4 Advice to Choose a Cylindrical Lithium Cells

Jul. 28, 2025

38 0 0

Choosing the Right Lithium Battery Cells: Essential Tips for ...

Choosing the correct lithium battery cells is a crucial step in designing an efficient and reliable battery system for your project. With a wide array of options available, it’s essential to carefully evaluate various technical factors to ensure optimal performance, safety, and longevity. In this guide, we’ll break down the key considerations for selecting lithium battery cells, offering clear guidance and practical examples to help you make informed decisions.

If you are looking for more details, kindly visit Xiaolu.

Understanding Capacity and Energy Density

Capacity is the measure of how much electrical charge a battery cell can store, typically measured in ampere-hours (Ah) or milliampere-hours (mAh). To determine the appropriate capacity for your project, consider your energy requirements and runtime expectations.

Energy density represents the amount of energy stored per unit volume or weight. While higher energy density cells can store more energy in a smaller or lighter package, they may come with a higher cost.

Example: If your project demands a long runtime and space is not a constraint, you might choose battery cells with higher capacity and moderate energy density, such as the NCRGA.

Voltage and Configuration: Matching Your Project’s Needs

Lithium battery cells come in various voltages—typically 3.2V, 3.6V, or 3.7V—depending on the specific lithium chemistry. To select the right voltage, you need to consider your project’s voltage requirements and the configuration of your battery system.

Series Configuration: Increases the total voltage by connecting cells in series.

Parallel Configuration: Increases capacity by connecting cells in parallel.

Example: For a project requiring a 12V system, you could use four 3.7V lithium cells connected in series to achieve the desired voltage.

Choosing the Right Chemistry

Different lithium battery chemistries offer varying performance characteristics, cycle life, and safety features. Common chemistries include:

Lithium Cobalt Oxide (LiCoO2)
Lithium Iron Phosphate (LiFePO4)
Lithium Nickel Manganese Cobalt Oxide (NMC)
Lithium Nickel Cobalt Aluminum Oxide (NCA)

When choosing the chemistry, consider factors like energy density, discharge rate, temperature range, and safety. If you’re debating between lithium-ion and lithium-polymer batteries, our article on the benefits of lithium-Ion batteries over lithium-polymer batteries provides an in-depth comparison that might help clarify your decision.

Example: If your project requires high discharge rates, LiFePO4 cells are a solid choice due to their excellent thermal stability and robust safety profile.

Discharge Rate and Pulse Performance

The discharge rate indicates how much current a battery can provide continuously or in bursts. It’s vital to ensure that the battery cells can handle your project’s current demands without sacrificing performance or longevity.

Example: For projects involving power-hungry devices that need high current bursts, select cells with strong pulse discharge capabilities, like the INR-30Q.

Cycle Life and Longevity: Planning for the Long Term

Cycle life refers to the number of charge-discharge cycles a battery can undergo before its capacity significantly diminishes. If your project involves frequent use and requires a long lifespan, opt for cells with a high cycle life.

Example: For long-term projects with frequent charging cycles, consider cells like the LG MJ1 or Samsung 35E, known for their high cycle life.

Environmental Considerations and Temperature Management

Lithium battery performance can vary significantly with changes in temperature. High temperatures can accelerate degradation, while low temperatures can reduce the available capacity. If your project operates in extreme conditions, consider cells designed for high or low-temperature performance, and explore temperature management solutions like passive or active cooling systems. For a deeper dive into how extreme weather conditions can affect battery performance, check out our article on battery weather characteristics.

Prioritizing Safety Features and Certification

Safety should always be a top priority when selecting battery cells. Look for cells equipped with built-in safety features, such as:

Overcharge protection
Over-discharge protection
Short-circuit protection
Temperature monitoring

Additionally, ensure that the cells comply with relevant safety certifications like UL or IEC to minimize the risk of accidents.

Example: Cells that meet certifications like UL or IEC provide extra confidence in the safety and durability of your battery system.

Size and Form Factor: Fitting Your Design Constraints

Consider the physical size and form factor of the battery cells to ensure they fit seamlessly into your project’s battery pack or system. Measure the available space and any weight restrictions before making your choice.

Example: For a compact battery pack, cells like the or , known for their small form factor, would be ideal.

