OHR MIXER — ozone treatment

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OHR MIXER Liquid–Liquid, Gas–Liquid, Solid–Liquid — the tougher the environment the more dramatic the results

Conventional ozone treatment requires bulky, complex equipment that is expensive and inefficient

Photo of ozone gas bubbling

Conventional ozone treatment requires bulky, complex equipment that is both expensive and inefficient because it injects large volumes of ozone-poor gas into large concrete tanks. This ozone gas then reacts slowly with the target substances in the wastewater.
While ceramic porous air diffusers may be used for ozone bubbling, the bubbles they produce are centimeters or millimeters in diameter — these rise much too quickly in the wastewater, allowing large amounts of unreacted ozone to escape into the atmosphere. As unreacted (waste) ozone gas is hazardous to the environment, waste ozone decomposition equipment is an absolute necessity.

The OHR method: high efficiency, low cost

Breaks down both ozone gas and liquids into microparticles

Micro- and nano-bubbles

Photo of Micro-nano bubbles

The OHR MIXER generates micro- and nano-bubbles that remain in liquids for a considerable length of time. In the case of ozone treatment, these fine bubbles of ozone contact and react highly efficiently with target substances in the wastewater. This is thanks to the much larger combined surface area of the OHR MIXER’s fine bubbles, as compared with conventional coarse bubbles.
A water treatment company that independently evaluated the OHR gas–liquid reaction method found that 70% of the gas injected was dissolved as nanobubbles, with the remaining 30% becoming microbubbles plus a small number of coarse bubbles. The pure-white clouds in the photo on the right are ozone microbubbles generated by the OHR MIXER. Being 0.5–3.0 microns across, they remain in the liquid much longer due to their low buoyancy. These invisibly small nanobubbles remain even longer and react even more efficiently with the target substances.

Direct reaction method

Photo

As ozone and wastewater pass through the OHR MIXER, both are broken down into microparticles before centrifugal and centripetal forces cause them to collide and react.
In other words, the ozone gas and target substances make direct contact and react inside the OHR MIXER. Hence the name "direct reaction method".

By contrast, the conventional method is an indirect method. First, coarse ozone bubbles are dissolved into wastewater, then left to make contact and react with the target substances purely by chance.

Real-world cases

Simple and compact

Before and after OHR ozone treatment

On top of doing away with equipment for waste ozone decomposition, the OHR method makes use of small amounts of highly-concentrated ozone gas and thus requires a much smaller ozonizer than does the conventional method.
A particular paper mill has been using our treatment technology to decolor 5,000 m³/day of colored wastewater for more than 10 years, over which time the OHR treatment equipment has consistently performed. This set-up uses: no ozone gas bubbling tank; no waste ozone decomposition equipment; and a much smaller ozonizer than the conventional method. All of this combined brought the initial cost down to $2 million, just one third of the $6 million required by the conventional method. The OHR method provides extremely effective ozone treatment at a fraction of the cost.
A further issue is that conventional methods require regular cleaning as well as replacement of clogged diffuser pipes and plates. With the OHR method, only the pump needs regular maintenance.

Real-world cases

The OHR method can be used without waste ozone decomposition equipment

Waste ozone decomposition equipment is intended to promote the natural decomposition of harmful ozone gas into harmless oxygen by passing it through a tank filled with activated carbon or catalysts. Equipment of this kind must be installed in any facility that uses the conventional ozone treatment method, as it produces large volumes of waste ozone. The activated carbon and catalysts in the tank must also be periodically replaced as they are used up or deteriorate in quality.
With the OHR method, it is possible not to use waste ozone decomposition equipment and significantly lower costs. Please contact us for more information.

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The OHR method can decompose dioxins with ozone alone

Result of analysis.

It is well-established that the conventional method cannot decompose dioxins using ozone alone; a treatment procedure known as AOP is required instead*. Rigorous tests carried out by Company Y in Japan have demonstrated that the OHR method can decompose dioxins in wastewater with ozone alone. The results of their analysis are displayed to the right. Please contact us for more details.

* Advanced Oxidation Processes (AOPs) are a collection of treatment methods in which ozone is combined with hydrogen peroxide or irradiated with UV light to create hydroxyl radicals, the strongest oxidant among all forms of active oxygen.

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WET: a new international standard for effluent wastewater

killfish water flea

Unlike the BOD and COD methods, WET (Whole Effluent Toxicity) testing does not involve chemical analysis but instead directly measures the effect of wastewater on the environment of aquatic organisms such as killifish, algae and water fleas.
BOD and COD indirectly measure the impurity of wastewater using the oxygen consumption of microorganisms or oxidizing agents, but are limited in that they can only measure a portion of the total organic matter. For example, potassium permanganate, an oxidizing agent commonly used for COD testing in Japan, can only detect 40–70% of the total organic matter contained in wastewater. Trace amounts of undecomposed organic matter that are not detected by these tests are discharged into the environment from wastewater emissions sources such as factories and sewage treatment plants. This evidently negatively affects the environment in all manner of ways.
Accordingly, a new standard has been developed to measure the effect of treated water in these respects. This is not an indirect method like BOD and COD, but a direct measurement by bioassay; that is, by exposing living aquatic organisms to treated wastewater.
WET-based regulations have already been introduced in the US, Canada, UK, France, Denmark, South Korea and other countries, with slight variations in terminology and methodology. Similar regulations are shortly to be introduced in Japan.
The box below shows examples of treated water that may still contravene the WET regulations when it has an adverse effect on aquatic organisms.

Examples of wastewater that may contravene WET regulations
  1. Treated water that passes the current effluent standard (based on BOD, COD, etc)
  2. Treated water containing substances that are difficult to identify or currently unregulated
  3. Treated water containing trace chemicals
  4. Treated water that has an adverse effect on life caused by the aggregate toxicity of multiple chemicals

Ozone treatment is an accepted, effective and WET-compliant method that decomposes up to 90% of substances that conventional treatment leaves undecomposed.


Variety of human pharmaceuticals detected in river water

Japan’s Kyoto University analyzed water from the Yodo River for 61 kinds of detectable chemicals over a period of 6 months from October 2009 to March 2010. They detected, in addition to pesticides and herbicides, a wide variety of pharmaceutical substances consumed and excreted by humans, including antipyretic analgesics, hypolipidemics, antihypertensives and anticonvulsants. They posit that these substances were part of treated water from a sewage treatment plant, which had not decomposed them prior to discharge.

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