CR1620 Battery Replacement: Alternatives, Compatibility, And Specifications Explained [Updated On- 2025]

The CR1620 battery can be replaced by equivalents like LM1620, BR1620, and DL1620. These batteries have the same size and voltage as the CR1620. They are commonly used in watches and small electronics. Always check compatibility before making a replacement.

The CR1620 battery is a commonly used lithium coin cell battery. It is compatible with various devices, including calculators, watches, and remote controls. When looking for a replacement, you may consider alternatives such as the CR1616 or the CR1632. However, ensure that these alternatives suit your device’s specifications.

The CR1620 battery has a voltage of 3 volts and a thickness of 2.0 mm. Its diameter is 16 mm. Important specifications include the capacity, generally around 70 mAh, which indicates how long the battery lasts under regular usage. When replacing the CR1620 battery, check if your device can accommodate variations in size and voltage. Using an incompatible battery may lead to device malfunction.

Understanding compatibility is crucial. Before selecting a replacement, review the device manual or contact the manufacturer. This ensures that the new battery will function properly. As you explore your options, keep in mind the importance of effective sourcing for these batteries.

Next, we will delve into where to find these batteries and discuss the implications of choosing high-quality options versus cheaper alternatives.

# Table of Contents

What is a CR1620 Battery and What Are Its Key Specifications?

The CR1620 battery is a type of lithium coin cell battery, commonly used in small electronic devices. It features a diameter of 16mm and a thickness of 2.0mm. These batteries are known for their high energy density and long shelf life.

According to the International Electrotechnical Commission (IEC), the CR1620 is classified under the category of CR series lithium batteries. The organization sets standards for battery specifications, including physical dimensions and voltage ratings.

The CR1620 battery typically has a nominal voltage of 3 volts and a capacity ranging from 50 to 75 mAh (milliamp hours). This allows it to power devices like watches, calculators, and medical devices for an extended period. The “C” in CR1620 indicates it is a lithium chemistry, while “R” refers to round shape.

Energizer defines coin cell batteries as compact power sources designed for devices requiring minimal electricity. This compact design allows for their use in various applications where space is limited.

Factors affecting CR1620 battery performance include temperature, usage patterns, and device power requirements. Extreme temperatures can lead to reduced capacity or even leakage.

Data from industry reports indicates that the global market for lithium batteries, including CR1620 cells, is projected to grow significantly, potentially reaching $100 billion by 2028. This growth reflects rising demand for portable electronics and improved batteries.

The use of CR1620 batteries impacts consumer behavior and encourages the design of more efficient electronic devices. Their portable nature facilitates advancements in compact technology.

In health, CR1620 batteries enable the function of critical devices like glucose meters and heart rate monitors. Environmentally, improper disposal can lead to pollution due to chemicals used in batteries.

Examples include health monitoring devices that rely on CR1620 batteries for accurate readings, influencing treatment decisions for patients.

Solutions to improve battery impact include better recycling programs and developing low-impact battery alternatives. Organizations like the Battery Recycling Coalition promote efficient recycling practices.

Technological advancements in battery design, such as solid-state batteries, may offer safer and more efficient options. Implementing better regulations on battery disposal contributes to minimizing environmental harm.

What is the Voltage and Capacity of a CR1620 Battery?

The CR1620 battery is a type of lithium coin cell battery designed for small electronic devices. It provides a voltage of 3 volts and typically has a capacity of 70 to 80 milliampere-hours (mAh).

The International Electrotechnical Commission (IEC) defines batteries using standard specifications, confirming that CR1620 batteries fall within the lithium coin cell category. These batteries are commonly used in watches, calculators, and medical devices.

This battery type is characterized by its compact size, low self-discharge rate, and reliable power output. It is also known for its lightweight design, making it ideal for portable applications. The CR1620 battery is not rechargeable; once depleted, it must be replaced.