Supplier Reputation and Support: Ensuring Quality and Reliability

Choosing a reputable supplier is essential for sourcing high-quality lithium battery cells. Research suppliers by looking at their track record, customer reviews, and their ability to provide technical support and after-sales service.

Example: Opt for suppliers with a proven industry reputation, positive customer feedback, and responsive technical support to ensure a smooth and reliable procurement process.

Custom Battery Pack Design and Prototyping

If your project requires a unique battery solution, custom battery pack design might be the answer. When designing a custom pack, it’s crucial to consider factors such as cell selection, thermal management, and physical layout. Prototyping plays a vital role in this process, allowing for the testing and refinement of the design before moving to full-scale production.

At Dan-Tech Energy, we focus on creating battery packs that meet the exact needs of your project. Our approach involves close collaboration with you to develop and prototype designs that ensure your battery system is both efficient and reliable, tailored to your specific requirements.

Ready to get started? Submit your battery pack specifications via Toolbox and we’ll work together with you to develop a custom-designed battery pack to fit your exact requirements.

‍

Conclusion: Setting the Foundation for Success

Selecting the right lithium battery cells for your project is a decision that will significantly impact your battery system’s performance, safety, and longevity. By considering factors like capacity, voltage, chemistry, discharge rate, cycle life, safety features, size, and supplier reputation, you can make informed choices that align with your project’s specific needs.

‍‍

For more Cylindrical Lithium Cellsinformation, please contact us. We will provide professional answers.

Explore more:
Chelates for cleaning products - Nouryon

Pros and Cons of Lithium Prismatic Cells vs Cylindrical Cells

Due to the vast shapes of electronics and other applications that function on battery power, battery cells also come in different shapes to fit the application. Two common types of shapes are prismatic cells and cylindrical cells. Both offer specific qualities to the application, whether you are looking for cost-effective batteries that are easy to mass produce or batteries with a higher capacity range.

Yet keep in mind that these two batteries have some functional differences. Selecting the right cell can greatly influence the design of your product, the available power, and what may occur if there is a cell failure.

Battery Cell Shapes and Sizes

Both cells have distinct shapes that can accommodate different devices. Cylindrical cells are long and round, much like the batteries found in toys, remote controls, and other devices. It's constructed by encasing electrodes that are wound tightly. Then they are placed into a specially designed metal can. This shape offers smaller sizes.

Example of cylindrical and prismatic battery cells.

Cylindrical cells are the most common cell shapes that are used in our daily lives and for various applications. This round shape allows for both the electrolyte and the internal pressure to be evenly distributed. So, there is a less likely chance of leaks or cell bloating.

Prismatic cells have flat and rectangular shapes. They have everything inside sandwiched into layers and are encased in steel or aluminum. An insulated film covers the outside of the can. This shape allows for the battery to save space inside the application as prismatic cells are commonly found in electric and hybrid vehicles. The shape of prismatic cells is quite larger than cylindrical cells.

One concern with prismatic cell shapes involves the pointed corners. These corners could experience more stress such as shocks and vibrations based on the application, making them weaker if not protected effectively in an enclosure. The corners also could not allow for the electrolyte to be distributed throughout, which may cause cell bloating and other deformations.

Prismatic cells come in varying sizes. There are no universal format types that every manufacturer adheres to, so they may design several specific shapes. Cylindrical cells do have universal format types between manufacturers, such as , , , and to name a few. Because there are no universal types of prismatic cells this means that most models are custom builds, which also means the customers need to be cognizant of minimum order quantities and what certifications need to be attained.

Voltages and Capacities

When it comes to voltages and capacities, there are key advantages and disadvantages to both cell forms. Prismatic cells are larger in size than cylindrical cells and have fewer connections in the application. So prismatic cells allow for larger capacities. For example, one lithium phosphate battery (LifePO4) in prismatic cell form has 3.2 volts 100ah.

On the other hand, cylindrical cells have more connections in the application and come in smaller sizes that allow for less energy storage. Even with the lower capacity, cylindrical cells have more voltage power. They provide faster discharge rates in per amp hours (Ah) due to requiring more connections.

