- Lithium Golf Cart Battery
- Forklift Lithium Battery
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48V
- 48V 210Ah
- 48V 300Ah
- 48V 420Ah (949 x 349 x 569 mm)
- 48V 420Ah (950 x 421 x 450 mm)
- 48V 456Ah
- 48V 460Ah (830 x 630 x 590 mm)
- 48V 460Ah (950 x 421 x 450 mm)
- 48V 460Ah (800 x 630 x 600 mm)
- 48V 460Ah (820 x 660 x 470 mm)
- 48V 500Ah
- 48V 560Ah (810 x 630 x 600 mm)
- 48V 560Ah (950 x 592 x 450 mm)
- 48V 600Ah
- 48V 630Ah
-
48V
- 12V Lithium Battery
12V 150Ah Lithium RV Battery
Bluetooth App | BCI Group 31
LiFePO4 Lithium
Discharge Temperature -20°C ~ 65°C
Fast Charger 14.6V 50A
Solar MPPT Charging - 24V Lithium Battery
- 36V Lithium Battery
- 48V Lithium Battery
-
48V LiFePO4 Battery
- 48V 50Ah
- 48V 50Ah (for Golf Carts)
- 48V 60Ah (8D)
- 48V 100Ah (8D)
- 48V 100Ah
- 48V 100Ah (Discharge 100A for Golf Carts)
- 48V 100Ah (Discharge 150A for Golf Carts)
- 48V 100Ah (Discharge 200A for Golf Carts)
- 48V 150Ah (for Golf Carts)
- 48V 160Ah (Discharge 100A for Golf Carts)
- 48V 160Ah (Discharge 160A for Golf Carts)
-
48V LiFePO4 Battery
- 60V Lithium Battery
-
60V LiFePO4 Battery
- 60V 20Ah
- 60V 30Ah
- 60V 50Ah
- 60V 50Ah (Small Size / Side Terminal)
- 60V 100Ah (for Electric Motocycle, Electric Scooter, LSV, AGV)
- 60V 100Ah (for Forklift, AGV, Electric Scooter, Sweeper)
- 60V 150Ah (E-Motocycle / E-Scooter / E-Tricycle / Tour LSV)
- 60V 200Ah (for Forklift, AGV, Electric Scooter, Sweeper)
-
60V LiFePO4 Battery
- 72V~96V Lithium Battery
- Rack-mounted Lithium Battery
- E-Bike Battery
- All-in-One Home-ESS
- Wall-mount Battery ESS
-
Home-ESS Lithium Battery PowerWall
- 24V 100Ah 2.4kWh PW24100-S PowerWall
- 48V 50Ah 2.4kWh PW4850-S PowerWall
- 48V 50Ah 2.56kWh PW5150-S PowerWall
- 48V 100Ah 5.12kWh PW51100-F PowerWall (IP65)
- 48V 100Ah 5.12kWh PW51100-S PowerWall
- 48V 100Ah 5.12kWh PW51100-H PowerWall
- 48V 200Ah 10kWh PW51200-H PowerWall
- 48V 300Ah 15kWh PW51300-H PowerWall
PowerWall 51.2V 100Ah LiFePO4 Lithium Battery
Highly popular in Asia and Eastern Europe.
CE Certification | Home-ESS -
Home-ESS Lithium Battery PowerWall
- Portable Power Stations
What are lead-acid vs. Li-ion advantages in autos?
Posted by
adminw
On June 17, 2024
Comments Off on What are lead-acid vs. Li-ion advantages in autos?
Lead-acid batteries are favored in autos for their cost-effectiveness and longer lifespan. They are commonly used in traditional internal combustion engine vehicles. In contrast, Li-ion batteries offer higher energy density and faster charging, making them ideal for electric and hybrid vehicles.
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Lead-Acid Batteries:
Lead-acid batteries have been widely used in autos for many years. One of their key advantages is their cost-effectiveness. Lead-acid batteries are generally more affordable compared to lithium-ion batteries, making them a popular choice for traditional internal combustion engine vehicles. Additionally, lead-acid batteries have a longer lifespan, providing reliable performance over an extended period. -
Lithium-Ion Batteries:
Lithium-ion batteries offer several advantages that make them well-suited for electric and hybrid vehicles. One significant advantage is their higher energy density, which allows for more power to be stored in a smaller and lighter package. This higher energy density enables electric and hybrid vehicles to have longer driving ranges and improved performance. Another advantage of lithium-ion batteries is their faster charging capability, reducing the time required to recharge the vehicle’s battery.
Table of Contents
ToggleWhat are lithium-ion battery safety concerns?
Lithium-ion battery safety concerns include overcharging, overheating, and physical damage. Overcharging can lead to overheating and the risk of thermal runaway. It is crucial to handle and store lithium-ion batteries carefully to prevent accidents and ensure safe usage.
