Zd10-100 Datasheet -
In the world of power electronics, the ability to select the right component for voltage regulation and transient suppression is critical. Among the vast sea of Zener diodes, the ZD10-100 stands out as a specific, high-reliability component often used in industrial, automotive, and telecommunications equipment. However, finding a clear, consolidated, and detailed datasheet for the ZD10-100 can be challenging.
This article serves as an exhaustive technical resource. Whether you are designing a power supply, repairing a circuit board, or sourcing components, this guide breaks down every parameter of the ZD10-100 datasheet, including electrical characteristics, thermal data, packaging, and application circuits.
Below is a breakdown of the official typical specifications found in the manufacturer’s datasheet. (Note: Always refer to the original datasheet from your specific vendor, as parameters can vary slightly between manufacturers like Vishay, ON Semiconductor, or Diodes Inc.) zd10-100 datasheet
The ZD10-100 is commonly a 10V, 100mA Zener diode (ZD = Zener Diode, 10 = 10V, 100 = 100mW or 100mA).
Alternative: Could be a 100V, 10A rectifier or a custom industrial module (less likely).
For low-current loads (e.g., <8 mA), the ZD10-100 can act as a simple shunt regulator, maintaining 10V across a load even if the input voltage fluctuates. In the world of power electronics, the ability
| Parameter | Conditions | Min | Typ | Max | Unit | |-----------|------------|-----|-----|-----|------| | Zener Voltage (VZ) | IZT = 5 mA | 9.4 | 10 | 10.6 | V | | Reverse Leakage Current (IR) | VR = 7.5V | - | - | 10 | µA | | Zener Impedance (ZZT) | IZT = 5 mA | - | 30 | - | Ω | | Temperature Coefficient | IZT = 5 mA | - | +0.07 | - | %/°C |
Critical Analysis:
A surprising number of field failures occur because designers ignore the derating curve. Let’s decode the ZD10-100 datasheet thermal specifications.
With 20 CFM forced air:
Practical advice: If the ZD10-100 is mounted inside a sealed IP65 enclosure, you must derate by at least 20% even at 40°C ambient. The datasheet provides a formula for calculating MTBF vs. temperature – a 10°C rise halves the capacitor lifespan.
For a 10V device, the coefficient is positive (~+0.07%/°C). This means if your circuit heats from 25°C to 75°C, the Zener voltage will increase by roughly: 10V * 0.0007 * 50 = 0.35V → 10.35V. With 20 CFM forced air: