Industrial And Commercial Energy Storage Systems
The Main Purpose Of The Industrial And Commercial Energy Storage System Is To Utilize The Peak And Valley Price Difference And Demand Management Of The Power Grid To Achieve Return On Investment On The Premise Of Meeting The Company'S Requirements For The Quantity And Quality Of Electric Energy.
Industrial And Commercial Energy Storage Systems Are Suitable For Industrial And Commercial Situations With High Grid Continuity. They Can Communication Energy Storage, Grid Frequency Modulation Energy Storage, microgrid Energy Storage, Large-Scale Industrial And Commercial Distributed Energy Storage, Data Center Energy Storage, and New Energy. Field Photovoltaic Power Generation Business, Etc.
Air Cooling Container Energy Storage System
The air-cooled container adopts modular design, standardization, high integration, and more comprehensive functions. It is an integrated container that can be quickly installed and deployed. It is compatible with 1000V and 1500V DC systems, can match the power requirements of different projects, has high product production efficiency, and is easy to install and maintain. The module side air intake design has high heat dissipation efficiency and a small temperature difference. The temperature difference of a single box is ≤3°C and the temperature difference of a single cluster is <8°C. It can be equipped with battery cluster-level or plug-in box-level fire protection and is equipped with a thermal runaway detector to pre-alarm thermal runaway in advance and realize point-to-point fire extinguishing.
It provides a cost-effective way to store excess energy generated by renewable energy sources such as wind and solar power plants. BESS systems can provide backup power during power outages or extreme weather events, reducing the need for expensive distribution system upgrades or emergency generators. They can not only integrate renewable energy more smoothly but also help balance power supply and demand.
We have long been focusing on the research, development, production and sales of new energy power equipment such as solar energy and energy storage. We have developed more than 20 series of photovoltaic inverter products for grid connection and energy storage, covering full power, and are committed to providing overall solutions such as smart energy management for households, industrial and commercial users and ground power stations.
With a collaborative model of each case, we complete customized solutions from initial demand analysis to system integration design and effectively provide customized solutions with both technical reliability and economic rationality for various working conditions. The modular system configuration is used to flexibly match various industrial and commercial scenarios, while supporting multi-mode operation, which improves investment returns, can achieve peak-valley time shifting, and peak-shifting electricity consumption, and relieves grid pressure.
The turnkey set delivery fully covers the entire process of design and development, production and manufacturing, operation and joint commissioning, and operation and maintenance management, truly realizing overall delivery and worry-free acceptance.
-Energy Storage Cabinet Access Schematic
-PV System Design
1, PV System requirement
Daily power needed: 800KWh
2, Overall design
2.1 Solar photovoltaic power generation systems are mainly composed of photovoltaic modules, lightning protection
combiner boxes, AC/DC distribution cabinets, photovoltaic inverters, photovoltaic mounting structures, cables, and
other components.
2.2 The system is designed and installed with 350 polycrystalline silicon photovoltaic modules, each with a power of
545W. The system inverter, which is from a well-known brand, converts the direct current (DC) generated by the
photovoltaic modules into 220V alternating current (AC), which is then stored in the BESS (Battery Energy Storage
System) battery cabinet system.
2.3 Daily output:
PV Capacity: 350pcs x 545W =190.7KW
Daily Valid sunlight: 4-5 Hours
System Loss Coefficient: 85%
Total output: 190.7kw x 4-5 hours x 85% =648 to 810 kWh
Mechanical Characteristics
| Cell Type |
P type Mono-crystalline |
| No. of cells |
144 (6×24) |
| Dimensions |
2274×1134×35mm (89.53×44.65×1.38 inch) |
| Weight |
28.9 kg (63.7 lbs) |
| Front Glass |
3.2mm,Anti-Reflection Coating,
High Transmission, Low Iron, Tempered Glass |
| Frame |
Anodized Aluminium Alloy |
| Junction Box |
IP68 Rated |
| Protection Class |
Class II |
| IEC Fire Type |
Class C |
| Connector Type |
JK03M/MC4/Others |
| Output Cables |
TUV 1×4.0mm2 (+): 400mm, (-): 200mm or Customized Length |
| Initial Configuration |
| No. |
Item |
Model |
Qty |
Remark |
| 1 |
Battery Cabinets |
215kwh |
4 |
|
| 2 |
Converging Cabinets |
400kwh |
1 |
