The integrated solution of source, grid, load, and storage adopted in this project can be effectively promoted and applied to application scenarios such as 100% off grid operation of renewable energy, green power development and utilization of enterprise power grids, and load guarantee of terminal power grids. The core grid-forming technology, NR has already applied for energy storage, flexible DC transmission, and static synchronous condenser. These applications can better support the construction of multiple application scenarios such as 100% renewable energy with energy storage through ultra-high voltage DC transmission. The successful practice of this project provides an innovative model for the construction of a new type of power system.
NR will continue to focus on new demands and problems in the development of the power system, continue to carry out technological innovation, and contribute new ideas and solutions to the construction of the new generation power system.
