Summary
- Samsung Electro-Mechanics has begun producing a new compact high-capacitance MLCC
- The CL32B226KLV6PN# MLCC is intended for use in tight spaces such as EV battery systems
- The new MLCC was developed using fine-particle ceramic and electrode materials
- It has the same size and high capacitance as previous models, but with an increased rated voltage
- The MLCC maintains a size of 3.2×2.5mm and a capacitance of 22㎌, with a rated voltage of 35 V
Article
South Korean electronic component company Samsung Electro-Mechanics has recently launched production of a new compact high-capacitance multilayer ceramic capacitor (MLCC). This new capacitor, known as the CL32B226KLV6PN#, is specifically designed for use in constrained spaces, such as 12 V EV battery systems and 48 V/12 V bidirectional DC-DC converter output stages. The company utilized fine-particle ceramic and electrode materials, along with ultra-precision stacking techniques, to develop this MLCC. Despite maintaining the same 1210 inch (3.2×2.5mm) size and high capacitance (22㎌) as its X7R product lineup, the CL32B226KLV6PN# offers an increased rated voltage of 35 V, up from the previous 16 V.
The innovative design and manufacturing process employed by Samsung Electro-Mechanics for the CL32B226KLV6PN# capacitor address the growing demand for compact components with high capacitance in the electronic industry. These features make it ideal for integration into various power systems, especially in applications with constrained spatial requirements. By utilizing fine-particle ceramic and electrode materials, along with ultra-precision stacking techniques, the company has been able to achieve a significant increase in the rated voltage without compromising on size or capacitance. This advancement in MLCC technology showcases Samsung Electro-Mechanics’ ability to meet the evolving needs of electronic applications, particularly in the automotive sector.
The compact yet high-capacitance nature of the CL32B226KLV6PN# capacitor makes it well-suited for use in 12 V EV battery systems and 48 V/12 V bidirectional DC-DC converter output stages. These applications typically require components that can operate efficiently within limited physical space while delivering reliable performance. Samsung Electro-Mechanics’ new MLCC addresses these requirements by offering a combination of small form factor, high capacitance, and increased rated voltage. This enables manufacturers to design and build more compact and energy-efficient electronic systems for various applications in the automotive and industrial sectors.
Samsung Electro-Mechanics’ decision to increase the rated voltage of the CL32B226KLV6PN# capacitor from 16 V to 35 V reflects the company’s commitment to enhancing the performance and reliability of its electronic components. By offering a higher rated voltage, the MLCC can now be used in a wider range of applications without the risk of voltage overload. This flexibility allows engineers and designers to incorporate the capacitor into different types of circuits and systems, providing more versatility in product development. The increased rated voltage also enhances the overall efficiency and durability of the capacitor, ensuring long-term operational stability in demanding electronic environments.
Overall, Samsung Electro-Mechanics’ introduction of the CL32B226KLV6PN# compact high-capacitance multilayer ceramic capacitor represents a significant advancement in MLCC technology. The capacitor’s small size, high capacitance, and increased rated voltage make it an ideal choice for applications in constrained spaces, such as 12 V EV battery systems and 48 V/12 V bidirectional DC-DC converter output stages. By utilizing fine-particle ceramic and electrode materials, along with ultra-precision stacking techniques, the company has achieved a balance between size, capacitance, and voltage ratings, catering to the evolving needs of the electronic industry. This innovation demonstrates Samsung Electro-Mechanics’ dedication to delivering cutting-edge electronic components that meet the demanding requirements of modern electronic systems.
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