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5 Must-Have Features in a Lithium Battery Testing Equipment

Mastering Battery Testing: Everything you Need to Know - Averna

Battery Types

There are many different battery types, each with their own advantages and disadvantages. Different industries base their selections on the specific requirements of the application. Generally, manufacturers will consider cost, energy density, cycle life, and environmental impact when selecting the appropriate battery type for a given application. 

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Different battery types include:  

Lithium-ion (Li-ion) 

Li-ion batteries use lithium-ion chemistry, which is known for its high energy density making them lightweight and compact. They have gained popularity in automotive, consumer devices and portable medical instruments due to their high energy density, longer cycle life, lower self-discharge rate and relatively lightweight design. They are used for both propulsion and auxiliary power in modern vehicles. With their long cycle life, they are ideal for devices that experience frequent charge and discharge cycles and are extremely reliable. On the flip side, Li-ion batteries can be more expensive to manufacture and can be damaged if overcharged, potentially leading to safety issues. Disposal and recycling of Li-ion batteries require careful management due to their chemistry. 

Lead-Acid Batteries 

Lead-acid batteries use a lead dioxide positive electrode, a sponge lead negative electrode, and a sulfuric acid electrolyte. They are relatively inexpensive to produce, making them popular for automotive and industrial applications. They are also used in larger medical equipment, such as uninterruptible power supplies (UPS) for hospitals or backup power systems, but they are heavy and have low energy density, making them less suitable for portable applications. They can handle deep discharges and provide a reliable source of power but there is a limited number of charge and discharge cycles before their performance degrades. 

These are the traditional and most widely used batteries in internal combustion engine (ICE) vehicles. They are affordable and provide the necessary cranking power to start the engine. Absorbent Glass Mat (AGM) Batteries are a variation of lead-acid batteries that offer improved performance, especially in start-stop systems and vehicles with higher electrical loads. 

Nickel-Cadmium (NiCd) Batteries 

NiCd batteries use a nickel oxide-hydroxide positive electrode, a cadmium negative electrode, and a potassium hydroxide electrolyte. Cadmium is toxic, so NiCd batteries pose environmental concerns and require proper recycling. They are known for their durability and resistance to extreme temperatures. They can provide high current output, making them suitable for power tools and other high-demand applications and can endure many charge and discharge cycles. NiCd batteries are known to experience the memory effect, which reduces capacity if not discharged fully before recharging and have lower energy density. 

Nickel-Metal Hydride (NiMH) Batteries: 

NiMH batteries are used in medical devices where cost-effectiveness and environmental considerations are important. These batteries are less toxic than NiCd batteries, which makes them more environmentally friendly. They have a relatively high energy density, are cost-effective and have a relatively low self-discharge rate making them suitable for certain portable medical equipment and devices that aren't constantly in use. NiMH batteries have been used in hybrid vehicles for many years.  

Alkaline Batteries: 

Alkaline batteries have a long shelf life, making them suitable for devices that may be stored for extended periods. They can often be found in many forgotten drawers in homes since they are commonly used for remote controls, flashlights, toys, etc. That said, they are also often used in single-use or disposable medical devices, like hearing aids since they are cost-effective and readily available. 

Zinc-Carbon Batteries: 

Zinc-carbon batteries are the least expensive option and are used in very basic consumer electronics like low-cost toys, clocks, and small gadgets. They have a shorter lifespan and are typically non-rechargeable. 

Lithium Polymer (LiPo) Batteries: 

LiPo batteries are a variation of Li-ion batteries and are known for their flexibility in terms of shape and size. They are used in slim and lightweight devices, such as drones, remote-controlled toys, and some smaller laptops. LiPo batteries are often chosen when manufacturers need custom-shaped batteries to fit within specific device designs. 

Custom Battery Packs: 

Alternately it is not uncommon for medical device manufacturers or electronics manufacturers to customize batteries to meet specific voltage, capacity, and size requirements. Custom packs can include various battery chemistries, such as Li-ion, Li-polymer, or NiMH, tailored to the device's needs. 

