Micro-electrolysis Catalyst
Hotspots:
1300-degree high-temperature sintering, stable, and efficient
No agglomeration, no passivation
Direct supply from the manufacturer, free sampling
Efficient removal of COD
Reduce chromaticity
Improve biodegradability
The treatment effect is long-lasting and stable, and low consumption
1. The iron-carbon filler is composed of a multi-metal molten catalyst that melts at high temperature to ensure that the "galvanic cell effect" is continuously effective.
2. The iron-carbon filler can work in a variety of scenarios, with strong activity, light weight, no agglomeration or passivation, fast reaction speed, and long-term stable and effective operation. General industrial wastewater only takes half an hour
to several hours. 3. The process flow is simple, the service life is long, the investment cost is low, the operation and maintenance are convenient, the operating cost is low, and the treatment effect is stable. Only a small amount of micro-electrolysis reactants are consumed during the treatment process. 4. It has a good coagulation effect, high chromaticity and COD removal rates, and the same amount can greatly improve the biodegradability of wastewater.
5. After the wastewater is treated with micro-electrolysis, original ferrous or ferric ions will be formed in the water, which has a better coagulation effect than ordinary coagulants. There is no need to add coagulants such as iron salts, and it will not cause secondary pollution to the water.
Ozone Oxidation Catalyst
(1) Composite porous high-strength silicon-aluminum catalytic carrier, uniformly loaded with catalytic components that are not easy to lose, improving the stability of the catalyst. The carrier is prepared using a special preparation process, with high mechanical strength and long service life.
(2) Carefully select the carrier and active components of the catalytic filler, and use transition metals, rare metals, and rare earth metals as effective catalytic components to ensure the continuous and efficient ozone oxidation efficiency.
(3) A variety of catalytic components enhance the adaptability of the catalyst to different wastewaters while improving the catalytic activity.
(4) The catalytic filler has no loss and does not need to be added regularly.
(5) It can catalyze the self-decomposition of ozone in water, increase the concentration of ·OH produced in water, thereby improving the ozone oxidation effect, and the oxidation efficiency is 2 to 4 times higher than that of simple ozone oxidation.
(6) It can reduce the reaction activation energy or change the reaction process, thereby achieving the purpose of deep oxidation and maximizing the removal of organic pollutants.
Fenton Reaction Catalyst
(1) This product uses porous composite materials as catalyst carriers, which have high mechanical strength and are doped with a variety of catalytic components that are not easy to lose, thereby improving the catalytic activity and stability of the catalyst. High-temperature sintering technology effectively reduces the loss rate of catalytic fillers, prevents secondary pollution, and prolongs the service life while ensuring high utilization and high adhesion of active components.
(2) This product screens the carriers and active components of catalytic fillers through a large number of tests and engineering applications to ensure that the Fenton reaction catalyst effect is continuously efficient.
(3) This product improves the catalytic activity of the catalyst and its adaptability to the pH of the reaction wastewater by screening suitable carriers and catalytic components, and to a certain extent broadens the pH range of the reaction.
(4) This product replaces the addition of ferrous ions in traditional Fenton, avoids the generation of a large amount of iron sludge, prevents the generation of secondary pollution, and greatly improves the shortcomings of traditional Fenton.
Autotrophic Denitrification Filler
(1) Stable chemical properties, long life and reusable.
(2) No chemical agents are added, which reduces treatment costs and prevents COD from exceeding the standard.
(3) Short residence time and fast degradation rate.
(4) No large amount of sludge is produced, reducing sludge treatment costs.
(5) Simple process equipment and high degree of operation automation.
(6) Supporting facilities can be constructed and equipped according to scale and user requirements to meet various needs.
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