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As a very essential step of PCB manufacturing process, drilling is pretty important to influence the performance and quality of the finished board. And in this passage, we will focus on laser drilling of PCB. Please check our content below and read for more knowledge.

What is circuit board drilling?

Circuit board drilling is the process of drilling holes on the PCB for any of the purposes mentioned below:

Placement of components

To bring interconnection between different layers

These are achieved by various types of vias namely through-hole vias, microvias, blind vias, and buried vias. When it comes to vias for electrical interconnection between layers, blind vias are preferred over through-hole vias. Blind vias increase the space available for wiring compared to the through-hole vias. It is demonstrated in the figure below.

Blind vias increase wiring space available on a PCB

Comparison between through-hole via and blind via in terms of space available for wiring

Why is laser drilling required for circuit boards?

When using HDI technology for PCB designing, plenty of microvias are included. These microvias that appear to be blind structures are small in size and require precise controlled depth drilling. This precision can only be achieved using lasers.

What are the advantages of laser drilling?

The advantages of using lasers are listed below:

Non-contact process: Laser drilling is a non-contact process and hence the damage induced on the material by drilling vibration is eliminated.

Precise control: We can control the beam intensity, heat output, and duration of the laser beam. This helps to create different hole shapes and offers high accuracy.

High aspect ratio: One of the most important parameters of a drilled hole on a circuit board is the aspect ratio. It is the ratio between the drilled depth and the diameter of the hole. Since lasers can create holes with very small diameters, they provide a high aspect ratio. A typical microvia has an aspect ratio of 0.75:1.

Multi-tasking: Laser machines used for drilling can also be used for other manufacturing processes like welding, cutting, etc.

How do you make micro-holes using lasers?

Laser drilling material removal

Stages of laser ablation

The recoil pressure will force the molten material to flow out of the hole. The ejection of the molten material is termed melt ejection. The absorption rate depends upon the type of material used. Usually, we use non-homogeneous materials like FR4 for circuit boards.

Single-pulse/shot laser drilling

As the name suggests, in single-pulse laser drilling, a single shot of laser beam is fired at the material to create the required hole. In this method, both the source of the laser and the work material is kept static.

Percussion laser drilling

In percussion drilling, a series of laser pulses are shot at the work material repeatedly. During this process, there is no relative motion between the laser beam and the workpiece. This form of laser drilling effectively creates deeper and precise holes with smaller diameters as compared to single-shot laser drilling.

Trepan laser drilling

Trepanning is the process in which a laser beam is guided around a predefined locus. This locus is the center of the via to be drilled. It is used in situations where the diameter of the via to be cut is larger than the laser beam diameter. The accuracy of the via is determined by the movement of the beam.

What is a PCB drilling machine?

A PCB drilling machine drills holes with high precision and accuracy based on the provided data. This data includes the exact position, number, and other parameters of the holes to be drilled.

Types of laser drilling machines

Different types of machines for laser processing are available depending on their operating principles. The most commonly used machines for drilling microvias are CO2 and Nd:YAG lasers. Excimer lasers are also available and are used in the etching of polymers. They are not suitable for the removal of metals.

CO2 lasers

Carbon dioxide lasers use gas as the lasing medium and emit light in the IR spectrum with around 10.6μm wavelength. These lasers create holes with 50-70μm diameter. CO2 lasers are one of the high-power lasers available today and are suitable for the drilling of polymers. These lasers have high reflectivity from metal surfaces. They are mostly used in areas where the speed of drilling is of primary importance. For around 80% of microvia drilling, CO2 lasers are used.

Nd:YAG lasers

The lasing medium in the Nd:YAG lasers is solid. Their fundamental emission is in the IR spectrum with a 1064nm wavelength. With non-linear crystals, they emit light in the visible spectrum (532nm) and in the UV spectrum (355 or 266nm). The Nd:YAG lasers can emit up to 100,000 pulses per second. The diameter of the focussed beams of these lasers is 12 to 25μm. For holes with higher diameters, they use the trepanning method.

The Nd:YAG lasers are the most versatile and can be used to drill on different types of materials such as polymers, glass, and metals, etc.

Combination of Nd:YAG and CO2 laser processes

Sometimes, we use a combination of both the lasers to get the specific results we want.

Considerations during laser drilling

During laser drilling, there are a few aspects regarding the circuit board that should be considered. Given below are two of the important ones.

Non-homogeneity of the stack-up

The non-homogeneity of the PCB materials used in the stack-up is the main consideration while using lasers. Different materials absorb energy at different rates. For example, FR4 resin absorbs light energy at the same rate as the glass fibers and leaves a clean hole. BT epoxy resin vaporizes at a rate faster than glass and hence leaves glass fibers in the hole.

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