Solid-State Batteries: 

While still in development and not as commonly used as the previous types, solid-state batteries are gaining attention in the automotive industry due to their potential for higher energy density, longer life, and improved safety. They are being researched and developed for use in electric vehicles. 

Battery Testing

There are many considerations that need to be made when designing and setting up the test process for battery manufacturing. Safety must always be a top priority considering the high-power ad and high-voltage applications that need to run. Some common battery test cases include: 

Voltage Testing  

Voltage testing is a fundamental step in battery manufacturing to ensure the quality, performance, and safety of the batteries produced and it covers a lot of ground in battery manufacturing.  

It is important to measure the open circuit voltage (OCV) of the battery, which is the voltage when there is no load or current flowing. OCV is a crucial parameter as it provides an indication of the battery's state of charge. It helps ensure that the battery has been properly charged during the manufacturing process. It is important to verify that individual cells within a battery pack have consistent voltage levels. This ensures that they contribute equally to the overall performance of the battery pack.  

In a multi-cell battery pack, voltage testing checks for cell balancing. It ensures that none of the cells are overcharged or undercharged, which can lead to issues like reduced capacity, overheating, and reduced battery life. If a cell has a significantly lower or higher voltage than the others, it may indicate a defective cell that should be replaced before further assembly. Voltage testing may also include measuring the battery's voltage while it is under a specific load. This test helps assess the battery's ability to maintain a stable voltage during operation, which is essential for the reliable performance of the battery in its intended application. It is also important to check if the battery's voltage falls within a specified tolerance range. This range is typically defined by the battery's design and the manufacturer's specifications. Deviations from this range may indicate quality issues or defects. 

Voltage testing can also verify that safety features like overcharge protection or over-discharge protection are functioning correctly. These features prevent the battery from exceeding safe voltage levels. In some cases, voltage testing may include subjecting the battery to voltage stress tests to simulate real-world conditions. This is especially important for automotive and industrial batteries, where they may experience varying loads and environmental conditions. 

Current Testing  

Current testing is essential to verify that the battery can reliably deliver the required power and energy for its intended use while maintaining safety and performance standards. Current testing helps determine the battery's capacity, which is its ability to store and deliver energy. By discharging the battery at a specified current rate, the test measures the time it takes for the battery to reach a specific voltage cutoff. The capacity is then calculated based on the discharge time and current, providing information about how much energy the battery can store and deliver.  

Current testing assesses the battery's ability to deliver power at different rates. By applying varying discharge rates, manufacturers can evaluate how the battery performs under different load conditions. This is crucial in applications where the battery must provide high power, such as in electric vehicles or power tools. It also measures the voltage response of the battery when subjected to different discharge currents. It checks how the battery voltage changes as it delivers current, ensuring that the voltage remains within acceptable limits for the intended application. 

Some batteries, especially in automotive applications, need to handle peak current demands during high-stress situations like starting a vehicle or rapid acceleration. Current testing verifies the battery's ability to deliver these peak currents without issues such as voltage drop or overheating. Like voltage testing, in multi-cell battery packs, current testing verifies that individual cells within the pack contribute equally to the overall current output. An imbalance in current distribution can lead to overloading some cells, reducing battery life. 

 It is also important to verify that the battery includes overcurrent protection mechanisms and that they are working properly. These mechanisms help prevent damage to the battery and associated equipment in cases of excessive current flow, like short circuits. Additionally, the battery's ability to maintain a stable output current when subjected to varying loads or sudden changes in load must be tested and the temperature changes within the battery must be monitored. Excessive temperature increases can be indicative of inefficiencies or safety concerns. 

