Multioxidative System (MOS)
Water descontamination system focused on reducing organic and microbiological components through AOP technology, enchancing existing water and wastewater treatment systems. This technology improves water quality, reduces costs, and enables water reuse.
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What are the benefits of the Multi-Oxidation System?
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Sustainable system that lowers energy costs
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Personalized
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Tailor-made or Modular
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Compact Size
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Effective degradation of COD level reduction
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Fast degradation (nanoseconds)
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Safe operation (No chemical or gas exposure)
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Does not generate solid waste, sludge and harmful by-product
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Relieves overloaded systems
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Enables WATER REUSE, minimizing water extraction from rivers
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Best Cost Benefit
Characteristics
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Application: Designed for water treatment in any industry or facility that uses and contaminates water.
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Investment: Tailored to client-specific requirements (KPIs); pricing adjusts according to water volume, organic load, decontamination objectives, and necessary modifications.
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Required Equipment and Chemicals: Electrical panel, space for chemicals tanks, ozone generator, and a pneumatic air system. Filters may be necessary as pre-treatment or post-treatment.
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Placement: Easily adaptable for integration at various stages of water treatment, depending on the objectives and specific study requirements.
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Efficiency: Efficiency is adjustable based on application and goals.
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Type of Treatment: Reactor handles organic decontamination only.
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Residual Sludge: If installed before the biological treatment, it reduces the amount of sludge generated.
One of the benefits of the multi-oxidative system is its high efficiency and small physical space requirement. This makes it possible to use the system in small treatment plants for numerous purposes, such as Pumping Stations.
Competitive Advantage of Current Technologies
In water and wastewater treatment, there is no single technology capable of fully treating water. For this reason, treatment plants are designed with a sequential combination of technologies that remove various contaminants, such as suspended solids, dissolved solids, dissolved gases, organic matter, and biological material. The choice of solutions depends on the type of water being treated and its final purpose—whether for reuse, discharge, surface water treatment, or potable water production.
The Multioxidative System (MOS) is an advanced organic treatment solution. Below is a comparison of conventional treatment methods currently used for organic decontamination. It is important to note that in many cases, the MOS should be implemented alongside these technologies rather than as a direct replacement.
Comparison of Conventional Organic Treatment Technologies
Activated Sludge Process
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Large area occupation
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High energy consumption
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Uses chemicals and biological agents
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Produces sludge as a by-product
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May require odor control
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High investment and lengthy construction time
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Complex maintenance
UASB Reactor
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Large area occupation
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Not applicable to all treatment needs
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Effluent quality can be affected by variability
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Moderate degradation rate
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Uses chemicals and biological agents
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Produces toxic by-products (gases)
UV Treatment (Mainly for biological treatment)
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Requires periodic light bulb replacement
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Energy consumption
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Limited efficiency if the effluent is dark
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Often requires chemicals for Advanced Oxidation Processes (AOP)
Reverse Osmosis – Membranes
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Requires specialized membranes
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Periodic membrane replacement
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High maintenance costs
The Multioxidative System offers a modular and flexible approach to organic decontamination, allowing industries to optimize their treatment processes, enhance existing technologies, and reduce operational costs while ensuring compliance with environmental regulations.
Where can the Multioxidative System be implemented?
Multioxidative Industries Applications
The Multioxidative System has been successfully applied across various industries. Below, you can explore the key industries where it is used, how its application works, why the system is beneficial, and the main advantages it offers to the industry.