|
| 3 |
PCS |
Include |
4 |
|
| 4 |
RMU |
Include |
1 |
|
-Liquid Cooling System Design
| C-rate |
0.5C |
| Temperature Range |
-20ºC - 55ºC |
| PACK Nominal Voltage |
748.8V |
| DC Side Battery Capacity @ BOL |
215KWH |
| Configuration |
280Ah, 1P26S*9 |
| Weight (t) |
≈2500KG |
| Dimension (W*H*D mm) |
1300*1300*2100mm |
| Rated charge discharge power (kW) |
100KW |
| Auxiliary power |
AC400V±15% 50/60Hz |
| Relative humidity |
0-95% (non-condensing) |
| Protection level |
IP54 |
| Anti-corrosion level |
C3 |
| Fire Suppression System |
Water fire protection |
| Perfluorohexanone |
Communications interface Ethernet |
| Communication protocol |
Modbus TCP/IP |
Degradation-SOH
Degradation-RTE
Single Line Diagram Design
-System Configuration Unit And Specification Design
Specifications
| No. |
Item |
Specification |
Qty |
Unit |
Remark |
| 1 |
Liquid Cooled Container |
210kWh |
4 |
pcs |
1300*1300*2100mm |
| 2 |
Battery Cells |
3.2V |
936 |
pcs |
LFP 300Ah |
| 3 |
Battery Module |
Liquid Cooling /IP54 |
36 |
pcs |
1P26S |
| 4 |
Battery Cluster |
1P234S,748.8V,280Ah |
4 |
pcs |
1P234S |
| 5 |
High Voltage Box/Switch Box |
Liquid cooling high-voltage box |
4 |
pcs |
|
| 6 |
BMS |
Three-stage structure |
1 |
pcs |
|
| 7 |
BMU |
Control unit |
36 |
pcs |
|
| 8 |
BCU |
Main control unit |
9 |
pcs |
installed in thehigh-voltagebox |
| 9 |
SCU |
Master control unit |
1 |
pcs |
installed in the Combiner Box |
| 10 |
DC Combiner Box |
|
1 |
pcs |
|
| 11 |
Industrial Liquid Cooling Units |
liquid cooling uni |
1 |
pcs |
|
| 12 |
Fire Suppression System and Alarm Sys |
tem Perfluorohexanone and Sprinker System |
1 |
pcs |
|
| 13 |
Video Surveillance System |
Electrical cabin monitoring |
1 |
pcs |
|
Battery Cell
The battery cell adopts the standard 280Ah lithium phosphate prismatic battery produced by a fully automated production line. This battery has high sustainable power, high cycle life, high storage life, and high safety.
| No. |
Performance index |
Parameter |
Remarks |
| 1 |
Battery type |
LFP |
|
| 2 |
Nominal voltage |
3. 2V |
|
| 3 |
Nominal capacity |
280Ah |
|
| 4 |
Nominal Energy |
896 Wh |
|
| 5 |
Minimum Voltage |
2. 8V |
|
| 6 |
laximum Voltage |
3. 6V |
|
| 7 |
Storage Tenperature Range |
-40~60ºC |
|
| 8 |
Operating Terperature Range |
-30~60ºC |
|
Module
The battery pack adopts an intelligent liquid cooling temperature control system which includes a liquid cooling unit, pipeline system, and liquid cooling plate structure in each battery module. The pipeline system is composed of primary, secondary, and tertiary pipelines and control valve groups to achieve a balanced distribution of liquid cooling medium.
Every single battery pack of this project uses the standard liquid cooling box, which adopts a pressure-die-casting structure integrating the battery case together with the liquid cooling plate to achieve compactness. Meanwhile, the design also ensures that the coolant is physically isolated from the battery, eliminating the risk of coolant leakage into the battery pack, and improving the safety and reliability of the system.
| No. |
Performance index |
Parameter |
| 1 |
Configuration |
1P26S |
| 2 |
Nominal voltage (V) |
83.2V |
| 3 |
Minimum working voltage |
72.8V |
| 4 |
Maximumworking voltage |
93.6V |
| 5 |
Nominal capacity |
280Ah |
| 6 |
Nominal Power |
23.296kWh |
| 7 |
Dimension (W*D*H) |
810*1145*238mm |
| 8 |
Weight |
200kg |
Battery Cluster
The battery cluster adopts a frame structure, and the battery pack and high-voltage box are fixed by screws and locking rails. Each cluster contains 9 packs and 1 high-voltage box, the packs and high. voltage boxes are arranged sequentially in the battery cabinet and each cluster consists of 1 battery cabinet. The packs in each battery cluster are connected in series, and waterproof quick-connect fittings are used between the packs and the high. voltage box to ensure the reliability of the connection.
| 1 |
General Characteristics |
| 2 |
Configuration |
1P2345 |
| 3 |
Nominal voltage(V) |
748.8V |
| 4 |
Minimum working voltage |
655.2V |
| 5 |
Maximum workingvoltage |
842.4V |
| 6 |
Nominal capadity |
280Ah |
| 7 |
Nominal Power |
210Kwh |
| 8 |
System Characteristics |
| 9 |
Dimension(WD*H) |
810*1145*2100MM |
| 10 |
Weight |
1800kg |
| 11 |
Thermal Management Features |
| 12 |
Cooling Method |
Liquid Cooling |
BMS System
The protection and monitoring functions of the battery system are realized by the Battery management system (BMS), which is adopted with a three-level network architecture:
BMU (module level, built into the module):
Monitors the voltage and temperature of a single cell, and the total voltage of a single pack, and through CAN protocol, the above information is transmitted to the upper-level BlS in real-time, which can control the voltage balance of the single cell.