According to the Battery Association of Japan, lithium coin cells are widely used due to their superior energy density compared to alkaline batteries. The global demand for these batteries is projected to increase, driven by the growing consumer electronics market.

The increasing reliance on CR1620 batteries can lead to issues such as battery waste, which impacts the environment due to improper disposal. The accumulation of electronic waste presents challenges for waste management systems.

To mitigate the impacts of battery waste, organizations like the Environmental Protection Agency recommend recycling batteries and promoting the use of rechargeable alternatives. Public education on proper disposal methods is essential to reduce environmental harm.

Implementing battery recycling programs and developing greener battery technologies can further address the challenges associated with CR1620 battery usage. Sustainable approaches will help reduce the ecological footprint of battery consumption.

What Batteries Can Replace a CR1620 Battery?

The CR1620 battery can be replaced by several alternative battery types, including CR1616 and CR1632.

CR1616
CR1632
BR1620
ML1620

The above alternatives vary in size and specifications, which can affect their compatibility with devices.

CR1616: The CR1616 battery is a lithium coin cell battery that is 1.6mm thick and 16mm in diameter. It shares the same diameter as the CR1620 but is thinner. This can make it an option for devices that can accommodate the reduced height. However, the lower capacity may not be suitable for devices requiring longer battery life.
CR1632: The CR1632 battery is another lithium coin cell alternative. It is 3.2mm thick, making it thicker than the CR1620, which can lead to compatibility issues with devices designed for the original battery. However, for devices with flexible design specifications, it can be a usable replacement.
BR1620: The BR1620 is a lithium manganese dioxide battery. It operates in a similar voltage range as the CR1620. It also features superior temperature stability and lower self-discharge rates. This makes it suitable for applications requiring longer life in extreme conditions.
ML1620: The ML1620 is a lithium rechargeable battery that may serve as an alternative. It can provide a different power source for devices designed to take rechargeable cells. Its advantage lies in being eco-friendly and cost-effective over time, provided the device supports rechargeable batteries.

Understanding each replacement’s specifications helps ensure that the chosen battery meets the device’s operational requirements and longevity needs.

Which Batteries Are Compatible with a CR1620?

Several batteries are compatible with a CR1620, primarily including the CR1616, CR1632, and BR1620.

CR1616
CR1632
BR1620

Understanding compatible battery options is essential for ensuring device functionality.

CR1616:
The CR1616 battery is a compatible alternative to the CR1620. It measures 16mm in diameter and 1.6mm in height. While it has the same diameter as the CR1620, it is thinner, making it less suitable for devices requiring more height. Its typically lower capacity can affect performance in high-drain applications.
CR1632:
The CR1632 battery is another acceptable substitute. This battery is 16mm in diameter and 3.2mm in height, making it thicker than the CR1620. Due to its larger size, it will not fit in devices designed for the CR1620 but offers higher capacity for devices that accommodate it. Using a CR1632 may provide a longer lifespan in less constrained devices.
BR1620:
The BR1620 is a lithium battery that shares the same size as the CR1620, featuring a diameter of 16mm and a height of 2.0mm. It offers better performance in extreme temperatures, which makes it an ideal choice for specific applications. While it has similar specifications to the CR1620, the chemistry difference may affect compatibility in some devices.

Understanding these alternatives helps make informed battery replacement choices while ensuring optimal device performance.

How Do CR1616 and CR1632 Compare as Alternatives to CR1620?

CR1616 and CR1632 batteries serve as alternatives to the CR1620, but they differ in size, capacity, and usage context. The CR1616 has a smaller diameter and lower capacity, while the CR1632 has a larger diameter and higher capacity, affecting their compatibility with devices.