For cylindrical cells to reach the same amp hours as one prismatic cell, you would need to have 18 cylindrical cells. To reach 48 volts for both battery cell shapes, you would require 18 prismatic cells and 16 groups of 18 cells.

So, while you would need more cylindrical cells to achieve the same capacity as prismatic cells, you have better energy efficiency with cylindrical cells. It's due to this reason that cylindrical cells are used more often in high-performance applications such as toys and electronics for longer-lasting battery life. Prismatic cell shapes are better suited for energy-intensive applications such as storage systems, medical devices, and vehicles.

Build and Lifecycle

Placing multiple cells into a battery pack requires a specific alignment for each battery shape. Cylindrical cells are stacked in several series and parallels. There may be 12 batteries aligned as three rows of four cells or four rows of three cells depending on the space available in the application. The shape of the round cells offers maximum airflow between each cell for better temperature control. The heat can dissipate quickly for better performance.

Prismatic cells are usually only stacked in a series. Due to the rectangular shape, the cells can touch one another. Unfortunately, this stacking does not allow for air to travel between the cells. The prismatic cells cannot discharge heat as quickly, instead, they can pass between the cell's walls into the next adjacent cell.

Typical prismatic cells may have lifecycles averaging around cycles. Cylindrical cells have less of a lifespan ranging between 300 to 500 cycles. An important thing to understand about battery cell lifecycles is how one bad cell can impact the rest of the cells within the pack. If one cylindrical cell goes bad, the many connections and the pack build are not impacted by the bad cell as the pack can continue to provide power as the capacity is dictated by the lowest capacity within the group. For prismatic cells, one bad cell can impact the entire battery pack based on how the cells are placed in the series.

Battery Testing, Certifications, and Costs

All battery packs no matter their shape should undergo the required testing based on their cell chemistry, industry requirements, and customer specifications. Testing and certification are typical requirements for lithium battery chemistries for both cylindrical and prismatic cells.

When it comes to costs, cylindrical cells are easier to manufacture as the technologies have been around for generations. Prismatic cells may cost more, yet the prices will also be based on the size of the cells and the volume of the order. Customers should also keep in mind that certain battery chemistries, such as lithium batteries, may have increased costs due to the testing and certification that is required compared to other nickel-based chemistries.

If trying to determine the best battery shape for your budget, this factor will depend on the application's power needs, lifecycle, and how much you want to spend. One type of battery cell is not actually better than the other. While prismatic cells offer better long-term capacity, they have higher prices. Cylindrical cells are cheaper to manufacture, have better thermal management, and are less likely to bloat, leak, or rupture. Yet cylindrical cells have lower capacities and may require larger volume purchases to obtain the same capacity as a prismatic cell.

The one thing that is most overlooked when discussing prismatic cells is that while many sizes are available, they are not an off-the-shelf product. That means that getting small quantities and samples may be difficult given the fact that most manufacturers need a minimum order amount to run off enough raw materials (anodes/cathodes) to make the production run worthwhile. Be sure to ask your supplier which sizes they run on a regular basis if your requirements are less than 5,000 pieces. If your estimated annual usage is over that amount, then it may make sense but keep in mind that if you require samples to do testing, they will usually be made in a sample lab and will have some differences from the full production models.

Another key item to be aware of when looking at using a custom-sized prismatic pack is the certifications. When getting started these cells will need to go through UL and UN 38.3 certification for safety and transportation requirements. Once the cells pass these certifications, they may need to be updated yearly, which the manufacturing site usually manages for high-volume customers. If you are right on the minimum order quantity where the factory may not need to run them again for 18-24 months, you will need to make sure that you plan for them to keep the UL file current every year otherwise it will run out and you will have to pay to get the certification back to active.

Summary

Battery pack manufacturers will state the minimum purchase requirements for both prismatic and cylindrical cells. Some companies only offer one shape of cell or battery chemistry while others offer more variety. When it comes to selecting the best cell for your application, speaking with your manufacturer can help you determine the right better power for your needs.

If you are looking for more details, kindly visit Cylindrical Cell.

Key Takeaways

¿NPK 20-20-20 realmente mejora el crecimiento de tus plantas?

Chelates for cleaning products - Nouryon

Comments

0/2000

Guest Posts

If you are interested in sending in a Guest Blogger Submission,welcome to write for us!