TR3B226K016C0700

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TR3B226K016C0700 – Application Field and Working Principle of Tantalum Capacitors

Tantalum capacitors, sometimes referred to as “tantalum electrolytic capacitors”, have become increasingly popular in recent years for their reliability and superior performance in extreme temperatures compared to aluminum electrolytic capacitors. A specific type of tantalum capacitor, the TR3B226K016C0700, is an optimized design for performance, signal processing, and embedded circuit applications. This article provides a closer look at the application areas, the construction and the working principles of the TR3B226K016C0700.

Application Fields

The TR3B226K016C0700 is well-suited for a wide range of uses such as industrial electronics, signal processing, medical electronics and embedded systems. This diverse application range is enabled by its ability to operate in extreme temperatures while maintaining superior performance. Furthermore, its robust construction has superior internal environmental protection, allowing it to withstand adverse conditions, making it the optimal capacitor for use in long-term, mission critical applications.

The TR3B226K016C0700 offers a variety of features that have made it the capacitor of choice for a broad range of electronics applications, including its small size, low leakage current and its high capacitance stability over various temperature ranges.

The TR3B226K016C0700 is also ideal for use in high frequency switching power supplies, and its low ESR makes it well suited for use in applications where the regulation of voltage is important. The superior performance of the TR3B226K016C0700 also makes it a preferable alternative to ceramic capacitors in many applications.

Construction

The TR3B226K016C0700 utilizes a two-lead construction. The two leads are an anode and a cathode, and are typically made of silver-plated copper or gold-plated nickel vanadium. The two leads are then connected to the capacitor body, generally made of tantalum.

The body of the TR3B226K016C0700 is filled with an electrolyte. The most commonly used electrolyte is a mixture of ethanol and water, mixed with trace amounts of chemical additives. Other electrolytes, such as propylene carbonate and trimethylene carbonate, are also sometimes used for specialized applications.

Working Principle

The TR3B226K016C0700 works as a storage device, much like a battery. It uses the electrolyte to create a potential difference between the anode and the cathode, which acts as an electrical field. This field enables the capacitor to store an electrical charge, and to hold it for a specified period of time.

The stored charge can be released when needed, commonly known as the capacitor’s discharge time. This is controlled by the capacitance of the capacitor, and the size and shape of the leads. The release time can range from microseconds to hours, depending on the application and the components used in the construction.

Another major benefit of the TR3B226K016C0700 is its ability to “self-heal”, a feature that allows the capacitor to automatically repair any damage caused by voltage spikes, resulting in minimized downtime and potential cost savings. This feature is possible due to the use of a dielectric oxide film that forms a barrier between the anode and the cathode.

Conclusion

The TR3B226K016C0700 is an optimized design of tantalum capacitor that is well-suited for use in a variety of applications, including industrial electronics, signal processing, medical electronics, and embedded systems. Its two-lead construction includes a body filled with an electrolyte and two leads, an anode and a cathode. The capacitance of the capacitor, combined with its dielectric oxide film, enables it to store and release an electrical charge, creating an electrical field.

Furthermore, the TR3B226K016C0700’s ability to self-heal makes it an appealing choice for long-term, mission critical applications that demand reliable performance. Its small size and robust construction further contribute to its efficiency, making it the preferred capacitor for a variety of uses.

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