Size: The CR1616 has a diameter of 16mm and a thickness of 1.6mm, whereas the CR1620 has the same diameter of 20mm but is 2mm thick. The CR1632 measures 20mm in diameter and is 3.2mm thick. This dimensional difference means the CR1616 cannot fit devices designed for CR1620 or CR1632 batteries.
Capacity: The CR1616 typically has a capacity of around 40mAh, which is lower than the CR1620’s capacity of about 60mAh. In contrast, the CR1632 battery offers approximately 240mAh. This means that the CR1632 has the highest capacity among the three, allowing it to power devices for a more extended period.
Voltage: All three batteries provide a nominal voltage of 3 volts. However, using a battery with a lower capacity, like the CR1616, can lead to shorter device operation times. Conversely, using a CR1632 in a device meant for a CR1620 might provide more power but could lead to fitment issues due to its increased thickness.
Compatibility: Devices explicitly designed for the CR1620 usually benefit from its specific dimensions and capacity. Substituting a CR1616 may result in insufficient power, while using a CR1632 may lead to mechanical fit problems, potentially damaging the device.

In summary, when selecting alternatives to the CR1620 battery, consider the size, capacity, and specific device requirements to ensure proper functionality.

What Are the Applications of CR1620 Batteries?

CR1620 batteries are commonly used in small electronic devices such as calculators, watches, and toys.

Applications of CR1620 Batteries:
– Watches
– Calculators
– Key fobs
– Fitness trackers
– Hearing aids
– Medical devices
– Remote controls

The applications of CR1620 batteries vary based on user needs and device requirements, reflecting both common and specialized usage.

Watches: CR1620 batteries are widely used in wristwatches. They provide a long-lasting power source that supports accurate timekeeping for digital and analog watches.
Calculators: CR1620 batteries power many handheld calculators. Their compact size and stable voltage make them ideal for devices that require consistent performance.
Key Fobs: Many vehicle key fobs use CR1620 batteries. These batteries ensure reliable operation of remote locking and unlocking functions.
Fitness Trackers: CR1620 batteries power several fitness tracking devices. They provide the necessary energy for functions like step counting and heart rate monitoring without frequent replacement.
Hearing Aids: Some hearing aids utilize CR1620 batteries. These batteries are preferred for their performance in devices that require a steady source of power for sound amplification.
Medical Devices: CR1620 batteries are used in various medical devices, including blood pressure monitors. Their reliability is crucial in ensuring accurate health monitoring.
Remote Controls: Many remote controls for televisions and other devices use CR1620 batteries. Their compact size fits well in the sleek designs of remotes.

In conclusion, CR1620 batteries serve diverse applications across everyday devices, providing crucial power for their functionality.

In Which Devices Are CR1620 Batteries Commonly Used?

CR1620 batteries are commonly used in various devices. These devices include wristwatches, calculators, medical devices, and keyless remote entry systems for cars. They also power toys, small electronic devices, and certain fitness trackers. Each of these applications relies on the CR1620 battery for its compact size and reliable performance.

What Factors Should You Consider When Replacing a CR1620 Battery?

To replace a CR1620 battery, consider factors such as compatibility, quality, cost, and environmental impact.

Compatibility with the Device
Battery Quality and Manufacturer Reputation
Cost Considerations
Environmental Impact
Battery Specifications

When making a decision about battery replacement, it is essential to weigh these factors in detail.

