Amp Nova 100 KWH Battery 512V 200Ah

  • Longer Cycle Life: Offers up to 6000 cycles.
  • Lighter Weight: About 40% weight of a comparable lead acid battery, save up to 60% in weight.
  • Quick Charge: Short charge time compared with lead acid battery.
  • Low Self-Discharge: Low self-discharge (2%/month) compared with lead acid battery, longer storage time without recharging.
  • Superior Safety: Multi-protection methods are built inside to protect the battery from overcharge, over-discharge, and short-circuit situations.
  • High Efficiency: Higher round-trip energy efficiency of the average (92%) than lead acid battery 80% (discharge from 100% to 0% and back to 100% charged).
  • Certifications: UM38.3, MSDS, CE
Nominal voltage 512V
Nominal capacity 200Ah
Dimensions Length 800±2mm (31.49inch)
Width 600±2mm (23.62inch)
Height 1800±2mm (70.87inch)
Total height 1870±2mm (73.62inch)
Approx. weight 1886.0kg (4157.88lbs)±60kg


Rated Voltage 512V
Rated Capacity (C5) 200Ah@25°C
Energy 102400Wh
Months Self Discharge <3%
Charge Efficiency 99.5%@ 0.2C
Discharge Efficiency 96-99%@ 1C
Terminal Diameter M8
Internal resistance (Fully charged, 25°C) ≤280mΩ
Cycle life >3000 cycles @ 0.2C 100%D.O.D
affected by
40°C 101%
25°C 100%
0°C 90%
-10°C 75%
Nominal operating temperature 25°C± 3°C (77°F± 5°F)
Discharge – 20°C~ 60°C (-4°F ~ 140°F)
Charge 0°C~ 45°C (32°F ~ 113°F)
Storage 0°C~ 40°C (32°F ~ 104°F)
Water Dust Resistance IP50
Charge Voltage 584V
Standard Charge Mode
(25°C±2°C, <75%RH)
0.2CA Constant Current to 584V,
then Constant Voltage 584V
until the current drops to 0.02CA,
before use, rest 30 minutes
Charge Current 40A
Maximum Charge Current 100A
Charge Cut off Voltage 584V
Continuous Discharge Current 200A
Maximum Pulse Current 400A (<2S, Adjustable)
Discharge Cut Off Voltage 448V
Communicate Protocol (optional) RS485/RS232/CAN
SOC (optional) Screen/LED/PC Software
Application connection 1 string 1 parallel
Mechanical Cells Qty 160 Strings
Container Metal

Amp Nova 100 KWH Battery 512V 200Ah

  • Introduction
  • Understanding Battery Capacity
  • Exploring the Potential of a 100 KWH Battery
  • Advantages of a 100 KWH Battery
  • Applications of a 100 KWH Battery
  • Challenges and Limitations of a 100 KWH Battery
  • Future Developments in Battery Technology
  • Conclusion


The advent of 100 KWh Battery has ushered in a transformative era in battery technology, revolutionizing multiple industries and reshaping our approach to energy storage and utilization. This article will focus on the capabilities and potential of these high-capacity batteries, exploring their advantages, applications, limitations, and prospects for the future.

Understanding Battery Capacity

Before we dive deeper into the world of 100 KWH batteries, it is essential to understand the concept of battery capacity. Battery capacity refers to the amount of electrical energy that a battery can store and deliver. It is typically measured in Kilowatt-hours (KWH), which represents the amount of energy the battery can provide in one hour. The higher the KWH rating, the more energy the battery can store and deliver.

Exploring the Potential of a 100 KWH Battery

A 100 KWH battery offers a tremendous amount of power and storage capacity. To put this into perspective, a typical electric vehicle battery has a capacity ranging from 20 to 100 KWH, meaning a 100 KWH battery can provide energy equivalent to charging an electric vehicle up to four times on a single charge.

Moreover, a 100 KWH battery has the potential to power an average household for several days, depending on the energy consumption. It can also serve as a backup power source during blackouts, ensuring uninterrupted electricity supply to critical appliances and systems.

