Company ESS-LFP-M Rechargeable Batteries Series
Product Details
| Model | Nominal Voltage (V) | Nominal Capacity (Ah) | Nominal Energy (kWh) | Max. Charge Current (A) | Max. Discharge Current (A) | Dimension (W*D*H) (±2mm) | Weight (±2kg) |
|---|---|---|---|---|---|---|---|
| VHR CES38100LFP (M1) | 38.4 | 100 | 3.84 | 100 | 100 | 522 x 460 x 150 | 35 |
| VHR CES38280LFP (M2) | 38.4 | 280 | 10.752 | 280 | 280 | 522 x 600 x 225 | 85 |
| VHR CES51100LFP (M3) | 51.2 | 100 | 5.12 | 100 | 100 | 522 x 560 x 150 | 52 |
| VHR CES51280LFP (M4) | 51.2 | 280 | 14.336 | 280 | 280 | 522 x 750 x 225 | 110 |
| VHR CES76100LFP (M5) | 76.8 | 100 | 7.68 | 100 | 100 | 522 x 750 x 150 | 70 |
| VHR CES76280LFP (M6) | 76.8 | 280 | 21.504 | 280 | 280 | 522 x 1070 x 225 | 155 |
Common Product Specifications
| Cycle Life (@80%DoD, 0.5C) | Working Temperature (℃) | Humidity | Communication |
|---|---|---|---|
| > 4000 (M1, M3, M5) | -20 ~ 60 | 5% ~ 95% | RS485/CAN/ Ethernet |
| > 6000 (M2, M4, M6) | - | - | - |
Product Manufacturing Process
The manufacturing process for lithium iron phosphate (LFP) batteries involves several stages, including the preparation of materials, electrode coating, electrolyte injection, and assembly. The process begins with the careful selection and mixing of raw materials, ensuring the right composition for optimal performance. Electrode coating follows, where active materials are applied to a substrate, typically aluminum for cathodes and copper for anodes. Subsequently, the coated electrodes are stacked or wound to form cells. During the electrolyte injection stage, a liquid electrolyte is added, facilitating ion transport between the electrodes. The cells are then sealed and subjected to formation cycling, where initial charging and discharging cycles refine the battery's capacity and performance. Quality control checks are rigorous throughout to ensure high manufacturing standards. This meticulous process, backed by continuous research and development, ensures that the batteries meet stringent safety and durability specifications, common in authoritative papers and industry standards.
Product Application Scenarios
Lithium iron phosphate batteries are increasingly utilized in various sectors due to their safety and performance advantages. In renewable energy projects, they act as efficient storage solutions, balancing intermittent energy production from solar and wind sources. LFP batteries are also pivotal in electric mobility, providing power for electric vehicles (EVs) and e-bikes, known for their lightweight and long cycle life. In the telecommunications sector, they offer reliable backup power, ensuring continuous network operations. Residential energy storage systems benefit from their compact design and long service life, supporting grid independence. Authoritative studies highlight these scenarios, emphasizing LFP batteries' role in reducing carbon footprints and fostering sustainable development.
Product After-Sales Service
HRESYS Company prioritizes customer satisfaction through comprehensive after-sales service, including warranty coverage, technical support, and customer service assistance. Our support team is available to address queries and guide customers through troubleshooting and maintenance processes, ensuring prolonged product life and reliability.
Product Transportation
Ensuring the safety of lithium batteries during transportation is critical. HRESYS Company adheres to international transport regulations, ensuring the safe packaging of batteries with UN-certified materials. Our logistics partners are experienced in handling hazardous goods, providing reliable delivery methods to reach global destinations securely.
Product Advantages
- High energy density
- Long cycle life
- Enhanced safety features
- Environmentally friendly
- Compact and modular design
Product FAQ
- How long do HRESYS rechargeable batteries last? Typically, our LFP batteries have a cycle life of 4,000 to 6,000 cycles, depending on usage and conditions.
- Are these batteries safe for residential use? Yes, they are designed with advanced safety features, including thermal management systems, ensuring a safe usage environment.
- What maintenance is required for these batteries? Minimal maintenance is needed. Regular checks on the battery management system (BMS) are recommended to ensure optimal performance.
- Can these batteries be recycled? Yes, HRESYS encourages recycling, and our batteries are designed to comply with recycling standards to minimize environmental impact.
- What is the warranty period for these batteries? Our batteries come with a standard warranty period, details of which are provided upon purchase. Extended warranty options are also available.
- How do I install the battery system? We provide installation guides and professional support to ensure proper setup and operation.
- What is the maximum depth of discharge (DoD)? Our batteries are designed for a maximum DoD of 80%, balancing longevity and performance.
- How do I monitor the battery system? An integrated BMS offers real-time monitoring and diagnostics through our compatible app, ensuring efficient management.
- Can these batteries be used in extreme temperatures? Yes, they are designed to operate within a temperature range of -20°C to 60°C.
- What is the communication protocol for these batteries? They support RS485, CAN, and Ethernet, providing versatile connectivity options.
Product Hot Topics
- Advancements in Rechargeable Battery Technology
The evolution of rechargeable batteries has been marked by significant technological advancements, with lithium iron phosphate (LFP) batteries standing out for their stability, environmental benefits, and long cycle life. HRESYS Company is at the forefront of this innovation, continually enhancing battery efficiency and safety standards.
- The Role of Rechargeable Batteries in Renewable Energy
Rechargeable batteries, particularly LFP types, play a crucial role in supporting renewable energy initiatives. These batteries store energy generated from intermittent sources like solar and wind, providing a steady supply and enhancing grid reliability. HRESYS Company leverages cutting-edge technology to optimize storage solutions for green energy applications.
- Safety Standards in Rechargeable Batteries
Safety is paramount in the design and use of rechargeable batteries. HRESYS Company implements rigorous safety measures, including advanced battery management systems (BMS) and thermal management, ensuring secure operation across applications.
- Environmental Impact of Rechargeable Batteries
Rechargeable batteries help reduce environmental impact by minimizing waste associated with disposable batteries. HRESYS Company is committed to sustainable practices, using environmentally friendly materials and supporting recycling initiatives to limit ecological footprints.
- Optimizing Energy Storage Systems with LFP Batteries
LFP batteries are increasingly favored in energy storage systems for their high energy density and safety. HRESYS Company integrates these batteries into scalable solutions, enabling efficient energy management for diverse sectors, from residential to industrial.
- Battery Management System (BMS) Innovations
The BMS is crucial in ensuring the reliable operation of rechargeable batteries. HRESYS Company's intelligent BMS technology monitors battery health, balances cell operations, and provides real-time diagnostics, enhancing system longevity and performance.
- Recycling and Disposal of Rechargeable Batteries
Proper recycling and disposal of rechargeable batteries are essential for environmental protection. HRESYS Company designs its products with recycling in mind, emphasizing the recovery of valuable materials and ecologically responsible disposal.
- Impact of Rechargeable Batteries on Electric Mobility
Rechargeable batteries are at the heart of the electric mobility revolution. HRESYS Company develops lightweight, long-lasting battery solutions for electric vehicles, supporting cleaner transportation and reducing reliance on fossil fuels.
- Technological Challenges in Battery Development
The development of rechargeable batteries faces challenges like energy density limits and fast-charging constraints. HRESYS Company addresses these through ongoing research and technological innovation, pushing the boundaries of battery performance.
- Future Trends in Rechargeable Battery Industry
The rechargeable battery industry continues to evolve, with trends leaning towards higher energy efficiency, sustainability, and integration with smart technologies. HRESYS Company is poised to lead these trends, providing cutting-edge battery solutions for a variety of applications.
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