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L501
- Product Description
-
- Commodity name: L501
- Application Areas: ESS
- Product Type: LFP
- Product Characteristics: Long cycle
- 型号: L501
- D50(μm): 1.1±0.5
- 粉体压实(g/cm³): ≥2.5
- C(%): 1.45±0.2
- 比表面(m²/g): 12.5±2.0
- 粉末电阻率(Ω·cm): ≤100
- 0.1C首充容量(mAh/g): ≥158
- 0.1C首效(%): ≥95
- 0.1C首放容量 (mAh/g): ≥156
Ultra-long cycle</br> Excellent energy efficiency</br> Small primary particles
Product Features
Product Type Product Model Product Features Powder Compaction(g/cm³) 0.1C First Charge Capacity
(mAh/g)
0.1C Discharge Capacity
(mAh/g)
LFP L501 Long cycle ≥2.5 ≥158 ≥156 
Ultra-long cycle
15,000 times of long cycling
Reduces pre-cycle decay predictions
Excellent energy efficiency
95.52% energy efficiency at 0.5P discharge condition
Small primary particles
D50<1μm
High compaction density, not easy to agglomerateApplication
High-end ESS
Powering the Future of High-End Energy Storage Systems with Long Cycle LFP Technology
In the realm of advanced energy storage solutions, where efficiency and longevity are paramount, the L501 Lithium Iron Phosphate (LFP) material stands tall as a beacon of innovation. Engineered specifically for High-end Energy Storage Systems (ESS), this cutting-edge product embodies the perfect amalgamation of technological prowess and sustainability, making it the go-to choice for industries seeking unparalleled performance and reliability.
At the core of the L501's exceptional capabilities lies its Long Cycle LFP technology. Designed to endure an astounding 15,000 cycles, this material significantly reduces pre-cycle decay predictions, ensuring a lifespan that outlasts conventional alternatives by a considerable margin. This ultra-long cycle life not only translates into reduced maintenance costs but also underscores its commitment to environmental preservation by minimizing resource consumption over time.
Efficiency is another hallmark of the L501. Boasting an impressive 95.52% energy efficiency at a 0.5P discharge rate, it sets new benchmarks in energy conversion, thereby maximizing the utility of every stored electron. This high efficiency is crucial for high-end ESS applications, where even the slightest losses can accumulate into substantial operational expenses. By converting more energy input into usable output, the L501 ensures that renewable resources like solar and wind are harnessed optimally, furthering the global transition towards clean energy.
A key contributor to the L501's superior performance is its adoption of small primary particles, with a median diameter (D50) of less than 1 micrometer. This nanoscale engineering facilitates faster ion transport within the material, enhancing both charge and discharge rates without compromising safety or stability. Coupled with a high compaction density that resists agglomeration, these particles enable the L501 to achieve higher energy densities while maintaining structural integrity, a critical factor in the design of compact yet powerful ESS units.
Moreover, the use of Lithium Iron Phosphate as the cathode material imparts inherent safety advantages. Unlike other lithium-based chemistries prone to thermal runaway, LFP's enhanced chemical stability minimizes the risk of overheating and fire hazards, making it ideal for large-scale deployments where safety is a top priority.
In conclusion, the L501 Long Cycle LFP represents a quantum leap forward in energy storage technology, tailored to meet the stringent demands of high-end ESS applications. Its combination of ultra-long cycle life, exceptional energy efficiency, and advanced material science based on small primary particles positions it as a game-changer in the quest for a greener, more sustainable energy future. As we continue to push the boundaries of what's possible in energy storage, the L501 stands ready to power our journey towards a world powered by clean, efficient, and reliable energy sources.
Keywords: L501
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