Capacity Testing 

Capacity testing measures the actual amount of energy a battery can store and subsequently release under specific conditions. It primarily involves a discharge test. During this test, the battery is discharged at a controlled current rate, typically referred to as the C-rate. The discharge process continues until the battery's voltage reaches a specified cutoff voltage. Throughout the discharge test, the current flowing from the battery and the time it takes to reach the cutoff voltage are continuously measured. The product of current and time provides the discharge capacity in ampere-hours (Ah) or watt-hours (Wh), depending on the intended application. The measured capacity is compared to the battery's rated or nominal capacity to ensure that it meets the manufacturer's specifications. Any significant deviation from the nominal capacity may indicate a quality issue or potential defect. 

Impedance Testing 

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Impedance testing assesses a battery's internal resistance. High impedance can lead to reduced efficiency and shorter lifespan. Testing involves applying an AC signal to the battery while measuring the voltage and current response. There are several parameters that are measured including: 

DC Resistance (R_dc): This measures the direct current (DC) resistance within the battery, which is primarily due to the resistance of the electrolyte, electrodes, and other internal components. Higher DC resistance can indicate issues like electrode degradation or cell aging. 

AC Impedance Spectroscopy: By varying the frequency of the AC signal, manufacturers can obtain a detailed impedance spectrum that reveals information about the battery's internal structure, including resistance and capacitance. This method allows for the identification of specific impedance components at different frequencies. 

Safety Assessment: Impedance testing is critical for evaluating the safety of batteries, especially in applications where thermal runaway (e.g., in lithium-ion batteries) could lead to safety hazards. High internal resistance or irregular impedance patterns may indicate potential safety risks. 

Comparative Testing: Manufacturers can use impedance testing to compare different battery designs, materials, and manufacturing processes to optimize performance and safety. 

The results from impedance testing results provide valuable insights into the battery like the State of Health (SoH), State of Charge (SoC) and overall quality.  

Cycle Testing 

Also known as charge-discharge cycling or cycle life testing, cycle testing simulates charging and discharging cycles to evaluate a battery's long-term performance and durability. During cycle testing, the battery is subjected to a predefined pattern of charging and discharging cycles. The pattern can vary depending on the intended application and manufacturer's specifications. Several parameters are monitored during cycle testing, including voltage, current, temperature, capacity and internal resistance. 

The primary goal of cycle testing is to determine the battery's cycle life, which is the number of charge and discharge cycles it can endure while maintaining specified performance and capacity levels. The battery's cycle life can vary significantly based on its chemistry, design, and the depth of discharge during each cycle. This can reveal how and when a battery fails. Failures may include reduced capacity, increased internal resistance, or safety issues such as thermal runaway. Understanding failures is the most effective way to improve battery designs and identify potential issues early in the manufacturing process. The data is also used to help set warranty terms and to assure customers of the battery's long-term reliability. 

Safety Features for Battery Test Chambers

Lithium-ion batteries have changed the world since they emerged commercially in the early s. They've directly influenced the rise of portable handheld devices, while also opening the possibilities for electric vehicles (EVs), drones and military and defense uses, and led to renewable energy options.

As companies strive to produce longer-lasting, faster-charging batteries, they require equipment that enables them to conduct safe and efficient battery testing.

Battery test chambers must include features to promote the safety of users. Associated Environmental Systems developed AES SAFE for this purpose.

Battery Test Chamber Safety Features: AES SAFE & EUCAR Hazard Levels

Companies push the limits of their batteries during various types of battery testing, including performance and durability. As a result, battery test chambers need to sustain events without risking the safety of the users or the lab as a whole.

Building on EUCAR hazard levels, AES has introduced AES SAFE for its line of battery test chambers. AES SAFE chambers have the required safety measures to mitigate circumstances that could lead to a battery thermal event (BTE), so you can innovate with confidence and keep your lab and users' safety in mind. 

For instance, if you're testing to Severity Level 2'described as an irreversible defect or damage to a cell without leakage, flame, or rupture'set temperature limits, standard on AES chambers, are appropriate.

However, as you move to Severity Levels 3 through 7, you'll need greater measures in place: burst disk, product thermocouples, safety purge, and optional gas sensors.

