Minimizing System Footprint Without Compromising Oxidation Performance

Space constraints are a major challenge in modern water treatment, impacting everything from capital costs and retrofitting feasibility to system maintenance. Traditional ozone oxidation systems often require significant real estate for large contact basins, off-gas destruct units, and bulky generator skids.

Achieving a minimal system footprint without sacrificing oxidation performance requires re-engineered system architecture. Key strategies involve replacing massive atmospheric tanks with efficient inline injection methods that achieve over 95% mass transfer efficiency. Additionally, moving away from linearly scaling components to modular, stackable generators allows for high dose capacity within a compact chassis. By integrating the generator, cooling, power control, and degas systems into smaller, pre-assembled skids, projects can see a 30–60% reduction in required space compared to conventional designs. This spatial efficiency not only reduces construction costs but also supports tighter process control and quicker installation.

Read the full article to learn how advanced system design can deliver powerful treatment outcomes in a compact, serviceable, and efficient footprint.