Full wave Rectifier

What is a Full-Wave Rectifier?

A full-wave rectifier is an electronic circuit designed to convert the entire AC waveform into a (DC) current. Unlike the half-wave rectifier, which only processes one half of the AC cycle, the full-wave rectifier utilizes both halves, making it significantly more efficient. This efficiency is why full-wave rectifiers are found in a wide range of applications, like Industria DC Power Supplies and other AC to dc converters.

There are two main different types of full-wave rectifiers: Center-Tap Rectifiers and Bridge Rectifiers:

1- Center-Tap Full-Wave Rectifier

The center-tap rectifier uses a center-tap transformer and two rectifier diodes to convert AC to DC. During the positive half of the AC cycle, one diode conducts, and during the negative half, the other diode conducts. This dual conduction process results in a pulsating DC output.

Advantages:

•  Efficient use of the transformer
• Simplicity in design, making it ideal for straightforward applications like Ni-CD Battery and **VRLA Battery chargers.

Disadvantages:

• Requires a center-tap transformer, which can be bulkier and more expensive
• Lower output voltage compared to the input AC voltage, which may not be ideal for applications requiring higher DC voltage

2-Bridge Full-Wave Rectifier

The bridge rectifier is the most commonly used full-wave rectifier. It uses four rectifier diodes arranged in a bridge configuration, which allows it to convert both halves of the AC cycle into DC without needing a center-tap transformer. During the positive half of the AC cycle, two diodes conduct, directing current through the load. During the negative half, the other two diodes conduct, ensuring that the current flows in the same direction through the load.

Advantages:

• Does not require a center-tap transformer, making it more compact and cost-effective.
• Higher output voltage compared to the center-tap rectifier, which is useful in DC to DC converters and

Disadvantages:

• More complex in design due to the need for four diodes, but this complexity is often outweighed by its advantages.