User:Psiĥedelisto/Ozone generator

A stationary industrial ozone generator

An ozone generator or ozonator is a domestic appliance which intentionally emits ozone (O₃), typically via electrolysis of molecular oxygen (O₂) found naturally in the air. Although commonly used industrially and commercially to deodorize and sometimes even to disinfect indoor spaces, despite there being no evidence of their ability to control airborne pathogens.^[1] Public health agencies in various jurisdictions warn the public against their purchase and use.^[2] In June 2023, the United States Environmental Protection Agency (EPA) reiterated this advice;^[3] in California, all air purifiers must be certified by the Air Resources Board to emit no more than 0.05 parts per million of ozone,^[4] effectively outlawing their sale in the state.^[5][6]

Methods of generation

Coronal discharge method

A homemade ozone generator. Ozone is produced in the corona discharge

This is the most common type of ozone generator for most industrial and personal uses. While variations of the "hot spark" coronal discharge method of ozone production exist, including medical grade and industrial grade ozone generators, these units usually work by means of a corona discharge tube or ozone plate.^[7][8] They are typically cost-effective and do not require an oxygen source other than the ambient air to produce ozone concentrations of 3–6%. Fluctuations in ambient air, due to weather or other environmental conditions, cause variability in ozone production. However, they also produce nitrogen oxides as a by-product. Use of an air dryer can reduce or eliminate nitric acid formation by removing water vapor and increase ozone production. At room temperature, nitric acid will form into a vapour that is hazardous if inhaled. Symptoms can include chest pain, shortness of breath, headaches and a dry nose and throat causing a burning sensation. Use of an oxygen concentrator can further increase the ozone production and further reduce the risk of nitric acid formation by removing not only the water vapor, but also the bulk of the nitrogen.

Ultraviolet light

See also: Photochemistry

UV ozone generators, or vacuum-ultraviolet (VUV) ozone generators, employ a light source that generates a narrow-band ultraviolet light, a subset of that produced by the Sun. The Sun's UV sustains the ozone layer in the stratosphere of Earth.^[9]

UV ozone generators use ambient air for ozone production, no air prep systems are used (air dryer or oxygen concentrator), therefore these generators tend to be less expensive. However, UV ozone generators usually produce ozone with a concentration of about 0.5% or lower which limits the potential ozone production rate. Another disadvantage of this method is that it requires the ambient air (oxygen) to be exposed to the UV source for a longer amount of time, and any gas that is not exposed to the UV source will not be treated. This makes UV generators impractical for use in situations that deal with rapidly moving air or water streams (in-duct air sterilization, for example). Production of ozone is one of the potential dangers of ultraviolet germicidal irradiation. VUV ozone generators are used in swimming pools and spa applications ranging to millions of gallons of water. VUV ozone generators, unlike corona discharge generators, do not produce harmful nitrogen by-products and also unlike corona discharge systems, VUV ozone generators work extremely well in humid air environments. There is also not normally a need for expensive off-gas mechanisms, and no need for air driers or oxygen concentrators which require extra costs and maintenance.

Cold plasma

In the cold plasma method, pure oxygen gas is exposed to a plasma created by DBD. The diatomic oxygen is split into single atoms, which then recombine in triplets to form ozone. It is common in the industry to mislabel some DBD ozone generators as CD Corona Discharge generators. Typically all solid flat metal electrode ozone generators produce ozone using the dielectric barrier discharge method. Cold plasma machines use pure oxygen as the input source and produce a maximum concentration of about 24% ozone. They produce far greater quantities of ozone in a given time compared to ultraviolet production that has about 2% efficiency. The discharges manifest as filamentary transfer of electrons (micro discharges) in a gap between two electrodes. In order to evenly distribute the micro discharges, a dielectric insulator must be used to separate the metallic electrodes and to prevent arcing.

