Sizing of Ozone Generators

Sizing an ozone generator can be made simple with the right information. However, obtaining said information can sometimes be problematic.

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&#;When selecting and sizing an ozone generator for your application, there are three important points to consider for effective results&#;

When selecting and sizing an ozone generator for your application, there are three important points to consider for effective results:

1. Ozone demand (g/m3, mg/l, ppm, etc.): The most important information when selecting an ozone generator for your project or application is an ozone demand, or how much ozone per volume of water or air you need to apply to remedy an existing problem, which is typically the inactivation of harmful or dangerous bacteria or contaminants. You can determine ozone demand through various means, including:
   • Published Scientific Studies
   • CT (Concentration Time) Factor Tables for Bacteria Deactivation
   • Experience or Pilot Testing
   • Government Regulations
2. Volume: The amount of water, air, gas, etc., that you need to treat (m3/h, GPM, SLPM, etc.).
3. Compensation: Implementing proper compensation is crucial to account for factors limiting ozone participation in the reaction. This compensation considers the efficiency of the ozone dissolution process, ozone concentration, and ozone decay half-life.

Once you know the ozone demand, you multiply it by the gas, water, etc. volume you need to treat. This will give you the theoretical amount of ozone required for your project in an ideal situation.

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Implementing proper compensation for all contributing factors that limit ozone participation in the reaction factors about ozone production will allow you not to undersize the ozone system and achieve greater treatment results.

&#;To help you better understand how you can do the calculations, let us review the following practical example for swimming pool ozone application&#;

To help you better understand how you can do the calculations, let us review the following practical example for swimming pool ozone application.

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• Ozone demand:
  To prevent any bacteria, algae or viruses from growing in the pool and to keep water safe and crystal clear, especially with organic dust and pollen entering the water in outdoor applications, you need to have a theoretical residual ozone concentration of 0.07 ppm, as we have learned from our experience over many years. An indoor pool will most likely work well with 0.04 ppm of residual ozone as indoors, you do not have organic dust, pollen, etc., blown into a pool by wind, dramatically increasing bio load and ozone demand. Some government recommendations suggest 0.03 &#; 0.05 residual ozone concentration, but I would never go as low as 0.03. CT factor for most bacteria diction is about 0.02 ppm/min
• Calculation:
  For a 50 m3 example swimming pool, To create 0.07 ppm ozone concentration (outdoor pool) in ice-cold water, you need to dissolve 0.07 g/m3(ppm) x 50 m3 = 3.5 g of ozone.
• Compensation:
  In reality, these calculations have to be compensated this way to find the actual size of the generator required:
  At 25˚C, the half-life of ozone in water is ~15 minutes (0.25 hours).
  To compensate for natural ozone decay in the water
  you will need to dissolve 3.5 g ÷ 0.25 = 14.0 g/h and not 3.5 g/h as calculations without compensation may suggest.