Compatibility with the Device:
Compatibility with the device refers to whether the CR1620 battery can fit and function in your specific device. Devices that commonly use CR1620 batteries include watches, calculators, and key fobs. It is crucial to check the device specifications or the user manual to ensure that a CR1620 battery is appropriate. Using a different battery type may lead to malfunction or performance issues.
Battery Quality and Manufacturer Reputation:
Battery quality and manufacturer reputation pertain to the reliability and longevity of the battery. Renowned brands often have better quality control processes, which can lead to improved performance. For instance, batteries from companies like Energizer and Panasonic are known for their consistency. According to a study conducted by Battery University in 2020, reputable brands often provide batteries with up to 30% longer shelf life compared to generic options. Choosing a reputable manufacturer can ensure a more dependable power supply for your devices.
Cost Considerations:
Cost considerations involve evaluating the price against the battery’s lifespan and performance. While cheaper batteries may save money upfront, they often have shorter lifespans. Consequently, they may require more frequent replacements, leading to higher long-term costs. A report by the Consumer Battery Alliance in 2021 indicated that investing in higher-quality batteries can yield savings over time by reducing replacement frequency.
Environmental Impact:
Environmental impact refers to the sustainability and disposal process of the battery. CR1620 batteries contain chemicals that can be harmful if not disposed of properly. Many communities offer recycling programs for batteries to prevent environmental contamination. According to the Environmental Protection Agency (EPA), the proper disposal of batteries is essential to minimize hazardous waste and promote recycling. Choosing batteries from manufacturers who prioritize sustainability can also help reduce your environmental footprint.
Battery Specifications:
Battery specifications include important details such as voltage, chemistry, and energy capacity. The CR1620 battery typically has a voltage of 3V and is made from lithium, offering a good energy density which allows for longer use. Understanding these specifications can help ensure you select a battery that meets both your device’s requirements and your performance expectations. Technical advice from manufacturers such as Duracell highlights the importance of matching specifications for optimal device performance.

What Makes Battery Compatibility Important for Device Functionality?

Battery compatibility is crucial for device functionality as it ensures that devices receive the correct voltage and power levels needed to operate efficiently and safely.

The main points regarding battery compatibility include:

Voltage Specifications
Physical Dimensions
Chemistry Compatibility
Device Safety
Warranty Considerations

Understanding these points allows for a comprehensive view of why battery compatibility matters. While most users may focus on simple replacements, the implications extend further into performance and device longevity.

Voltage Specifications:
Voltage specifications dictate how much electrical potential a battery provides. Compatibility in voltage ensures devices operate within their designed electrical limits. Using a battery with a higher voltage can damage the device, whereas a lower voltage may not provide sufficient power. According to a study by S. H. Ko et al. (2019), mismatched voltage levels account for 30% of electronic device malfunctions reported in warranty claims.
Physical Dimensions:
Physical dimensions refer to the size and shape of the battery. Compatibility in size is essential to ensure the battery fits securely inside the device. If a battery is too large or small, it can lead to poor connections or physical damage. For example, many smartphones rely on specific battery forms like lithium polymer packs that fit within tight spaces, as noted in a report by T. R. Carlson (2021) highlighting design constraints in mobile devices.
Chemistry Compatibility:
Chemistry compatibility involves using batteries with the same chemical composition as originally intended for the device. Lithium-ion, nickel-cadmium, and alkaline are common types. Each has different charging cycles and discharge rates. An example is using a nickel-cadmium battery in a device designed for lithium-ion; this mismatch can affect performance and may even lead to overheating, as explained by J. L. Britz (2020).
Device Safety:
Device safety is a significant concern related to battery compatibility. Non-compatible batteries can pose risks, such as overheating, leaks, or explosions. Safety certifications ensure that batteries meet certain standards for use. For instance, the Underwriters Laboratories (UL) certification guarantees that a battery complies with safety norms, which can prevent hazardous incidents.
Warranty Considerations:
Warranty considerations can also be affected by battery compatibility. Manufacturers often require the use of specific batteries to maintain warranty protection. Using third-party or incompatible batteries can void warranties. According to a consumer rights report by K. M. Jasper (2022), 40% of consumers were unaware that replacing original batteries with non-certified ones could lead to warranty issues.

Overall, battery compatibility plays a vital role in ensuring that devices function properly, operate safely, and remain covered by manufacturer warranties.

How Should You Dispose of a CR1620 Battery Safely?

To dispose of a CR1620 battery safely, you should take it to a designated recycling facility or a battery collection event. CR1620 batteries, like other lithium coin cells, contain materials that can be harmful to the environment if discarded improperly. Approximately 3 billion batteries are sold annually in the U.S., and only about 4% are recycled, highlighting a significant opportunity to improve safe disposal practices.

