Tag Archives: contamination
Thanks to advancements in powertrain manufacturing, sealing processes have improved assembly efficiency. Formed-in-place gaskets (FIPG) are replacing traditional mechanical fasteners as they are more cost effective, stronger, and easier to apply. However, adhesive bonding rather than mechanically fastening presents different challenges and requires new protocols.
Lead Sales Engineer Lucas Dillingham has presented “Defining Cleanliness in Powertrain Manufacturing for FIPG Applications,” at several events and automotive factories. BTG Labs works with numerous automotive manufacturers on surface chemical cleanliness and what it means for assembly.
Traditional millipore tests reveal particulate contamination, but on a sealing surface, one must detect chemical contamination. To adhere successfully, surface cleanliness on a chemical level is vital.
A byproduct of automotive manufacturing processes is contaminants that are detrimental to adhesion. Processes entailing unwanted contaminants include:
Handheld Solution for Verifying Surface Cleanliness
The Surface Analyst™ is an innovative handheld solution for use in the lab and on the factory floor. It reduces waste, rework, and recalls when poorly prepared substrate surfaces lead to bonding, coating, sealing, painting, or printing failure.
Using contact angle measurement, the Surface Analyst measures the cleanliness level of surfaces and determines preparedness for adhesion. Developed and manufactured by BTG Labs, it is a fast, easy, accurate, and nondestructive instrument for manufacturers with critical surface requirements. The Surface Analyst replaces legacy methods such as dyne and water break tests.
Measuring Contact Angle to Determine Surface Cleanliness
The Surface Analyst deposits a highly purified drop of water on the surface. In two seconds, it measures the contact angle and in turn, determines the cleanliness level of a substrate.
When a surface is clean, it emits high energy, and water–as a high energy molecule–spreads out on the surface, in attraction to other high energy molecules (Figure 1). A contaminated surface emits low energy and will cause water to bead up in attraction to itself rather than the low energy surface molecules (Figure 2).
By knowing the volume and area of a drop of water, the contact angle of the water against a given surface can be determined. The larger the contact angle, the more the water beads up on the surface – and therefore the lower the energy level of the surface.