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Punching Out: How Are the Big Boys in Electronics Doing?
High-performance electronics must endure everything from rain, dust, and oil to extreme temperatures, shock, and vibration. These reliability demands now share the stage with other priorities such as size reduction, lightweighting, and environmental sustainability. Combined with constant pressure to cut costs, accelerate production, and boost manufacturing efficiency, material suppliers are racing to develop advanced conformal coatings that deliver it all: compatibility with finer-pitch circuitry, durability, eco-friendliness, and manufacturing efficiency.
The history of protective coatings spans more than a century, beginning with early epoxies and advancing to sophisticated chemistries engineered to meet evolving reliability and manufacturing requirements. Building on this foundation, Electrolube® UVFlex™, a UV-curable, high-elasticity conformal coating based on urethane acrylate chemistry, represents the next phase in coating innovation,. It combines rapid curing and robust mechanical performance with environmental responsibility, delivering exceptional surface insulation resistance (SIR), thermal cycling durability, and component coverage while remaining solvent-free, PFAS-free, and 30% bio-based.
Comparative testing demonstrates that UVFlex surpasses traditional acrylic, silicone, and urethane coatings on finer-pitch circuitry exposed to severe environmental stress, including thermal cycling from -40 to +125°C, 85°C/85% RH aging, and condensation exposure.
The Road to Modern Conformal Coatings
Protecting circuits with a polymeric barrier is not a new concept: Thomas Edison experimented with phenolic insulators back in the 1800s. However, the real breakthroughs came in the 1960s, when NASA engineers recognized the need to protect mission-critical electronics from moisture and contaminants.
At that time, PCBs were either left bare or covered with thick, two-component epoxies, which were prone to cracking under large temperature swings. Fractured solder joints were common, and repairs were painfully difficult, requiring hardened epoxy to be chipped away.
To continue reading this article, which originally appeared in the November 2025 edition of SMT007 Magazine, click here.
