Edison Cell Battery Size: Specs, Weight, and Insights on NiFe Technology

Edison cells have a nominal voltage of 1.2 volts. Their dimensions vary by design, with common sizes like 167 x 162 x 345 mm. These nickel-iron batteries offer different capacities, such as 100 Ah at 12, 24, or 48 volts. This variety ensures reliability and suitability for various applications.

The key specification is the nickel-iron (NiFe) technology, which provides greater durability and a longer lifespan. NiFe batteries are known for their ability to withstand deep discharges, making them ideal for renewable energy systems. Their weight, while sometimes a limitation, contributes to their stability and reliability in operation.

One critical advantage of the Edison cell battery is its eco-friendliness. The materials used are abundant and non-toxic. This attribute aligns with the increasing need for sustainable energy solutions.

As renewable energy technologies continue to evolve, understanding the weight and specifications of these batteries becomes essential. The next section will explore the practical applications of Edison cell batteries in modern energy systems, emphasizing their performance and longevity in real-world settings.

What Are the Key Features of the Edison Cell Battery?

The key features of the Edison Cell Battery include its long lifespan, resistance to overcharging, use of non-toxic materials, and excellent deep discharge capabilities.

1. Long lifespan
2. Resistance to overcharging
3. Use of non-toxic materials
4. Excellent deep discharge capabilities

The Edison Cell Battery offers various advantages and attributes. These features appeal to different user preferences and environmental considerations. Understanding these attributes can help assess its practicality for various applications.

1. Long Lifespan: The Edison Cell Battery exhibits a long lifespan, often exceeding 20 years. According to various studies, its robust design supports over 5,000 charging cycles. This longevity significantly reduces replacement costs and environmental waste compared to traditional batteries, which typically last around 2-5 years.

2. Resistance to Overcharging: The Edison Cell Battery has a high tolerance to overcharging. This characteristic prevents damage to the cells, enhancing safety and longevity. The battery can remain connected to a charger without the risk of overheating or degradation, allowing for greater user convenience and reliability.

3. Use of Non-Toxic Materials: The materials used in the Edison Cell Battery are non-toxic, which makes it an environmentally friendly option. The primary components include nickel and iron, which are less harmful compared to lead used in conventional batteries. This feature appeals to eco-conscious consumers and industries seeking sustainable energy solutions.

4. Excellent Deep Discharge Capabilities: The Edison Cell Battery supports deep discharges without compromising performance. Users can discharge the battery to near-empty levels without damaging it, which is beneficial in applications where consistent power is required over extended periods. This feature enhances its suitability for renewable energy systems, such as solar power storage.

In summary, the Edison Cell Battery presents significant advantages. Its durability, safety, eco-friendliness, and reliability cater to diverse user needs across various sectors.

What Are the Exact Dimensions of the Edison Cell Battery?

The exact dimensions of the Edison cell battery, also known as the Nickel-Iron (NiFe) battery, are approximately 12 inches in height and 6 inches in diameter.

Key Specifications of the Edison Cell Battery:
1. Standard Height: 12 inches
2. Standard Diameter: 6 inches
3. Weight: Approximately 128 pounds
4. Cell Configuration: Vertical cylindrical design
5. Capacity: Ranges from 100 to 300 amp-hours, depending on the specific model

These specifications provide a general idea of the size and capacity of the Edison cell battery, but different configurations may vary slightly. Understanding the specific dimensions and attributes of the Edison cell battery is crucial for various applications, particularly in renewable energy systems.

1. Standard Height:
   The standard height is 12 inches. This size makes the battery suitable for several applications, including off-grid solar systems and electric vehicles. Its vertical structure allows efficient use of space.

2. Standard Diameter:
   The standard diameter of the Edison cell battery is 6 inches. This diameter contributes to the lightweight design, which is beneficial for mobility and installation in various setups.

3. Weight:
   The battery weighs approximately 128 pounds. This weight reflects its robust construction, which contributes to its longevity and durability. It is heavier than many modern batteries, but this is offset by its long lifecycle.

4. Cell Configuration:
   The Edison cell battery features a vertical cylindrical design. This design helps in effective heat dissipation, enhancing battery performance. The configuration also impacts the installation and space requirements.

