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Система хранения энергии POWEROAD Era L2-51 на литий-ферольных аккумуляторах для жилых помещений

POWEROAD H-U51100 51.2V 100Ah racking residential LiFePO4 battery energy storage system with built-in own-developed BMS.
● Scalable from 5.32kWh to 63.90kWh power configurations.
● Modular design allows convenient installation, saving labor cost.
● Extendable-modular, adding more capacities as needed.
● Safest LiFePO4 technology, sustained power supply.
● Long lifespan, up to 8000 cycles.
● Armed with POWEROAD designed BMS, three layer over current
● protection, safety first.
● Floor space sparing, allowing more space management.
● RS485, CAN communication support. Wi-Fi / BLE optional.
● Series connection providing higher efficiency and larger power.

The META H1 is powered by lithium-ion phosphate (LiFePO4) battery and for use with an external inverter.

Given the credit to the POWEROAD BMS, the systems will automatically trigger four layer over-current protection ensure powerful output and safety.

Starting with 1 module of 102.4V 52Ah batteries, users can configure the system capacity according to requirement from 5.32kWh to 63.90kWh by quick installation.

Основные характеристики

Выбор квалифицированной ячейки:

Мы предлагаем лучший ассортимент, обеспечивая широкий выбор элементов питания, включая CATL, CALB, EVE и др. Все элементы питания имеют сертификаты UL1642/IEC62133/IEC62619. Вы принимаете решение, а мы делаем все остальное.

Высокоэффективные компоненты:

В аккумуляторных изделиях POWEROAD используются проводники только высшего класса, что дает одну из лучших гарантий снижения сопротивления и повышения производительности.

Trusty Production:

Компания POWEROAD прошла сертификацию основных мировых производителей. Мы обещаем нашим клиентам профессиональную и строгую процедуру стандартизации производства, обеспечивающую научный подход к процессу сборки и высокое качество продукции.

Строгий контроль:

POWEROAD имеет более 20 этапов проверок, охватывающих до, во время и после производства. Мы предлагаем один из самых строгих в отрасли СОП по проверке, гарантирующий качество продукции и улучшающий качество обслуживания клиентов.

Technical Spec

Battery Type


Nominal Voltage (V)


Battery Capacity (Ah)


Nominal Energy (Wh)


Жизнь цикла


Charge Voltage (V)


Discharge Voltage (V)


Recommend Charge/Discharge Current (A)


Max. Charge/Discharge Current (A)


Peak Charge/Discharge Current (A)


Configuration (Max. in 1 Battery Group, pcs)


Mechanical Spec

Dimension (mm)


Масса (кг)



RS485, CAN

Protection Class


Cooling Type

Natural cooling

Working Temperature (℃)

Charge: 0~50

Discharge: -10~50


5% ~ 85%(RH) Without condensation


CE, UN38.3


In our ever-evolving world, the pursuit of sustainable energy solutions has become paramount. As we strive to reduce our carbon footprint and transition to cleaner energy sources, innovations in energy storage technologies are playing a pivotal role. One such innovation is the residential lifepo4 battery, a cutting-edge advancement that promises to revolutionize how we store and utilize energy in residential settings.

In this comprehensive article, we will delve deep into the world of LiFePO4 batteries, exploring their composition, benefits, applications, and the significant impact they are making on the residential energy storage landscape. As we embark on this journey, we will uncover how LiFePO4 batteries are at the forefront of sustainable living, ensuring a greener and more efficient future for homeowners worldwide.

Chapter 1: Understanding Residential Lifepo4 Battery

1.1. What Are LiFePO4 Batteries?

LiFePO4 batteries, short for Lithium Iron Phosphate batteries, belong to the family of lithium-ion batteries and are renowned for their exceptional energy density, longevity, and safety features. Unlike traditional lead-acid batteries, residential lifepo4 battery use lithium iron phosphate as their cathode material, making them a preferred choice for energy storage applications.

1.2. Composition of LiFePO4 Batteries

LiFePO4 batteries consist of several key components:

  • Cathode: Lithium iron phosphate (LiFePO4) is the primary cathode material, known for its stability and safety.

  • Anode: Typically, a carbon-based material such as graphite is used as the anode.

  • Electrolyte: An ionic conductor, often a lithium salt dissolved in a solvent, facilitates the movement of ions between the cathode and anode.

  • Separator: A porous material that physically separates the cathode and anode while allowing ion flow.

  • Current Collector: Conductive materials like copper or aluminum are used to collect and transport electrical current.