The disposal process can be categorized into two main methods: recycling and hazardous waste collection. Recycling helps recover valuable materials and prevents environmental contamination. Many communities have recycling kiosks, often located in stores or recycling centers, where consumers can drop off used batteries. Alternatively, local hazardous waste management programs often offer collection days for various types of batteries, including CR1620.

For example, if you have a dead CR1620 battery from a watch or small electronic device, bringing it to a local electronics store with a battery recycling program is an effective way to dispose of it responsibly. Some major retailers provide bins specifically for battery drop-off, making disposal easier and promoting community awareness of battery recycling.

Additional factors that may influence disposal methods include local regulations and environmental policies. Regulations can vary significantly by region. Some areas may have stricter guidelines regarding battery disposal, while others might not have any designated programs at all. It’s essential to check your local waste management guidelines to ensure you are following the correct procedures.

In conclusion, safe disposal of CR1620 batteries involves using recycling facilities or participating in hazardous waste collection programs. By utilizing these methods, you help protect the environment and encourage responsible battery management. For further exploration, consider researching more about the recycling process and the environmental impact of battery waste in different regions.

What Are the Environmental Considerations When Disposing of Batteries?

The environmental considerations when disposing of batteries include several critical factors. Proper battery disposal safeguards ecosystems, human health, and conserves resources through recycling.

Toxic Chemicals
Resource Recovery
Environmental Impact
Health Risks
Recycling Facilities
Regulations and Policies

Understanding the environmental considerations outlined above helps highlight the various perspectives and implications of battery disposal.

Toxic Chemicals:
Toxic chemicals are often present in batteries. Batteries contain substances like lead, cadmium, and mercury. These chemicals can contaminate soil and water if batteries are disposed of improperly. According to the Environmental Protection Agency (EPA), about 40% of mercury in the environment comes from improper battery disposal. Instances of hazardous waste leaching into groundwater can lead to severe environmental degradation, affecting drinking water sources and terrestrial ecosystems.
Resource Recovery:
Resource recovery focuses on reclaiming valuable materials from used batteries. Many batteries contain recyclable components like lithium, cobalt, and nickel. Recovered materials can significantly reduce the need for new resource extraction, which often has substantial environmental consequences. A study by the International Energy Agency (IEA) shows that recycling lithium from lithium-ion batteries can recover over 95% of the material for reuse. This process diminishes the ecological footprint associated with mining new resources.
Environmental Impact:
The environmental impact of battery disposal is substantial. Improperly discarded batteries contribute to pollution. The accumulation of batteries in landfills raises concerns due to the potential release of hazardous materials. The European Union’s Waste Electrical and Electronic Equipment (WEEE) directive reflects this concern, mandating the responsible disposal and recycling of batteries to minimize environmental harm.
Health Risks:
Health risks from improper battery disposal can affect communities near disposal sites. Exposure to toxic substances released from batteries can lead to various health issues, including respiratory problems and skin conditions. The World Health Organization (WHO) highlights that populations living near waste disposal sites experience a higher prevalence of certain diseases due to exposure to hazardous waste.
Recycling Facilities:
Recycling facilities play a crucial role in the safe disposal of batteries. Numerous facilities across the globe specialize in the proper recycling of batteries to ensure minimal environmental harm. These facilities utilize advanced technologies to break down battery components and extract valuable materials. The National Recycling Coalition advocates for improved access to recycling facilities to promote responsible battery disposal and resource recovery.
Regulations and Policies:
Regulations and policies govern battery disposal practices. Local and national governments have established specific guidelines for battery disposal and recycling. For example, the Battery Act in the United States mandates the recycling of rechargeable batteries and prohibits the disposal of certain types of batteries in landfills. These regulations aim to protect public health and the environment through responsible waste management practices.

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