Learn more about how sustainability is built into our philosophy and our products
English
English French German Portuguese Spanish Russian Japanese Korean Arabic Irish Greek Turkish Italian Danish Romanian Indonesian Czech Afrikaans Swedish Polish Basque Catalan Esperanto Hindi Lao Albanian Amharic Armenian Azerbaijani Belarusian Bengali Bosnian Bulgarian Cebuano Chichewa Corsican Croatian Dutch Estonian Filipino Finnish Frisian Galician Georgian Gujarati Haitian Hausa Hawaiian Hebrew Hmong Hungarian Icelandic Igbo Javanese Kannada Kazakh Khmer Kurdish Kyrgyz Latin Latvian Lithuanian Luxembou.. Macedonian Malagasy Malay Malayalam Maltese Maori Marathi Mongolian Burmese Nepali Norwegian Pashto Persian Punjabi Serbian Sesotho Sinhala Slovak Slovenian Somali Samoan Scots Gaelic Shona Sindhi Sundanese Swahili Tajik Tamil Telugu Thai Ukrainian Urdu Uzbek Vietnamese Welsh Xhosa Yiddish Yoruba Zulu Kinyarwanda Tatar Oriya Turkmen Uyghur
contact us
Leave Your Message
High-Voltage LiFePO4 lithium battery system (module 15KWh)

HV ESS

products_img5.jpg
High-Voltage LiFePO4 lithium battery system (module 15KWh) (2).jpg
High-Voltage LiFePO4 lithium battery system (module 15KWh) (3).jpg

High-Voltage LiFePO4 lithium battery system (module 15KWh)

System Options

System voltage (V)

Module Q'ty

Hades-48100

Hades-9650

5kwh lithium battery

44.8~56.8

89.6 ~113.6

1

10kwh lithium battery

89.6~113.6

179.2~227.2

2

15kwh lithium battery

134.4~170.4

268.8~340.8

3

20kwh lithium battery

179.2~227.2

358.4~454.4

4

25kwh lithium battery

224~284

448~568

5

30kwh lithium battery

268.8~340.8

537.6~681.6

6

35kwh lithium battery

313.6~397.6

627.2~795.2

7

40kwh lithium battery

358.4~454.4

/

8

45kwh lithium battery

403.2~511.2

/

9

50kwh lithium battery

448~568

/

10

ENSMAR Hades-series 15KWh modules are high voltage battery that offers multiple energy storage options through an expandable modular design, which further simplifies installation and O&M with multiple smart functions. The safest battery cell technology (LFP) comes with a high charging rate, ensuring superior performance and supplying robust power for your life. They are ideal for new installation of household energy storage..

    Contact us download Download
    product details

    Product features

    ▶ Charge Your Battery within ONE HOUR;

     Remote Diagnosis & Upgrade;

     Auto Under-voltage Reboot;

     Self-designed BMS protects batteries;

    ▶ Grade A LiFePO4 battery assures safety;

    Technical Description

    MODEL

    Hades-48280

    Battery Type

    Lithium Iron Phosphate Battery (LiFePO4 battery)

    Nominal Capacity

    280Ah (@0.5C, 250℃)

    Nominal Voltage

    51.2V

    Total Energy

    14336Wh

    Battery Working Voltage

    44.8 ~56.8V

    Cell working Voltage

    2.5 ~ 3.65V

    Continuous Current

    140A (charge / discharge)

    Max. Continuous Current

    160A (charge / discharge)

    Peak Current

    180A@5S (charge / discharge)

    Cycle Life

    ≥5000 cycles (25℃±2 ℃ 0.5C @90%DOD 70%EOL)

    Ingress protection

    IP21

    Efficiency

    ≥94% (25℃±2 ℃ 0.5C @90%DOD)

    Expansion capability

    32pcs max in series

    Working Environment

    0 ~ 45℃ (charge)

    20 ~ 50℃ (discharge)

    ≤85% humidity

    Storage Environment

    -30℃~45℃

    5%~95% humidity

    Weight

    108KG

    Siz (W x D x H, mm)

    376*885*238.5mm(incl. hangers etc, )

    Design Life

    15 years

    Warranty Period

    5 years (10 years optional)

    Tips About Lithium Battery

    Backup Time Of LiFePO4 Energy Storage
    The backup time of a LiFePO4 (Lithium Iron Phosphate) energy storage system depends on several factors, including the battery's capacity, the power consumption of the household or devices being powered, and the efficiency of the system. Here's how to estimate it:

    Estimating Backup Time
    Formula: Backup Time (hours)= Battery Capacity (Wh)/Backup Time (hours)

    Steps to Calculate:
    1.Determine the Battery Capacity:
     Battery capacity is typically given in watt-hours (Wh). If it's provided in ampere-hours (Ah) and voltage (V), you can convert it using:
     Battery Capacity ( Wh ) = Battery Capacity ( Ah ) x Battery Voltage ( V)
     
    2.Calculate the Load Power:
    Sum up the power consumption of all devices or the average household power consumption (in watts, W).
    3.Consider Efficiency:
    While LiFePO4 batteries are highly efficient (around 95%), you might want to account for any inefficiencies in the system.

    Example Calculation
    Suppose you have a 10 kWh LiFePO4 battery (10,000 Wh) and your household has an average power consumption of 500 W.
    Backup Time (hours)= 10000wh/500w=20 HOURS
    This means that, in theory, the battery can provide 20 hours of backup power at a continuous load of 500 W.

    Practical Considerations
    1.Peaks and Variability:
    Actual power consumption can vary throughout the day. High-power appliances like air conditioners, heaters, or electric stoves can reduce backup time significantly when in use.

    2.Partial Discharge:
    To prolong battery life, it’s often recommended not to discharge batteries completely. For instance, using only 80% of the battery's capacity for backup would mean:
    Usable Capacity = 10000 Wh x 0.8 = 8 000wh
    Backup Time ( hours )=8000 Wh/500w=16 hours

    3.Partial Discharge:
    Accounting for a 5% efficiency loss:

    Effective Capacity=10,000 Wh×0.95=9,500 Wh
    Backup Time = 9500wh/500w =19 hours

    The backup time for a LiFePO4 energy storage system varies based on several factors, but it can be estimated using the battery's capacity and the power consumption of the load. Understanding these variables allows homeowners to make informed decisions about their energy storage needs and to manage their energy usage effectively during outages.

    description2

    Make an free consultant

    Your Name*

    Phone Number

    Country

    Remarks*

    reset