PCB Manufacturing Process

Once the design is complete, it undergoes a rigorous verification process to identify any errors or inconsistencies. This ensures the final product meets the desired specifications.

After design verification, the PCB design is transferred to a transparent film using a plotter printer. This film acts as a negative image of the PCB layout, with black ink representing copper traces and clear ink representing non-conductive areas.

For multi-layer PCBs, separate films are created for each inner layer. The PCB laminate material is then bonded with copper foil, and a photosensitive resist is applied to the surface. Based on the film’s design, UV light is used to harden the resist in specific areas, protecting the desired copper traces during the etching process.

The laminate panel is then etched with a chemical solution that removes the unprotected copper, leaving behind the designed copper traces.

Once the inner layers are etched, they are precisely aligned and inspected using an optical inspection machine to ensure proper alignment and identify any potential defects.

Holes are drilled through the laminated PCB stack to create vias (connections between layers) and mounting points for electronic components.

The drilled holes and exposed copper surfaces are then plated with a thin layer of metal, typically copper or nickel, to ensure proper conductivity and protect the copper from corrosion.

Similar to the inner layer process, a photoresist is applied to the outer layers, patterned with UV light based on the design film, and then etched to remove unwanted copper.

Another automated optical inspection is performed on the outer layers to verify they meet design specifications and ensure proper functionality.

A solder mask is applied to the PCB surface using a stencil and UV light. This mask protects desired copper areas from solder during component assembly while allowing solder to flow to designated connection points. 

A final surface finish, such as electroless nickel immersion gold (ENEPIG) or hot air solder leveling (HASL), is applied to the PCB. This coating protects the copper traces from oxidation and corrosion while facilitating component soldering.

After completing all the above steps, the PCBs undergo a series of electrical tests to ensure proper functionality and identify any defects. These tests typically include continuity checks to verify connections and isolation tests to confirm there are no unwanted shorts between circuits.

Once the PCBs pass electrical testing, they are profiled using the Gerber files to determine their final size and shape. A computer-controlled machine then routes or scores the PCB panel, separating individual PCBs without damaging the edges.