HeatX is a revolutionary advanced nanocomposite surface treatment that creates a passivating layer that repels fouling, water and oil and also protects against corrosion, which increases the efficiency of the heat exchanger.
HeatX is an omniphobic (oil & water repellant) coating that repels biofouling (both micro and macro-organism) growth on the tubular and metallic surfaces of all varieties of heat exchangers which are vulnerable to corrosion, pitting, and fouling.
Due to the extremely slick, low surface energy of the HeatX surface treatment, tubular surfaces are endowed with extremely low-friction properties that minimize organisms’ ability to bind on the surface. HeatX does not contain any harmful biocidal compounds that are commonly found in other anti-fouling coatings/epoxies, so the resulting surface is inert to both water and oil-based substances. Rather, the slick surface ,combined with flow through the tubular, repels organisms from adhering to the tubular surface.
HeatX is functional at less than 2mil DFT and is non-insular, meaning it does not affect the overall heat transfer function of the heat exchanger unit. In addition to releasing fouling from surfaces, HeatX also prevents corrosion of heat exchanger surfaces and prevent erosion pitting and other material losses from surface substrates. By preventing the build-up of insulating corrosion or biofouling, HeatX preserves the efficiency of the heat exchanger, saving a large amount of maintenance downtime and costs for the operator.
HeatX coating is a water-based formulation, non-VOC and non-toxic after curing. It can even be applied to unprepared, corroded surfaces and still achieve the full benefits.
Water-and-oil compatible nano coating material allows for use in mixed-phase and oleic systems.
Extreme thinness of the nano coating (2 mil DFT), allows for negligible change in exchanger thermal efficiency.
Treated material is compatible with a variety of different inspection techniques (eddy current, boroscope, leak-testing)
Resistant to abrasive wear due to particulate contaminants.
Capable of surviving intake silt from unprocessed, unfiltered sea water.