Ozone Catalyst
O₃ dissolves in water to form hydroxyl radicals (·OH), which have stronger oxidation capability.
With the presence of a catalyst, a larger amount of ·OH is generated, resulting in better oxidation performance and reduced ozone dosage.
Currently, the most commonly used method is to utilize heterogeneous catalysts to promote the generation of hydroxyl radicals from ozone. The reaction unit is filled with solid granular catalysts composed of various noble metals. These catalysts are sintered onto specific carriers and are hardly lost with the water flow during operation.
Ozone catalysts are available in different types, such as alumina-based and carbon-based materials, and are applied according to different water qualities and operating conditions.
Model (with unit) | AK-GDC | AK-GC | AK-XTC | AK-FHC | Custom |
Catalyst Type | Transition Metal | Noble Metal | Rare Earth Metal | Multi-component Composite Metal | |
Specification(mm) | Ф3-5 | Ф3-5 | Ф3-5 | Ф3-5 | |
Strength(N) | ≥100 | ≥100 | ≥100 | ≥100 | |
Pore Volume(ml/g) | ≥0.5 | ≥0.5 | ≥0.5 | ≥0.5 | |
Bulk Density(t/m³) | 0.55~1.2±10% | 0.55~1.2±10% | 0.55~1.2±10% | 0.55~1.2±10% | |
Specific Surface Area(m²/g) | ≥200 | ≥200 | ≥200 | ≥200 | |
Active Component Content(%) | 3-5 | 3-5 | 3-5 | 3-5 | |
Appearance | Spherical | Spherical | Spherical | Spherical | |
Packaging | Ton bag | Ton bag | Ton bag | Ton bag |
