Flux is a fundamental material in the electronics manufacturing process, particularly in the assembly of printed circuit boards (PCBs). It plays a crucial role in ensuring the reliability and functionality of electronic components by enabling high-quality solder joints. Its versatility and multifunctionality make it indispensable in the reflow soldering process.
Types of Flux
Flux is generally classified into four types:
1. Rosin Mildly Activated (RMA)
This flux has a moderate activity level and is commonly used for general-purpose soldering. It leaves a small amount of residue, which is typically cleaned off after soldering.
2. Rosin Activated (RA)
RA flux is more aggressive in removing oxidation and leaves behind a larger amount of residue, necessitating post-soldering cleaning.
3. No-Clean Flux (R0)
No-clean flux leaves minimal residue and does not require post-soldering cleaning. It is widely used in high-volume production, where cleaning may be impractical or unnecessary.
A commonly used type within no-clean flux solder paste compositions is R0L0.
• R0 indicates that the flux leaves minimal or no residue.
• L0 signifies low activity, making it suitable for clean surfaces or applications where only mild activation is needed.
4. Water-Soluble Flux (R0 or R1)
These fluxes leave residues that must be cleaned off with water after soldering since they can be conductive or corrosive if left on the board.
Key Functions of Flux in PCB Assembly
1. Oxide Removal
One of the primary functions of flux is to remove oxides from the surfaces of PCBs, components, and solder balls in solder paste. Oxidation can prevent proper soldering by inhibiting the flow and bonding of solder. Flux chemically cleans these oxides, ensuring a smooth soldering process.
• It contains mildly acidic properties that break down and dissolve copper oxide, which forms when copper is exposed to air.
2. Promotion of Wetting
Flux facilitates wetting, which is the ability of molten solder to flow and adhere to the surfaces being joined. Good wetting is essential for strong and reliable solder joints. Flux achieves this by reducing the surface tension of molten solder and metal surfaces.
3. Thermal Energy Transfer
During the reflow soldering process, flux aids in the efficient transfer of thermal energy, ensuring even heat distribution. This is critical for melting solder paste without damaging sensitive components.
• The effectiveness of this process depends on maintaining the flux below its vaporization point, typically between 250°C and 350°C (for no-clean flux). Exceeding this range, the flux no longer effectively plays its role.
• Temperature setting of reflow oven is important to maintain flux effectiveness. Wrong setting might cause defects such as non-wetting, tombstoning, or thermal damage to components.
4. Oxidation Barrier
Flux acts as a protective barrier, preventing new oxidation during the reflow process. This ensures that solder bonds effectively with components and the PCB.
5. Encapsulation Post-Reflow
After reflow, flux can encapsulate solder joints, protecting them from environmental factors such as moisture and contaminants. This contributes to the long-term reliability of the electronic assembly.
6. Carrier for Solder Alloy Balls
In solder pastes, flux functions as a carrier for solder alloy balls, maintaining their uniform distribution and positioning until the reflow process.
• Flux prevents solder balls from scattering, reducing the risk of defects.
• It also aids in uniting solder balls, enhancing the curing process of the solder paste.
7. Tackiness for Component Placement
Flux provides tackiness, helping hold components in place during assembly. This is particularly useful in automated manufacturing, where precise alignment is critical.
• The sticky characteristic prevents components from shifting during reflow.
8. Promotion of Workability
Flux enhances the workability of the assembly process by promoting stress distribution and dissipation, reducing the risk of mechanical stress or thermal expansion compromising solder joints.
9. Tailored Formulations for Specific Needs
Flux is often formulated to support specific metals and surface finishes. Whether the surface finish is gold, silver, copper, or a specific alloy, tailored flux formulations ensure optimal performance and compatibility with the materials being soldered.
Application in Rework Processes
Due to its ability to reactivate solder, flux is widely used in PCB assembly (PCBA) rework.
• Solder paste will not melt during a second reflow process without the presence of flux.
• This challenge often arises in SMT manufacturing for PCBs with components on both sides.
• By applying flux to specific areas requiring rework, it enables easier solder melting, making rework more efficient and practical.
Conclusion
Flux is much more than just a cleaning agent in PCB assembly—it is a multifunctional material that ensures the quality, reliability, and efficiency of the soldering process. By facilitating oxide removal, promoting wetting, transferring thermal energy, and providing essential protective functions, flux remains a critical component in modern electronics manufacturing.
For tailored solutions and expertise, trust PICA Manufacturing Solutions to guide your assembly processes to perfection.