5. Capacity:
   The Edison cell battery’s capacity ranges from 100 to 300 amp-hours. This range enables varied usage scenarios, from small-scale applications to larger, more demanding systems. The capacity is essential for energy storage and output duration.

Understanding these dimensions and specifications helps users select the right battery for their needs, ensuring compatibility and optimal performance in energy storage applications.

How Do the Dimensions Impact the Battery’s Efficiency?

The dimensions of a battery significantly impact its efficiency by influencing energy density, heat management, internal resistance, and overall capacity. These factors play crucial roles in the battery’s performance and lifespan.

Energy density: The dimensions affect how much energy a battery can store in a given volume. Larger batteries can hold more active material, which increases total energy capacity. Research by K. K. Kar et al. (2018) showed that larger lithium-ion batteries could achieve 250 Wh/kg energy density, while smaller batteries often fall below 150 Wh/kg.

Heat management: The physical size of the battery influences its ability to dissipate heat. A larger battery can spread heat over a greater surface area, reducing hotspots and enhancing thermal stability. A study by Zhao et al. (2020) indicated that effective thermal management in larger batteries increased their efficiency by 15%.

Internal resistance: Smaller battery dimensions tend to have higher internal resistance due to shorter pathways for current flow. High internal resistance leads to energy loss in the form of heat. A 2019 study by M. R. Sahu highlighted that optimizing battery dimensions can reduce internal resistance by as much as 20%, improving overall efficiency.

Overall capacity: The overall dimensions dictate the total volume and surface area available for electrodes. Larger batteries often provide increased surface area for electrochemical reactions, enhancing charge and discharge rates. According to research by X. Wang et al. (2021), increasing electrode surface area can improve capacity utilization by up to 30%.

These factors demonstrate that battery dimensions directly influence efficiency, energy storage, thermal management, and internal resistance, ultimately determining the effectiveness and life of the battery.

What Is the Weight of the Edison Cell Battery?

The Edison cell battery, known as the nickel-iron (NiFe) battery, is a rechargeable battery invented by Thomas Edison in the late 19th century. This battery typically weighs between 25 to 30 kilograms (55 to 66 pounds) per cell, depending on the size and construction.

According to the U.S. Department of Energy, the Edison cell battery is notable for its durability and longevity. It is designed for applications that require a robust and long-lasting energy source, such as in electric vehicles and off-grid energy storage.

The Edison cell battery consists of nickel oxide and iron electrodes. It operates with an alkaline electrolyte, which allows for efficient charge and discharge cycles. Its design offers advantages such as a long lifecycle, low maintenance needs, and resistance to overcharging.

The Encyclopedia of Energy describes the Edison cell battery as having a high tolerance for deep discharges and a relatively stable output voltage. However, its lower energy density compared to modern lithium-ion batteries limits its use in certain applications.

Factors such as operational temperature, charging habits, and cycle life can influence the performance and weight of the Edison cell battery. Its construction materials also contribute to its overall weight.

The average energy capacity of a NiFe battery cell ranges from 80 to 100 ampere-hours. This indicates an efficient storage potential for diverse applications.

The broader impact of Edison cell batteries includes their role in renewable energy storage systems, supporting a shift to cleaner energy technologies.

Additionally, NiFe batteries contribute to reducing reliance on lead-acid batteries, which have negative environmental impacts through toxic lead leakage.

Examples of their applications include renewable energy systems, such as solar or wind energy installations, which benefit from energy storage capabilities.

To enhance the use of Edison cell batteries, experts recommend incorporating advanced battery management systems. These systems ensure optimal charging practices and prolong battery life.

Adopting improved recycling practices and developing newer materials can mitigate environmental concerns associated with outdated battery technologies.

How Do the Specifications of the Edison Cell Battery Compare to Other Battery Technologies?

The specifications of the Edison cell battery, known for its nickel-iron (NiFe) technology, differ from other battery technologies in terms of lifespan, charging efficiency, environmental impact, and energy density.

Lifespan: The Edison cell battery has an exceptionally long lifespan, lasting up to 30 years with proper maintenance. This longevity contrasts sharply with lead-acid batteries, which typically last around 3-5 years, and lithium-ion batteries, which can last 8-15 years (Linden & Reddy, 2002).