BCU (rack-level, built-in high voltage box):
Detects the total voltage and current of the cluster batteries, passes through the protocol, and transmits the above information to the upper-layer BNS in real time. it can display the capacity, health status power of the battery when charging and discharging, and the power prediction and calculation of internal resistance
SCU (system-level):
Collects lower-level BCU information to monitor battery remaining capacity and health status forecast in real-time. Communicates with the upper and external systems via RS-485 or Modbus-TCP/P.
Liquid Cooling Cabinet
The overall structure of a single battery pack is shown in the following Figure. The liquid cooling flow passage is integrated into the bottom plate of the box, which not only reduces the height of the whole pack but also realizes the dry and wet separation between the coolant and the battery cell, ensuring the safety of the system.
A single battery cluster consists of 9 battery packs stacked on the rack from bottom to top, as shown in the Figure below. There are 44 x 9=396 battery cells. The liquid cooling pipelines between the nine battery packs are all in parallel, so that the water temperature at the inlet of all battery packs is consistent, which is conducive to reducing the temperature difference inside clusters. The container-level thermal management system is shown in the following Figure. The liquid cooling flow passages for all battery packs are connected in parallel. The system uses customized refrigeration units. The total flow is evenly distributed to each battery pack to meet the heat dissipation requirements of the battery pack.
Thermal Management System
Adopting scientific fluid design, in the liquid cooling panel, piping, and mainframe system, have carried out a targeted design to ensure that the container's internal ambient temperature is controlled at 15 °c -35 °c, and the temperature difference is not more than 5 °c.
| No. |
Performance index |
Parameter |
| 1 |
System internal ambient temperature |
15 ~ 30ºC |
| 2 |
Average temperature of electric core |
15 ~ 45ºC |
| 3 |
Average temperature |
≤5ºC |
| 4 |
Difference Heating function |
Yes |
| 6 |
Air conditioning type |
Liquid-cooling |
| 7 |
Air conditioning nominal power |
10kW |
Pack Level Fire Suppression System
The battery container system adopts battery module level immersion protection automatic explosion-proof exhaust device + Novec1230 automatic fire extinguishing system + water sprinkler multiple progressive fire extinguishing protection system. The system includes an early warning device, an automatic fire extinguishing device, an exhaust device, and a fire sprinkler device. The alarm or air exchange function is started by detecting fire information and combustible gas concentration through an early warning device and, at the same time, automatically starts the fire extinguishing device to extinguish the fire completely after triggering the spraying conditions.
The whole process of battery container system safety prevention and control is divided into three levels of protection, as follows:
•In the first stage of protection, the thermal runaway of the battery is mainly suppressed in the battery module. In this stage, the possible malrunaway can be effectively suppressed in the early stage through the real-time monitoring of the cell level temperature and the submerged fire extinguishing function of the battery module. This protection level has high fire suppression reliability, and the protection efficiency can reach more than
90%.
•In the second stage of protection, when the fire fails to be effectively controlled by the first-level protection, the thermal runaway spreads to the container. The temperature sensor, smoke sensor, and combustible gas detector in the container will automatically start fire-fighting functions such as explosion-proof exhaust ventilation or gas injection fire extinguishing (with clean extinguishing agent Novec 1230) according to the detection situation. The fire extinguishing process can minimize secondary losses.
•In the third stage of protection, when the second-level protection function fails to control the fire in the container, the water sprinkler system is started
and the full coverage sprinkler is carried out in the container to ensure that the thermal runaway in the battery container is controlled and does not spread
1. Are You The Manufacturer Or Trader?
We Are A Leading Professional Manufacturer
2. How Could I Get A Sample?
Before We Received The First Order, Please Afford The Sample Cost And Express Fee. We Will Return The Sample Cost Back To You Within Your First Order.
3. Do You Accept OEM And ODM?
Yes. Our R&D Team Owns the Latest Technology and can Develop And Produce Products According To Customers' Design And Their Brand.
4. How Do I Order Customized Enclosures?
The Customized Product Will Be Designed And Made As Per Your Drawing Or Sample. When The Customized Sample Can Fully Meet Your Requirements, We Will Start Mass Production.
5. How To Guarantee The Quality Of Your Products?
1) Strict Detection During Production.
2) Strict Sampling Inspection On Products Before Shipment And Intact Product Packaging Ensured.
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