Advantages of a 100 KWH Battery

The adoption of 100 KWH batteries comes with several advantages and benefits. Let’s explore a few of them:

  1. Increased Energy Independence: With a 100 KWH battery, homes and businesses can reduce their reliance on the electrical grid. They can store excess energy generated from renewable sources, such as solar panels or wind turbines, and utilize it during times of high demand or when the grid experiences an outage.
  2. Environmental Sustainability: By leveraging a 100 KWH battery, individuals and organizations can further promote sustainability by relying less on fossil fuels and generating their own clean energy. This reduces greenhouse gas emissions and contributes to a greener future.
  3. Cost Savings: While the initial investment in a 100 KWH battery may be significant, it can lead to long-term cost savings. By storing excess energy during low-demand periods or when prices are lower, users can optimize their energy consumption and reduce their electricity bills.
  4. Load Shifting: A 100 KWH battery allows users to shift their energy consumption to off-peak hours when electricity prices are typically lower. This can help flatten the demand curve and relieve strain on the electrical grid during peak hours.

Applications of a 100 KWH Battery

The versatility of a 100 KWH battery opens up a wide range of applications across various industries. Some notable applications include:

  1. Residential Power Storage: One of the primary applications of a 100 KWH battery is residential power storage. Homeowners can store excess energy generated by solar panels or wind turbines during the day and use it during the night or during power outages.
  2. Commercial and Industrial Backup Power: Businesses and industries can benefit from the uninterrupted power supply provided by a 100 KWH battery during emergencies or in areas prone to frequent blackouts.
  3. Grid Stabilization: The integration of large-scale 100 KWH battery systems into the electrical grid can help stabilize the supply-demand imbalance, ensuring a consistent and reliable power supply.
  4. Electric Vehicle Charging: A 100 KWH battery can significantly enhance the charging capabilities for electric vehicles, enabling faster charging and longer driving ranges.

Challenges and Limitations of a 100 KWH Battery

While the 100 KWH battery brings a plethora of advantages, it is important to acknowledge its challenges and limitations. Some of the key considerations include:

  1. Cost: The cost of manufacturing and deploying a 100 KWH battery can be substantial. This factor may hinder its widespread adoption, especially for individual consumers or small-scale applications.
  2. Size and Weight: A 100 KWH battery typically requires a significant physical space and may have a substantial weight. This can pose challenges for installation, particularly in areas with limited available space.
  3. Maintenance: Like any other battery, a 100 KWH battery requires regular maintenance to ensure optimal performance and longevity. This can involve monitoring the battery’s state of charge, temperature regulation, and occasional replacements of faulty cells.
  4. Limited Lifespan: Despite continuous advances in battery technology, the lifespan of a 100 KWH battery is finite. Over time, the battery’s capacity may degrade, requiring eventual replacement.

Future Developments in Battery Technology

As technology continues to evolve, researchers and developers are actively working to overcome the limitations of 100 KWH batteries while further enhancing their capabilities. Some areas of future development in battery technology include:

  1. Increased Energy Density: Advancements in battery chemistry aim to increase the energy density of batteries, allowing for higher capacity within a smaller physical footprint.
  2. Quick Charging: Developers are exploring ways to reduce charging times significantly, enabling rapid replenishment of a 100 KWH battery’s energy.
  3. Improved Lifespan: Extending the lifespan of 100 KWH batteries through advancements in materials and manufacturing processes is a focus area for researchers. This would reduce replacement frequency and overall costs.
  4. Enhanced Safety: Battery safety is a paramount concern. Future developments will focus on enhancing the safety features of 100 KWH batteries, mitigating risks such as thermal runaway and improving overall reliability.


The emergence of 100 KWH batteries presents a remarkable leap in energy storage and delivery. These high-capacity batteries offer numerous advantages, including increased energy independence, environmental sustainability, cost savings, and versatility across various applications. Despite their challenges and limitations, ongoing research and development in battery technology hold promise for addressing these concerns and advancing the capabilities of 100 KWH batteries. As the world continues to embrace renewable energy and strive towards a more sustainable future, the power and potential of a 100 KWH battery will undoubtedly play a pivotal role in shaping our energy landscape.

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