Guide to the use of plastic paint defoamers: A complete analysis from scientific principles to industrial practice
Guide to the use of plastic paint defoamers: A complete analysis from scientific principles to industrial practice
In the car bumper spraying workshop, paint that does not use defoamers correctly is stirred into air due to high-speed stirring, forming dense bubbles on the surface. These bubbles expand and burst when baked and cured at 180°C, resulting in defects such as pinholes and orange peel on the surface of the paint film, causing the yield rate to drop sharply to 85%. After scientifically adding 0.3% of special defoamers, the bubble defect rate can be controlled below 0.2%. This case reveals the core value of the use of defoamers-the correct use method is not only a guarantee of paint quality, but also the key to industrial production efficiency.
1. The mechanism of action of defoamers: a physical and chemical revolution in the microscopic world
Defoamers achieve bubble breaking through three-stage synergistic effects:
Permeation stage: hydrophobic particles (such as fumed silica) migrate to the surface of the foam liquid film by Brownian motion to form a microscopic rough structure. Experimental data show that the penetration rate of defoamers containing 20% hydrophobic particles is 3 times faster than that of pure silicone systems, and can break through the foam elastic film within 0.01 seconds.
Spreading stage: Low surface tension components (such as polydimethylsiloxane) form a monolayer on the surface of the liquid film, expanding the surface tension gradient difference to 17mN/m. This gradient causes the surrounding high-tension liquid to flow to the low-tension area, causing the membrane wall to thin to a critical value (about 100nm).
Membrane breaking stage: When the membrane thickness drops to a critical value, the van der Waals force is insufficient to maintain the membrane structure, causing chain rupture. The Tsinghua University team captured through high-speed camera technology that high-quality defoamers can complete the membrane breaking process within 0.02 seconds.
2. Scientific use of the four-step method: standardized process from laboratory to production line
1). Pre-experimental determination of the optimal addition amount
Gradient test method: Take 5 equal amounts of base paint (such as 100g), add 0.1%, 0.2%, 0.3%, 0.4%, and 0.5% of defoamers respectively, and observe the foam height after stirring under the same conditions (1000rpm, 5 minutes).
Data recording: Use a foam analyzer to measure the initial foam height (H0) and the residual height (H30) after 30 seconds, and calculate the defoaming efficiency = (H0-H30)/H0×100%.
2). Accurate addition timing control
Paint mixing stage: Adding defoamer after the pigment is dispersed and before dilution can avoid microfoam generated by high-speed dispersion. The practice of a home appliance company shows that adding at this stage can increase the powder coating rate by 15%.
Pre-spraying treatment: For electrostatic spraying, it is necessary to add the defoamer after the paint is filtered and 10 minutes before spraying to ensure that the defoamer is fully dispersed. The case of wind turbine blade coating shows that this method extends the salt spray test time to 5000 hours.
Special process adaptation: In UV-curing coatings, light-stable defoamers need to be selected and added under light-proof conditions to prevent ultraviolet rays from causing degradation.
3). Mixing process optimization
Stirring parameters: Stir at a low speed (300-500rpm) for 10-15 minutes to avoid high-speed shearing to damage the defoamer structure. A 3C electronics company reduced the pinhole defect rate of the mobile phone shell coating from 1.2% to 0.05% by optimizing the stirring parameters.
Dispersion equipment selection:
Laboratory scale: Use ultrasonic disperser (power 200W, ultrasonic 5 minutes)
Production line scale: Use high shear emulsifier (speed 8000rpm, processing time 3 minutes)
Temperature control: It is recommended to control the water-based system at 25-40℃, and the oily system does not exceed 60℃. A certain car bumper coating line uses a temperature control system to improve the stability of defoaming efficiency by 40%.
4). Storage and compounding management
Storage conditions: Store in a sealed and light-proof environment, and the temperature is controlled at 5-35℃. After a certain bio-based defoamer is stored at 40℃ for 3 months, the defoaming efficiency decreases by 23%, while it only decreases by 5% when stored at 25℃.
Compounding taboos:
Avoid mixing with strong acid and strong alkali substances
It is forbidden to use with additives containing heavy metal ions
Mineral oil defoamers should not be compounded with water-based systems
Shelf life management: After opening the can, it must be used up within 6 months. Unused products should be resealed and marked with the opening date.
3. Solutions to common problems
1). Excessive defoamer causes shrinkage
Phenomenon: Circular depressions appear on the surface of the paint film, with a diameter of 0.1-3mm
Reason: The amount of defoamer added exceeds the solubility of the system
Solution:
Add 0.1-0.2% of leveling agent (such as polyacrylate)
Increase the stirring speed to 800rpm for 10 minutes
Add 5-10% of diluent to reduce the viscosity of the system
2). Defoamer failure causes bubble recurrence
Phenomenon: New bubbles appear within 24 hours after spraying
Reason:
Storage temperature is too high (>40℃)
Incompatible with the system
Improper timing of addition
Solution:
Replace heat-resistant defoamer (such as core-shell nanoparticle type)
Perform compatibility test (stand at 25℃ for 72 hours to observe the stratification)
Adjust the order of addition (add after the pigment is dispersed and before dilution)
3). Performance decay of bio-based defoamers
Phenomenon: Defoaming efficiency decreases by >15% after 3 months of use
Reason: Microbial contamination leads to degradation of active ingredients
Solution:
Add 0.05% preservative (such as sodium benzoate)
Sterilize before storage (heat treatment at 60℃ for 30 minutes)
Store under nitrogen protection
From laboratory pre-experiments to standardized operations on production lines, the scientific use of plastic paint defoamers requires the establishment of a complete quality control system. A multinational coatings company has increased the qualified rate of defoamer use from 78% to 99.5% by implementing the three-stage management method of "pre-experiment-process monitoring-effect verification", saving more than 5 million yuan in rework costs annually. With the development of new defoamers such as intelligent responsive and bio-based, future use technologies will develop in a more precise and environmentally friendly direction, providing key technical support for the upgrading of the global manufacturing industry.