Exploring the Latest Breakthroughs in Commercial and Industrial Energy Storage
The EGbatt 100KWH lithium battery pack ESS-GRID series introduces an advanced commercial and industrial energy storage solution, meticulously crafted to fulfill the demands of high-power applications. Boasting battery capacities of 100 kWh and 200 kWh, our system is purpose-built to supply unwavering, enduring power to both industrial and commercial ventures.
Our system's design is geared towards optimizing efficiency while curtailing expenses. Employing sophisticated software algorithms, we ensure the judicious utilization of the battery while upholding peak performance. Incorporating cutting-edge technology and top-notch materials, our energy storage setup guarantees safety and robustness, all the while being user-friendly for installation and upkeep.
Our team of adept professionals is committed to tailoring each energy storage solution to the distinct requisites of our customers. Our goal is to deliver unparalleled performance and reliability that aligns seamlessly with their unique needs.
What Application Scenarios are Supported by ESS-GRID?
Backup Power for Critical Operations: The battery stands ready to supply dependable backup power to vital operations, like data centers or hospitals, should a power outage or other disruption occur.
Load Shifting: The battery is adept at shifting energy consumption to hours with lower demand, when electricity costs are reduced. This tactic aids in curbing energy expenses for commercial and industrial setups.
Peak Shaving: The battery excels in trimming peak demand charges during periods of heightened energy usage. This strategic move aids businesses with substantial peak demand charges in trimming down their electricity bills.
Integration of Renewable Energy: The battery proves invaluable in storing surplus energy generated by renewable sources such as solar or wind power. This approach fosters greater utilization of renewable energy and diminishes dependence on fossil fuels.
Voltage Regulation: The battery's role extends to aiding in voltage regulation across the electrical grid. This intervention enhances grid stability and reliability.
Microgrid Support: The battery seamlessly integrates into microgrids, furnishing unwavering power to localized areas like remote communities or military bases, thereby enhancing their autonomy.
By offering EGbatt versatile solutions, ESS-GRID caters to a spectrum of energy needs across diverse settings, amplifying efficiency and sustainability.
Features
Turnkey Solution: Our comprehensive offering encompasses energy storage converter PCS, EMS lamp, and multiple adapters, providing you with a complete and hassle-free energy storage solution.
Ease of Assembly: The battery system is designed for effortless setup, utilizing rack-mounted batteries. Each module, weighing 65 kg, can be easily installed by a team of just two individuals.
Intelligent Monitoring Panel: The high voltage control box features a display panel for holistic system monitoring. This interface facilitates the verification of system data authenticity and enables control over the air conditioning system.
Scalability: While the current ESS-GRID series allows for a maximum of two parallel connections, our commitment to technological advancement ensures that our solution will evolve into a more flexible option for commercial and industrial energy storage. As technology progresses, we plan to enhance the system's scalability to cater to diverse requirements.
Performance with HV battery System
Within our high-voltage ESS battery systems lies a remarkable 768V system voltage, guaranteeing peak performance and efficiency across all your commercial and industrial undertakings. This elevated voltage blueprint aids in minimizing energy wastage and amplifying overall system efficiency, furnishing you with a dependable and potent energy storage resolution.