Electrolytic

Electrolytic ozone generation (EOG) splits water molecules into H₂, O₂, and O₃. In most EOG methods, the hydrogen gas will be removed to leave oxygen and ozone as the only reaction products. Therefore, EOG can achieve higher dissolution in water without other competing gases found in corona discharge method, such as nitrogen gases present in ambient air. This method of generation can achieve concentrations of 20–30% and is independent of air quality because water is used as the source material. Production of ozone electrolytically is typically unfavorable because of the high overpotential required to produce ozone as compared to oxygen. This is why ozone is not produced during typical water electrolysis. However, it is possible to increase the overpotential of oxygen by careful catalyst selection such that ozone is preferentially produced under electrolysis. Catalysts typically chosen for this approach are lead dioxide^[10] or boron-doped diamond.^[11]

The ozone to oxygen ratio is improved by increasing current density at the anode, cooling the electrolyte around the anode close to 0 °C, using an acidic electrolyte (such as dilute sulfuric acid) instead of a basic solution, and by applying pulsed current instead of DC.^[12]

Special considerations

Ozone cannot be stored and transported like other industrial gases (because it quickly decays into diatomic oxygen) and must therefore be produced on site. Available ozone generators vary in the arrangement and design of the high-voltage electrodes. At production capacities higher than 20 kg per hour, a gas/water tube heat-exchanger may be utilized as ground electrode and assembled with tubular high-voltage electrodes on the gas-side. The regime of typical gas pressures is around 2 bars (200 kPa) absolute in oxygen and 3 bars (300 kPa) absolute in air. Several megawatts of electrical power may be installed in large facilities, applied as single phase AC current at 50 to 8000 Hz and peak voltages between 3,000 and 20,000 volts. Applied voltage is usually inversely related to the applied frequency.

The dominating parameter influencing ozone generation efficiency is the gas temperature, which is controlled by cooling water temperature and/or gas velocity. The cooler the water, the better the ozone synthesis. The lower the gas velocity, the higher the concentration (but the lower the net ozone produced). At typical industrial conditions, almost 90% of the effective power is dissipated as heat and needs to be removed by a sufficient cooling water flow.

Because of the high reactivity of ozone, only a few materials may be used like stainless steel (quality 316L), titanium, aluminium (as long as no moisture is present), glass, polytetrafluorethylene, or polyvinylidene fluoride. Viton may be used with the restriction of constant mechanical forces and absence of humidity (humidity limitations apply depending on the formulation). Hypalon may be used with the restriction that no water comes in contact with it, except for normal atmospheric levels. Embrittlement or shrinkage is the common mode of failure of elastomers with exposure to ozone. Ozone cracking is the common mode of failure of elastomer seals like O-rings.

Silicone rubbers are usually adequate for use as gaskets in ozone concentrations below 1 wt%, such as in equipment for accelerated aging of rubber samples.

Incidental production

Ozone may be formed from O
₂ by electrical discharges and by action of high energy electromagnetic radiation. Unsuppressed arcing in electrical contacts, motor brushes, or mechanical switches breaks down the chemical bonds of the atmospheric oxygen surrounding the contacts [O
₂ → 2O]. Free radicals of oxygen in and around the arc recombine to create ozone [O
₃].^[13] Certain electrical equipment generate significant levels of ozone. This is especially true of devices using high voltages, such as ionic air purifiers, laser printers, photocopiers, tasers and arc welders. Electric motors using brushes can generate ozone from repeated sparking inside the unit. Large motors that use brushes, such as those used by elevators or hydraulic pumps, will generate more ozone than smaller motors.

Ozone is similarly formed in the Catatumbo lightning storms phenomenon on the Catatumbo River in Venezuela, though ozone's instability makes it dubious that it has any effect on the ozonosphere.^[14] It is the world's largest single natural generator of ozone, lending calls for it to be designated a UNESCO World Heritage Site.^[15]

Laboratory production

A laboratory method for the preparation of ozone by using Siemen's Ozoniser.

In the laboratory, ozone can be produced by electrolysis using a 9 volt battery, a pencil graphite rod cathode, a platinum wire anode and a 3 molar sulfuric acid electrolyte.^[16] The half cell reactions taking place are:

${\displaystyle {\begin{aligned}&{\ce {3 H2O -> O3 + 6 H+ + 6 e-}}&&(\Delta E^{\circ }=-{\text{1.53 V}})\\&{\ce {6 H+ + 6 e- -> 3 H2}}&&(\Delta E^{\circ }={\text{0 V}})\\&{\ce {2 H2O -> O2 + 4 H+ + 4 e-}}&&(\Delta E^{\circ }={\text{1.23 V}})\end{aligned}}}$

where E° represents the standard electrode potential.

In the net reaction, three equivalents of water are converted into one equivalent of ozone and three equivalents of hydrogen. Oxygen formation is a competing reaction.

