● Specifically designed for the application scenarios of energy storage EMS, the chip selection is tailored to be compatible with the EMS systems of various manufacturers.
● It monitors the operation status of each link in the energy storage system in real time and collects data from sensors and devices.
● The data is monitored and stored in real time for subsequent analysis, enabling the safe and optimized dispatch of energy.
● It is equipped with a rich variety of peripheral interfaces, which comply with the latest industry standards of the energy storage sector.
This Energy Storage Energy Management System (EMS) solution is compatible with container and distributed energy storage systems. It supports multiple protocols, ensures a stable connection, and enables integrated management. It can monitor devices in real time, has NPU computing power, complies with Australian standards, and helps with the efficient management and control of energy.
It supports the access and aggregation of information from various components of the container energy storage system or the distributed energy storage cabinet system, enabling local display, local monitoring, and energy management.
It connects various sensors such as temperature and humidity sensors, gas sensors, and electricity meters through RS-485. It connects to the battery BMS through the CAN port and to the PCS through the network port, achieving integrated management of the energy storage system.
Using aviation interfaces, it has good connection stability and can be applied in industrial scenarios.
It supports protocols such as Modbus TCP, Modbus RTU, and MQTT, and enables quick connection to various sensors and cloud platforms.
● Interfaces: Network port, CAN, RS485, DI (Digital Input), DO (Digital Output), AI (Analog Input), USB, etc.
● Supports GPS (Global Positioning System), BeiDou Navigation Satellite System, and Galileo satellite navigation system.
● Supports hardware watchdog.
● It supports 8-channel bus interfaces, RS-485 and Can protocols, and is compatible with both 5V and 12V power supplies.
● Installation methods: Rail-mounted installation, wall-mounted installation, and installation in a standard 19-inch rack.
● It supports the hardware watchdog function.
● Over 100 professionals with extensive IoT expertise.
● Efficient collaboration between R&D and production.
● Core algorithms and high versatility in industry-specific chip integration.
● Stable and reliable solutions reducing project R&D risks.
● Streamlined design, manufacturing, and quality control. Shortened time-to-market and reduced development costs.
● 30 wave soldering lines, 8 testing lines, and 10 finished product assembly lines. Daily production capacity of 10,000 units.
● MES digital management system with unique QR code for each product.
● Long-term partnerships with multiple mainstream chip manufacturers.
● Keeping abreast of technological advancements.
● Mature production lines ensuring fast and stable delivery.
● Lead times: 4 weeks for small batches (≤1,000 units), 2 weeks for baseline products (≤50 units).
● Certified to ISO14001:2015, ISO9001:2015, IATF16949:2016, and ISO45001:2018.
● Product testing includes DQA testing and laboratory certification.
● Utilization of quality management tools: FMEA, PPAP, ECN, SPC/CPK.
EMS controllers usually incorporate high-performance processors, such as those from the RK series. These processors can provide powerful computing capabilities and energy efficiency, meeting the requirements of EMS controllers for real-time data processing and complex control algorithms.
The commonly used operating systems for EMS controllers include Ubuntu and Linux. These systems are favored for their stability and extensive software support, which can ensure the stable operation and easy management of EMS controllers.
EMS controllers are usually equipped with sufficient memory and storage space to meet the requirements of their high-performance processing and data storage. For example, common configurations include 8GB or 16GB of RAM, as well as 32GB of FLASH or eMMC storage.
The EMS controller supports a variety of communication interfaces to meet the connection requirements of different devices and systems. Common communication interfaces include CAN, RS485, USB, HDMI, etc. These interfaces enable the EMS controller to efficiently exchange data and communicate with other devices.
EMS controllers usually adopt a sturdy metal casing and an effective heat dissipation design to enhance their durability and stability in harsh environments. In addition, some controllers are also equipped with features such as a hardware watchdog to further improve the reliability of the system. Meanwhile, the operating temperature range of the controller is usually quite wide to adapt to various extreme climatic conditions.
The EMS controller usually supports the functions of data collection and the issuance of control commands. By being equipped with a high-performance processor and a variety of communication interfaces, the EMS controller can collect various data in real time and issue control commands as required, enabling automated and intelligent management.
Suitable for medium and large-sized robots, such as charging robots, cleaning robots, AGV (Automated Guided Vehicle)/AMR (Autonomous Mobile Robot), etc.
It is compatible with container and distributed energy storage systems. It supports multiple protocols, ensures a stable connection, and enables integrated management.
Supports Wi-Fi and BLE (Bluetooth Low Energy) protocols, enabling docking with in-vehicle IoT wireless devices. It is compact in appearance and can be installed in a concealed manner.
Through a rich variety of interfaces, it connects various intelligent sensors and controllers in the scenarios of oil depot management.