Energy Storage System Specifications
| 50kW/100kWh | 100kW/215kWh | 50kW/83kWh | 100kW/215kWh | |
|---|---|---|---|---|
| Model | 50(100kwh) | 100(215kwh) | 50TS(DC50)(83kwh) | 100TS(DC100)(215kwh) |
| Max. PV input power | / | / | 50kW | 100kW |
| Max. PV input voltage | / | / | 620V | 680V |
| STS | / | / | STS optional | STS optional |
| Transformer | / | / | Transformer inside | Transformer inside |
| Battery(DC) | ||||
| Rated battery capacity | 100kWh | 215kwh | 83kWh | 215kwh |
| Rated system voltage | 844.8V | 768V | 691.2V | 768V |
| Battery type | Lithium iron phosphate battery (LFP) | |||
| Battery Cell capacity | 120Ah | 280Ah | 120Ah | 280Ah |
| Series of battery | 1P*24S*11S | 1P*20S*12S | 1P*24S*9S | 1P*20S*12S |
| AC | ||||
| Rated AC power | 50kW | 100kW | 50KW | 100kW |
| Rated AC current | 72A | 144A | 72A | 144A |
| Rated AC voltage | 400V,3P+N+PE,50/60Hz | |||
| THDi | 3%(rated power) | |||
| PF | -1 leading to+1 lagging | |||
| General Parameters | ||||
| Protection level | IP55 | |||
| Isolation mode | Non-lsolation (Adding isolation transformer is optional) | |||
| Operating temperature | -25~60℃(Derating above 45℃) | |||
| Altitude | 3000m(>3000m derating) | |||
| Communication interface | RS485/CAN 2.0/ Ethernet/dry contact | |||
| Dimension(W*D *H) | 1200*1000*2150mm | 1800*1200*2300mm | 1400*1000*2300mm | 1800*1200*2300mm |
| Weight (with battery) | 1200kg | 2400kg | 1750kg | 3000kg |
| Note: Above models are typical configurations. PV charging (DC/DC) module, On/of-grid switching module, industrial isolation transformer and other components can also be selected for micro-grid scenarios, to form Solar ESS integrated system cabinet. | ||||
How Long Will a 100 kWh Battery Last?
The duration a 100 kWh battery will last depends on the power consumption of the connected system or device, measured in watts (W) or kilowatts (kW). To determine the battery's lifespan, divide the battery capacity (100 kWh) by the power usage.
For example:
- If a device uses 10 kW of power, the battery would last 100 kWh / 10 kW = 10 hours.
- If a device uses 100 W (0.1 kW) of power, the battery would last 100 kWh / 0.1 kW = 1000 hours.
Thus, the lower the power consumption, the longer the battery will last.
How Much is a 100 kWh Battery?
The cost of a 100 kWh battery varies depending on its type, manufacturer, and features. Prices can range from a few thousand to tens of thousands of dollars.
As of 2024, the average cost of a lithium-ion battery pack was around $140/kWh. Therefore, a 100 kWh battery would cost approximately $14,000.
For the best value and latest pricing on a 100 kWh battery, please contact us for a detailed quotation.
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Solar Battery Capacity and Understanding Kilo-Watt Hours (kWh)
These solar batteries are designed to deliver a capacity of 100 kilo-watt hours (kWh) per cycle. To determine the appropriate battery size for your residence or business, refer to your power bills to ascertain your actual kWh consumption. Calculate the average daily kWh usage as well as the peak daily consumption.
We offer an array of solar battery packs that cater to power storage ranging from 1 kWh to over 100 kWh. If you're interested in the cost of a 100 kWh backup battery power storage solution, kindly inquire about the pricing for our most economical 100 kWh battery options.
- Understanding Kilo-Watt Hours (kWh): A kilo-watt hour symbolizes 1,000 watts expended over the course of one hour. Abbreviated as kWh, it encapsulates the concept of 1 kWh being equivalent to 1,000 watts consumed in one hour. Energy consumption is measured by power companies in kWh, forming the basis for your monthly billing calculation.
- Determining Your Kilo-Watt Hour Requirements: According to the U.S. Energy Information Agency (EIA), the average household consumes around 900 kWh each month, summing up to 10,800 kWh annually. Translated to daily figures, this amounts to approximately 30 kWh per day. When sizing a grid-tied solar battery system for daily utilization, it's advisable to choose a setup capable of supplying up to 30 kWh per day. This may need to be higher to account for days with peak energy needs.
However, if you're aiming for the system to offer off-grid backup battery storage as well, a typical strategy involves opting for a capacity ranging from 3 to 5 times the daily average, resulting in 90 to 150 kWh. This range ensures ample storage for complete system autonomy during extended power outages spanning 3 to 5 days. For enhanced sustainability, combine the battery storage with a photovoltaic (PV) solar panel system. This integration guarantees a renewable power source for keeping the batteries adequately charged.
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