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PROPRIETARY  INDUSTRIAL WASTEWATER PURIFICATION TECHNOLOGY 

ONLINE REALTIME MONITORING
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CETI couples real time monitoring for command and control of each system (“SCADA” or Supervisory Control and Data Acquisitions) in the field. Real time data collected with histograms from our modular architecture allows us to deploy machine learning logic. 

For example, based upon a raw water supply sample, we can calculate the most efficient process of contaminant extraction, then customize processes that benefit the most in deploying ultrasonic [with bump back flow] to achieve the highest turnaround efficiencies for cleaning.
CLOSED LOOP CONTROL

With our closed loop systems we can answer some basic questions in real time: IS THE WATER SAFE TO DRINK? IS IT FREE FROM HARMFUL CONTAMINANTS? DOES IT MEET OR EXCEED EPA STANDARDS?

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We know in real time the content of the feed water, intermediate water, clean water and concentrate. All filtered water is approved off of Spectrometric Quality Control [every 10 seconds] of contaminants and implemented on a United Nations SG6 Protocol (which no one else in the United States is using). 

 

On commercial systems, we crystalize the concentrate for collection into waste burial sites. Our sensors are rated ten bar, corrosion proof, with 5000 hours MTBF or [mean time before failure].

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ELECTRO-DIALYSIS
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Electro Dialysis fits into multiple brackish, wellhead, and desalinization applications. Coupled with micro-cavitation techniques, their use forms foundational and post treatment processes found in larger systems. We use it on smaller applications to increase output, efficiency, and reduce energy footprints by 60% over ordinary filtration systems designed for the same purpose.

 

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NANOFILTRATION

Nano-mechanics has evolved into advanced manufacturing methods under single atom strata injection with dynamic results. Integration of submicronic capture is used in several stages of our filtration system, to the extent of pre-filtration prior to membrane implementation.

 

We reduce nominal particulates from 5 microns to .02 microns. Think of it as reducing particulates from 80 ounces being slung at a filter membrane to 3.2 ounces. That equates to 25 times less weight and force which increases membrane system life spans exponentially.

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MICROCAVITATION
Bubbles

Applications determine the best type of technology needed. Included is microbubble, thermal dissipation, accoustical wave, or plasma arc. We deploy the process in the proper nanosphere, thereby decreasing diffusion rates, flocculation rates, retention time, reactant reagents, chemical dosing levels, and antiscalant measures up to 500%. 

 

Our low energy footprint coupled with advanced process methods increase yields far beyond normal ranges found in typical filtration systems.

IMPROVED SELECTIVITY REMOVAL

By using proper molecular sieve technology, we deliver a dedicated single pass with a 700% increase in adsorption. How does this translate in our systems?  7 times LONGER operations or 1/7th the SIZE of our needed filters or increased capacity to deliver 7 times the speed. 

 

It’s all application driven.  Normal sand filtration, comparably on footprint or size, is completely outdated. 1 tablespoon of our filter media contains enough surface area to cover a complete football field. For a single grain of sand, our media is 9,700 times the surface area of that grain, thanks to nanotechnology. 

Molecules Security

80%

60%

INCREASES SALINITY EXTRACTION BY 80%
REDUCED ENERGY & CAPX COSTS
 
BY OVER 60% VS ORDINARY SYSTEMS
BY OVER 80% VS ORDINARY SYSTEMS

100%

20%

100% REMOVAL OF PLASTIC TOXINS
REDUCE POWER COSTS
NONEXISTENT IN MOST WATER SYSTEMS
SAVINGS OF 20% IN PRODUCTION COSTS
SYNOPSIS
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