Water Parks

It boosts the activity of aerobic bacteria that break down fats, oils, and proteins faster by increasing oxygen availability. Technically, the system generates ultra-fine nanobubbles that enhance gas-liquid mass transfer rates, accelerating aerobic biodegradation and suppressing anaerobic microbial processes responsible for sludge formation.

Smaller bubbles have higher surface area-to-volume ratios and longer residence times in water, improving oxygen dissolution efficiency. Unlike larger bubbles that rapidly surface and collapse, nanobubbles remain suspended and create a stable oxygen-rich microenvironment, optimizing oxidation reactions critical for organic matter breakdown.

These molecules possess both hydrophilic and lipophilic properties, enabling emulsification of hydrophobic fats and oils. This emulsification enhances bioavailability of organic pollutants to aerobic microbes, accelerating enzymatic hydrolysis and microbial uptake, which collectively reduce organic load and prevent deposit buildup.

No, it maintains chemical stability by complementing sanitizer and pH control regimes. The bio-catalytic process minimizes reliance on harsh oxidizing chemicals by biologically degrading organics, thereby preserving water chemistry equilibrium and reducing the formation of disinfection byproducts.

Yes. Enhanced microbial degradation reduces organic sludge accumulation and suppresses sulfide-producing bacteria, leading to less frequent mechanical cleaning and chemical dosing. This lowers operational costs and system downtime while improving treatment efficiency.

By elevating dissolved oxygen concentrations, the system inhibits anaerobic sulfate-reducing bacteria that generate hydrogen sulfide (H₂S) and other volatile sulfur compounds. Promoting aerobic microbial populations shifts microbial ecology towards odor-neutral metabolite production, improving ambient air quality.

Yes. The formulation utilizes biodegradable amphiphilic biosurfactants derived from natural fermentation supernatants, ensuring non-toxicity and environmental compatibility while eliminating the need for harmful chemical biocides.

It is injected directly into circulation or filtration streams, where nanobubbles and bio-catalysts interact with contaminants continuously. This integration requires minimal retrofitting and supports automated dosing control, enabling real-time response to water quality fluctuations.

Sustained use leads to stabilized microbial consortia, reduced organic fouling, and diminished chemical oxidant demand. Operators benefit from clearer water, decreased sludge, lower maintenance frequency, and improved swimmer experience with consistent water quality.

Initial reductions in turbidity and odor can be observed within days as aerobic microbial activity increases. Over weeks, enhanced enzymatic degradation and biofilm disruption contribute to long-term organic matter control and sustained system performance.