Allicdata Part #: | 493-3325-ND |
Manufacturer Part#: |
JJD0E238MSEF |
Price: | $ 102.03 |
Product Category: | Capacitors |
Manufacturer: | Nichicon |
Short Description: | CAP 2300F 20% 2.5V CHASSIS MOUNT |
More Detail: | 2300F (EDLC) Supercapacitor 2.5V Radial, Can - Scr... |
DataSheet: | JJD0E238MSEF Datasheet/PDF |
Quantity: | 1000 |
Lead Free Status / RoHS Status: | Lead free / RoHS Compliant |
Moisture Sensitivity Level (MSL): | 1 (Unlimited) |
5 +: | $ 92.74750 |
Series: | EVerCAP® JJD |
Packaging: | Bulk |
Lead Free Status / RoHS Status: | -- |
Part Status: | Active |
Moisture Sensitivity Level (MSL): | -- |
Capacitance: | 2300F |
Tolerance: | ±20% |
Voltage - Rated: | 2.5V |
ESR (Equivalent Series Resistance): | 4 mOhm |
Lifetime @ Temp.: | 2000 Hrs @ 60°C |
Termination: | Screw Terminals |
Mounting Type: | Chassis Mount |
Package / Case: | Radial, Can - Screw Terminals |
Lead Spacing: | 1.024" (26.00mm) |
Size / Dimension: | 2.008" Dia (51.00mm) |
Height - Seated (Max): | 5.433" (138.00mm) |
Operating Temperature: | -25°C ~ 60°C |
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Electric Double Layer Capacitors (EDLC), Supercapacitors
JJD0E238MSEF is an electric double layer capacitor (EDLC) commonly known as a supercapacitor. EDLCs are an energy storage device with different characteristics from batteries and capacitors. The most striking difference between EDLCs and other energy storage devices is the relatively high charge and discharge rate, which makes them especially suitable for power electronic device applications. This article explains the application field and working principle of the JJD0E238MSEF.
Applications
Ed The JJDE238MSEF is used in a variety of applications due to its size, high energy and power density, and wide range of operating temperatures. These include electric vehicles and energy storage systems where high charge and discharge rates are required, as well as consumer electronics and medical equipment, as well as industrial applications.
Electric vehicles have seen increased use in recent years due to rising gasoline prices. EDLCs are used in these vehicles to store energy that can be used during acceleration and other high-load applications. This allows electric vehicles to have longer ranges and improved performance. They are also used to quickly supply energy when needed, which helps improve acceleration and reduce fuel consumption.
EDLCs are also used in energy storage systems. These systems provide a way to store energy from renewable sources like solar and wind power. EDLCs are ideal for this application as they are able to quickly charge and discharge large amounts of energy. These systems are also used to provide back-up power during outages, which can be used to maintain operations in critical industries such as healthcare and manufacturing.
EDLCs are also used in consumer electronics, such as cell phones and tablets. Due to the rapid charge and discharge capability, these devices are able to quickly recharge during use, while still lasting for longer peak periods. This helps the device to run for a longer period of time without needing frequent recharging.
Finally, EDLCs are sometimes used in medical equipment. These devices often require high power and fast response times, which EDLCs are able to provide. EDLCs also enable smaller and lighter power supplies, which is important in medical equipment where size and weight are often constraints.
Working Principle
The working principle of the EDLC is based on the double layer effect. When a voltage is applied to an electrolyte, an electric double layered structure is formed. This double layer allows energy to be stored in the form of an electric field. The energy stored in this electric field can then be used to power a device or to charge an EDLC.
When an EDLC is charged, ions from the electrolyte attach to the electrodes. These ions are stored in a “double layer”, where one layer is positively charged and the other is negatively charged. This causes a potential difference between the two layers and creates an electric field in which energy is stored. As the EDLC is discharged, the ions move back into the electrolyte and the electric field is dissipated.
The primary benefit of EDLCs is their fast charging time compared to other energy storage devices. EDLCs are able to store and release energy much faster than batteries, which is why they are preferred in applications where fast charging and discharging is needed. Additionally, EDLCs have a very large capacity for their size, which is useful in applications that have space constraints.
Conclusion
The JJD0E238MSEF is an electric double layer capacitor, commonly known as a supercapacitor. It is used in a wide range of applications, from electric vehicles to consumer electronics, due to its small size, high energy and power density, and wide range of operating temperatures. Its working principle is based on the double layer effect, in which ions from the electrolyte attach to the electrodes and create an electric field in which energy is stored.
EDLCs are an increasingly popular energy storage device due to their fast charging and discharging capabilities. They are ideal for applications where fast response time is needed, such as electric vehicles and energy storage systems. Additionally, they have a large capacity for their size and are therefore useful in applications where space is limited. The JJD0E238MSEF is a great example of an EDLC and its many applications.
The specific data is subject to PDF, and the above content is for reference
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