1.3. Advantages of Residential Lifepo4 Battery

LiFePO4 batteries offer numerous advantages, making them an ideal choice for residential energy storage:

  • Long Cycle Life: Residential lifepo4 battery can endure thousands of charge-discharge cycles, resulting in a longer lifespan compared to other battery chemistries.

  • High Energy Density: They provide a high energy-to-weight ratio, allowing for more energy storage in a compact space.

  • Enhanced Safety: LiFePO4 batteries are inherently stable and less prone to thermal runaway or fire, making them a safer option.

  • Wide Temperature Range: They can operate efficiently in a broader temperature range compared to other lithium-ion batteries.

  • Fast Charging: Residential lifepo4 battery have a relatively short charging time, making them suitable for quick energy replenishment.

Chapter 2: Applications of LiFePO4 Batteries in Residential Settings

2.1. Off-Grid Solar Systems

One of the primary applications of residential lifepo4 battery is in off-grid solar systems. These batteries store excess solar energy generated during the day for use during the night or on cloudy days. Homeowners can significantly reduce their reliance on grid electricity and enjoy a consistent and renewable power source.

2.2. Energy Backup

LiFePO4 batteries serve as reliable backup power sources during grid outages. They seamlessly switch to battery power when the grid fails, ensuring that essential appliances and systems continue to operate, providing peace of mind to homeowners.

2.3. Peak Shaving and Load Management

Residential lifepo4 battery can be used to manage peak electricity demand effectively. During periods of high electricity usage, these batteries discharge stored energy, reducing the load on the grid and helping homeowners avoid peak-hour energy costs.

2.4. Time-of-Use (TOU) Optimization

LiFePO4 batteries can be programmed to charge during off-peak hours when electricity rates are lower and discharge during peak hours when rates are higher. This smart energy management reduces electricity bills and enhances cost-effectiveness.

Chapter 3: Environmental Impact and Sustainability

3.1. Reduced Carbon Footprint

By enabling the efficient storage of renewable energy, residential lifepo4 battery play a pivotal role in reducing carbon emissions. Homeowners who utilize solar panels and LiFePO4 batteries can significantly decrease their reliance on fossil fuels for electricity, contributing to a greener planet.

3.2. Resource Efficiency

LiFePO4 batteries are highly resource-efficient, thanks to their long lifespan and recyclability. The reduction in battery replacements and the ability to recycle lithium and iron phosphate materials make them a sustainable choice for residential energy storage.

3.3. Energy Independence

With residential lifepo4 battery, homeowners can become more energy independent by generating and storing their electricity. This reduces their reliance on centralized power grids and fosters a sense of energy autonomy.

Chapter 4: Challenges and Solutions

4.1. Cost

While residential lifepo4 battery offer numerous benefits, they can be relatively expensive upfront. However, the long-term savings from reduced energy bills, longer lifespan, and reduced maintenance costs often outweigh the initial investment.

4.2. Limited Energy Density

LiFePO4 batteries have a lower energy density compared to some other lithium-ion battery chemistries. This limitation may require larger battery systems to meet the energy storage needs of larger households.

4.3. Recycling Infrastructure

To maximize the sustainability of residential lifepo4 battery, it is crucial to develop efficient recycling infrastructure to recover valuable materials and minimize waste. Governments and industries should invest in battery recycling facilities to address this challenge.

Chapter 5: The Future of Residential LiFePO4 Batteries

5.1. Technological Advancements

Continuous research and development in battery technology are driving improvements in residential lifepo4 battery. Future advancements may lead to even longer lifespans, increased energy density, and lower costs.

5.2. Integration with Smart Home Systems

Resident LiFePO4 Batteries are increasingly being integrated into smart home systems, allowing homeowners to monitor and control their energy consumption and storage remotely through smartphone apps and home automation platforms.

5.3. Market Growth

The global market for residential residential lifepo4 battery is expected to grow substantially in the coming years as more homeowners embrace sustainable energy solutions. This growth will likely lead to increased competition and further innovations in the field.


The residential lifepo4 battery is a game-changing technology that is transforming residential energy storage. Its numerous advantages, including long lifespan, safety, and environmental benefits, make it a compelling choice for homeowners looking to reduce their carbon footprint and gain energy independence.

As we move toward a more sustainable future, LiFePO4 batteries are poised to play a vital role in reshaping the residential energy landscape. With ongoing advancements and increasing market adoption, these batteries are set to power a greener, more efficient, and environmentally responsible world for generations to come.

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