THE ANTI-LIMESCALE SOLUTION
(*Patented Technology)
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SCOPE ASIA -PROFI-®
An electromagnetic field is generated by an induction pipe in the STAP process. So-called submicroscopic clusters of the ions dissolved in the water are formed by stimulation of the coil current of the electromag- netic field induced by the STAP process.
These clusters act as crystallisation nuclei and – especially when the fluid is heated up – cause calcium carbonate to precipitate in the form of suspended particles. This represents a process that competes with calcium deposition on the inner walls of pipes, boilers and machine parts.
As the STAP process continues, more ions from the water accumulate on these crystallisation nuclei caused by precipitation, which can lead to a considerable growth of these suspended particles, depending on the duration of the electromagnetic effect.
This process takes place throughout the entire volume of water. The crystal nuclei thus formed act as crys- tallisation centres in places of raised supersaturation and, thanks to their growth, succeed in significantly reducing supersaturation. In addition to transforming the molecular structure of constituents – for instance in calcitic molecules – the STAP process is also capable of preventing further deposits.
The crystallisation nuclei formed bind more calcium from the limescale deposits dissipating it as amorphous precipitation. This process continues until the surface is free of deposits. A thin protective layer is formed once the limescale deposits have been dissolved, which is produced by the amorphous surface of the crys- tals reacting with the metallic surface. As soon as the thin protective layer has formed it no longer grows.
These clusters act as crystallisation nuclei and – especially when the fluid is heated up – cause calcium carbonate to precipitate in the form of suspended particles. This represents a process that competes with calcium deposition on the inner walls of pipes, boilers and machine parts.
As the STAP process continues, more ions from the water accumulate on these crystallisation nuclei caused by precipitation, which can lead to a considerable growth of these suspended particles, depending on the duration of the electromagnetic effect.
This process takes place throughout the entire volume of water. The crystal nuclei thus formed act as crys- tallisation centres in places of raised supersaturation and, thanks to their growth, succeed in significantly reducing supersaturation. In addition to transforming the molecular structure of constituents – for instance in calcitic molecules – the STAP process is also capable of preventing further deposits.
The crystallisation nuclei formed bind more calcium from the limescale deposits dissipating it as amorphous precipitation. This process continues until the surface is free of deposits. A thin protective layer is formed once the limescale deposits have been dissolved, which is produced by the amorphous surface of the crys- tals reacting with the metallic surface. As soon as the thin protective layer has formed it no longer grows.
