Zener diodes, 18V, 50W, DO-5 form factor
Manufacturer: ['microsemi', 'solid-state']
The 1N3317 Series is a robust line of silicon rectifier diodes renowned for their efficiency and reliability in a variety of electronic applications. Designed to handle moderate to high currents, these diodes feature a maximum repetitive reverse voltage (VRRM) rating of 40 volts and a forward current (IF) rating of 1 ampere, making them suitable for demanding environments. The construction of the 1N3317 ensures low forward voltage drop, which translates to reduced power loss and enhanced thermal performance, critical for applications where efficiency is paramount.
With a unique design that emphasizes reliability, the 1N3317 Series incorporates a glass passivated junction, providing exceptional protection against environmental factors such as moisture and dust. This design characteristic not only extends the lifespan of the diode but also enhances its performance under varying temperature conditions, with a maximum junction temperature of +150°C. The diodes are housed in a DO-41 package, which offers both durability and ease of mounting, making them ideal for integration into printed circuit boards (PCBs) and other electronic assemblies.
The 1N3317 Series finds its application across a wide spectrum of industries, including telecommunications, automotive, and consumer electronics. They are particularly effective in rectification circuits, where they convert alternating current (AC) to direct current (DC), making them indispensable in power supply units and inverters. Furthermore, their ability to withstand surge currents makes them an excellent choice for protecting sensitive components from voltage spikes, thereby ensuring the longevity of electronic devices.
In summary, the 1N3317 Series serves as a versatile solution for engineers and designers seeking reliable rectification and protection in their electronic circuits. With their combination of high performance, durable design, and broad applicability, these diodes are well-suited for contemporary electronic systems that demand both efficiency and resilience.
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