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Overcharging and Overheating:
One of the primary safety concerns with lithium-ion batteries is overcharging, which can lead to overheating. Overcharging occurs when a battery is charged beyond its recommended voltage or for an extended period. This can cause the battery to generate excess heat, potentially leading to thermal runaway and the risk of fire or explosion. Proper charging techniques and using chargers specifically designed for lithium-ion batteries can help prevent overcharging and mitigate the associated risks. -
Physical Damage:
Lithium-ion batteries are sensitive to physical damage, such as punctures or impacts. Damaged batteries can develop internal short circuits, which can result in overheating and potentially lead to thermal runaway. It is crucial to handle lithium-ion batteries with care and avoid subjecting them to unnecessary physical stress. Proper storage and transportation in protective cases or packaging can help minimize the risk of physical damage. -
Safe Handling and Storage:
To ensure the safe usage of lithium-ion batteries, it is important to follow recommended handling and storage practices. Avoid exposing batteries to extreme temperatures, as both high heat and freezing temperatures can impact their performance and safety. Store batteries in a cool, dry place and avoid storing them near flammable materials. Additionally, it is essential to use chargers and accessories that are compatible with lithium-ion batteries to prevent overcharging and overheating.
What factors influence battery selection?
Battery selection is influenced by factors such as application requirements, power needs, space availability, and budget. Battery chemistry, maintenance requirements, and environmental impact are also important considerations. By understanding these factors, users can make informed decisions and choose the most suitable battery for their specific needs.
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Application Requirements:
Different applications have varying power demands and operational characteristics. It is crucial to assess the specific requirements of the application, such as voltage, current, and discharge rate. This helps determine the battery capacity and chemistry that will best meet the power needs. -
Power Needs:
The power requirements of the system or equipment play a significant role in battery selection. Assessing the power consumption, both in terms of peak and continuous loads, helps determine the battery’s capacity and discharge rate. Choosing a battery that can deliver the required power without compromising performance is essential. -
Space Availability:
The physical dimensions and form factor of the battery are important considerations, especially when space is limited. Assessing the available space for battery installation helps determine the size and shape of the battery that can be accommodated without causing any interference or compromising safety. -
Budget:
Budget considerations are crucial when selecting a battery. Different battery chemistries and technologies have varying costs. It is important to assess the budget available for the project and find a balance between cost and performance to ensure the best value for money. -
Battery Chemistry:
Battery chemistry plays a significant role in determining the performance, lifespan, and maintenance requirements of the battery. Common battery chemistries include lead-acid, lithium-ion, and nickel-based chemistries. Each chemistry has its advantages and disadvantages, and selecting the most suitable chemistry depends on the specific application requirements. -
Maintenance Requirements:
Some batteries require regular maintenance, such as checking electrolyte levels or equalizing charges, while others are maintenance-free. Assessing the maintenance requirements and the available resources for battery maintenance is crucial in choosing a battery that aligns with the user’s capabilities and preferences. -
Environmental Impact:
Considering the environmental impact of the battery is important, especially in applications where sustainability and eco-friendliness are prioritized. Evaluating factors such as the recyclability of the battery, the presence of hazardous materials, and the overall carbon footprint helps make environmentally conscious choices.
How do starter and deep-cycle batteries compare in cycles?
Starter batteries and deep-cycle batteries differ in their cycle life. Starter batteries are designed for high-power bursts to start engines, while deep-cycle batteries provide sustained power. Deep-cycle batteries generally have a longer cycle life compared to starter batteries due to their construction and design.
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Starter Batteries:
Starter batteries are primarily designed to provide a high burst of power for starting engines. They deliver a short, intense burst of energy to crank the engine and get it running. Starter batteries are optimized for quick bursts of power and are not intended for deep discharges or prolonged use. -
Deep-Cycle Batteries:
Deep-cycle batteries, on the other hand, are designed to provide sustained power over longer periods. They are built to handle deep discharges and repeated cycles of charge and discharge. Deep-cycle batteries are commonly used in applications that require continuous power, such as golf carts, RVs, boats, and renewable energy systems. -
Cycle Life Comparison:
When comparing starter batteries and deep-cycle batteries in terms of cycle life, deep-cycle batteries generally have a longer lifespan. The construction and design of deep-cycle batteries allow them to withstand the rigors of deep discharges and repeated charge cycles without significant performance degradation. -
Factors Affecting Cycle Life:
Several factors can impact the cycle life of both starter and deep-cycle batteries. Overcharging, undercharging, and operating the battery outside of its recommended temperature range can reduce the overall cycle life. Proper maintenance, such as regular charging and avoiding deep discharges, can help maximize the cycle life of both battery types.