TLDR;
This video introduces Zener diodes, explaining how they differ from standard diodes by having a specific reverse breakdown voltage (Zener voltage). The video demonstrates how a Zener diode prevents current flow up to its Zener voltage when reverse-biased, but allows current to flow once that voltage is exceeded. It also showcases a practical application of Zener diodes in creating a simple voltage regulator, maintaining a constant voltage output despite variations in the input voltage.
- Zener diodes have a specific reverse breakdown voltage (Zener voltage).
- They can be used to create voltage references, shunt voltage regulators and over-voltage protection circuits.
- Zener diodes can maintain a constant voltage output even with varying input voltage.
Introduction to Zener Diodes [0:10]
The video introduces Zener diodes as a specific type of diode with unique properties, building upon a previous discussion of standard diodes. While standard diodes allow current to flow in only one direction and block it when reverse-biased, Zener diodes have an additional characteristic related to their behaviour under reverse-bias conditions. The presenter sets the stage for explaining the key difference: the Zener diode's specified reverse breakdown voltage, also known as the Zener voltage.
Zener Diode Functionality [0:32]
Zener diodes, like standard diodes, initially block current flow when reverse-biased. However, Zener diodes have a specified reverse breakdown voltage, or Zener voltage. When a Zener diode is reverse-biased, it prevents current from flowing up to this specific voltage. If the voltage exceeds this breakdown point, the Zener diode allows current to flow, differentiating it from a standard diode which would ideally block current regardless of the reverse voltage.
Demonstration of Breakdown Voltage [1:22]
A practical demonstration illustrates the Zener diode's breakdown voltage. A Zener diode with a 10-volt breakdown voltage is reverse-biased in a circuit. When the applied voltage is below 10 volts, no current flows. However, as the voltage increases above 10 volts, current begins to flow through the circuit, showing that the Zener diode's breakdown voltage has been exceeded.
Applications of Zener Diodes [1:59]
Zener diodes are useful for creating voltage references, shunt voltage regulators and over-voltage protection circuits. The presenter introduces a circuit with a 12-volt power supply and a reverse-biased Zener diode with a 10-volt breakdown voltage to demonstrate one of these applications. Because the power supply exceeds the Zener diode's breakdown voltage, current flows through the circuit.
Voltage Regulation Example [2:22]
The video demonstrates a voltage regulation circuit using a Zener diode. With a 12V power supply, the voltage across the Zener diode is measured at approximately 10V. When the power supply voltage is increased to 51V, the voltage across the Zener diode remains stable at around 10V. This demonstrates the Zener diode's ability to maintain a constant voltage output despite significant variations in the input voltage, effectively creating a 10V voltage regulator. The explanation of how this regulation works will be covered in a future video.