Here's a breakdown of the features available:

Emergency Stop

This button enables you to rapidly disrupt the entire function of the battery test chamber.

Set Point Temperature Limit

A temperature control feature prevents a user from unintentionally setting temperatures beyond the established testing limits.

High/Low Temperature Limit

On a related note, this feature operates independently of the set point temperature limit, ensuring the control temperature limit doesn't exceed what is safe for cells. For instance, AES's ATP chambers do not exceed -20°C and 80°C.

Audible & Visual Alarm

A loud sound is emitted when an emergency condition is at play, while visual cues reveal the current status of the chamber. A three-color system guides safe use: green indicates a chamber is ready for use and the door is unlocked, blue signals the chamber is in use and the door locked, and red announces the chamber is in alarm condition with the door locked.

Rapid Temperature Change

Safety feature in place to monitor and detects when a rapid temperature shift occurs.

Reinforcement

A reinforced stainless steel interior provides the durability necessary to conduct high-stakes battery testing.

Temperature Limited Sheath Heaters

The stainless steel, finned tubular heaters with a temperature sensor limit the maximum operating temperature of your battery test chamber.

Burst Disk/Low Flow Vent

Made from graphite, this burst disk contains rupture sensors that trigger your alarm system.

Door Lock

Not only should your chamber have a fail-safe rotary cam door to ensure it locks, but a mechanical override in case some electrical components malfunction. A cam position sensor indicates whether the door is locked. Most chambers will not function with an open or unlocked door.

Gas Sensors (Optional)

These sensors monitor the chamber for combustible gasses.

Product Sensors

Installed on the rear of the chamber, these sensors enable you to monitor the products under test.

Safety Purge

When the test chamber is in an alarm state, this device triggers an inert gas purge.

Chamber Alarm Input

When the external terminal block's voltage signal is disrupted, this feature triggers an alarm state and the entire chamber shuts down.

Chamber Alarm Output

This feature is intended to safely disable test equipment for a device under testing. While the chamber remains powered and in a safe state, the contact closes. However, a power loss or alarm condition opens the contacts.

Below outlines the recommended safety features for each severity level:

  • Severity Level 1 (reversible loss of function) and Severity Level 2 (irreversible defect/damage) rely on the high/low temperature limit and set point temperature limit features.
  • When reaching Severity Level 3 (leakage with mass change less than 50%) and Severity Level 4 (venting with mass change greater than 50%), you'll need several more safety features: emergency stop, chamber alarm input, chamber alarm output, product sensors, reinforcement, safety purge, low flow burst disk, temperature limited sheath heaters, audible and visual alarms, and door lock.
  • At Severity Level 5 (fire or flame), Severity Level 6 (Rupture), and Severity Level 7 (explosion), you get all the aforementioned features plus optional gas sensing features. Naturally, an expansive suite of safety features becomes more vital as battery testing becomes riskier as batteries are pushed to their limits.

Other Battery Testing Safety Considerations

As much as the safety features of a battery test chamber matter, they can be compromised by poor education and lack of maintenance. Users who employ the test chamber should be fully informed on everything from proper operations and installation to incident response. While human error can't be eliminated, it can be minimized to avoid accidents.

For instance, a well-designed battery testing solution (such as AES's ATP series, which includes ATPPRIME, ATPHEAVY, and ATPFLEX) limits waste as defined in lean manufacturing principles, maximizes efficiency, and is an easy test to set up'users can safely swap in battery cells without jeopardizing testing results. 

Safety considerations are even more important when working with high-density or high-amperage batteries, due to their increased volatility and threat of thermal runaway events. Fortunately, advanced battery testing safety features give you peace of mind when working on the edge of the future, particularly the wide variety of batteries emerging in the automotive industry. 

Working with lithium-ion batteries takes responsibility, and you'll need to dedicate serious time and resources to conduct tests safely. The payoff, however, can change your industry, if not the world at large.

For more Lithium Battery Testing Equipmentinformation, please contact us. We will provide professional answers.

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