It can also be generated by a high voltage arc. In its simplest form, high voltage AC, such as the output of a neon-sign transformer is connected to two metal rods with the ends placed sufficiently close to each other to allow an arc. The resulting arc will convert atmospheric oxygen to ozone.

It is often desirable to contain the ozone. This can be done with an apparatus consisting of two concentric glass tubes sealed together at the top with gas ports at the top and bottom of the outer tube. The inner core should have a length of metal foil inserted into it connected to one side of the power source. The other side of the power source should be connected to another piece of foil wrapped around the outer tube. A source of dry O
₂ is applied to the bottom port. When high voltage is applied to the foil leads, electricity will discharge between the dry dioxygen in the middle and form O
₃ and O
₂ which will flow out the top port. This is called a Siemen's ozoniser. The reaction can be summarized as follows:^[17]

${\displaystyle {\ce {3O2->[{\text{electricity}}]2O3}}}$

References

1. "Hazardous Ozone-Generating Air Purifiers". California Air Resources Board. Retrieved 2023-10-29.
2. "Ozone Generators: What You Need To Know" (PDF). Connecticut Department of Public Health. Retrieved 2023-10-29.
3. "Ozone Generators that are Sold as Air Cleaners" (June 2023 ed.). United States Environmental Protection Agency (US EPA). August 2014.
4. California Code of Regulations, Title 17, Division 3, Chapter 1, Subchapter 8.7, Article I (PDF) (Regulation 94800 et seq., for limiting ozone emissions from indoor air cleaning devices). California Air Resources Board. 2019.
5. Wilson, Janet (2007-09-28). "State bans home ozone air purifiers". Los Angeles Times. Retrieved 2023-10-29.
6. "Why can't I ship an ozone generator to an address in California?". Amazon.com Questions & Answers. 2017-01-24. Retrieved 2023-10-29.
7. "Ozone Cell vs Ozone Plate – A2Z Ozone". Archived from the original on 2020-01-10. Retrieved 2020-01-10.
8. Smith, L. I.; Greenwood, F. L.; Hudrlik, O. (1946). "A laboratory ozonizer". Organic Syntheses. 26: 63; Collected Volumes, vol. 3, p. 673.
9. Dohan, J. M.; W. J. Masschelein (1987). "Photochemical Generation of Ozone: Present State-of-the-Art". Ozone Sci. Eng. 9 (4): 315–334. doi:10.1080/01919518708552147.
10. Foller, Peter C.; Tobias, Charles W. (1982). "The Anodic Evolution of Ozone". Journal of the Electrochemical Society. 129 (3): 506. Bibcode:1982JElS..129..506F. doi:10.1149/1.2123890.
11. Arihara, Kazuki; Terashima, Chiaki; Fujishimam Akira (2007). "Electrochemical Production of High-Concentration Ozone-Water Using Freestanding Perforated Diamond Electrodes". Journal of the Electrochemical Society. 154 (4): E71. Bibcode:2007JElS..154E..71A. doi:10.1149/1.2509385.
12. Hale, Arthur J. (1919). The Manufacture of Chemicals by Electrolysis. D. Van Nostrand Co. pp. 15, 16. Retrieved 12 September 2019.
13. "Lab Note #106 Environmental Impact of Arc Suppression". Arc Suppression Technologies. April 2011. Retrieved October 10, 2011.
14. ¿Relámpagos del Catatumbo regeneran la capa de ozono? Archived 2016-03-05 at the Wayback Machine. Agencia de noticias de la Universidad del Zulia.
15. "Fire in the Sky". Archived from the original on 2011-07-21. Retrieved 2008-08-16.
16. Ibanez, Jorge G.; Rodrigo Mayen-Mondragon; M. T. Moran-Moran (2005). "Laboratory Experiments on the Electrochemical Remediation of the Environment. Part 7: Microscale Production of Ozone". Journal of Chemical Education. 82 (10): 1546. Bibcode:2005JChEd..82.1546A. doi:10.1021/ed082p1546.
17. Brown, Theodore L.; LeMay, H. Eugene Jr.; Bursten, Bruce E.; Burdge, Julia R. (2003) [1977]. "22". In Nicole Folchetti (ed.). Chemistry: The Central Science (9th ed.). Pearson Education. pp. 882–883. ISBN 978-0-13-066997-1.