Charging Efficiency: The Edison cell requires a longer charging time compared to lithium-ion batteries. It typically takes 8-10 hours to reach full charge, while lithium-ion can charge effectively within 1-3 hours (Ceder, 2017). However, the Edison cell can be recharged with sporadic charging, making it versatile for certain applications.

Environmental Impact: The materials used in the Edison cell, primarily nickel and iron, are less harmful to the environment than those found in lithium-ion batteries, which use cobalt and lithium. The presence of these toxic materials in lithium-ion batteries leads to increasing concerns regarding recycling and disposal (Liu et al., 2019).

Energy Density: The energy density of the Edison cell is lower than that of lithium-ion batteries. The Edison cell has an energy density of about 30-40 Wh/kg, while lithium-ion batteries can reach 150-200 Wh/kg. This difference affects their suitability for portable electronic devices, where weight and size are critical factors (Nagaiah & Kumar, 2013).

In summary, while the Edison cell battery excels in lifespan and environmental safety, it falls short in charging efficiency and energy density when compared to other contemporary battery technologies.

What Advantages Does NiFe Technology Offer in Terms of Size and Performance?

NiFe technology offers several advantages in terms of size and performance compared to traditional battery technologies.

1. High energy density
2. Longer lifespan
3. Robustness and durability
4. Size flexibility
5. Lower weight-to-power ratio

Transitioning from these points, it is important to delve deeper into the specific advantages that NiFe technology offers regarding its performance and size characteristics.

1. High Energy Density: High energy density refers to the ability to store more energy in a smaller volume. NiFe batteries can deliver significant energy per unit of weight. According to research by Wang et al. (2021), NiFe batteries achieve energy densities around 100 Wh/kg, making them competitive with lead-acid batteries and advantageous for applications with space constraints.

2. Longer Lifespan: Longer lifespan means that the battery retains its functionality over many charging cycles. NiFe batteries can endure thousands of charge-discharge cycles without significant degradation. As noted in a report by the Battery University, NiFe technology boasts a lifespan of up to 20 years, far exceeding that of comparable lead-acid and lithium-ion batteries.

3. Robustness and Durability: Robustness and durability pertain to the battery’s ability to withstand physical stress and adverse conditions. NiFe batteries can handle extreme temperatures and are resistant to overcharging and deep discharging. This resilience aids in applications that require reliability, like renewable energy systems.

4. Size Flexibility: Size flexibility means that the battery can be manufactured in various shapes and sizes to fit specific applications. NiFe technology can be adapted for different uses without compromising performance. This characteristic enables seamless integration into tight spaces, such as in electric vehicles or portable devices.

5. Lower Weight-to-Power Ratio: The lower weight-to-power ratio denotes a more efficient design that allows for reduced weight while maintaining power output. NiFe batteries achieve a good balance between weight and power delivery, making them suitable for mobile and lightweight applications such as aviation and aerospace pursuits.

In summary, NiFe technology excels in energy density, lifespan, robustness, size flexibility, and weight-to-power ratio, making it a strong contender for various applications in modern energy solutions.

How Can Understanding the Size of the Edison Cell Battery Influence Its Application?

Understanding the size of the Edison Cell battery influences its application by determining its capacity, weight, and suitability for specific uses across industries. The following points elaborate on how size impacts these factors.

1. Capacity: The size of the Edison Cell battery directly relates to its energy storage capacity. Larger batteries can store more energy, making them suitable for applications requiring longer operational durations, such as electric vehicles or stationary energy storage systems.

2. Weight: Size influences the weight of the battery, which is crucial for applications like portable electronics and electric vehicles. Heavier batteries can limit mobility and efficiency. Therefore, engineers must balance energy requirements with weight constraints to optimize performance.

3. Suitability: Smaller Edison Cells are advantageous for lightweight applications, while larger cells offer better energy output. For instance, a compact design may be ideal for tools or small devices, whereas larger cells can power industrial machinery.

4. Design considerations: The dimensions affect how the battery can be integrated into systems. Compatibility with existing designs is essential for ease of use and efficiency. A study by Sullivan and Wang (2020) highlights how battery dimensions can impact design choices in automotive applications.

5. Thermal management: The size also impacts heat dissipation capabilities. Larger batteries generally have better thermal management due to increased surface area, reducing the risk of overheating during high-demand applications.

These factors illustrate that understanding the size of the Edison Cell battery is critical for optimizing its performance and application potential in various fields.

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