Light oxygen plasma purification integrated machine

1、 The relevant characteristics of the photo oxygen plasma purification integrated machine:

This purification machine can remove major pollutants such as volatile organic compounds (VOCs), ammonia, hydrogen sulfide, inorganic substances, thiols, as well as various odors. The deodorization efficiency can reach over 98%. It can eliminate long-term diffuse and accumulated odors and odors within 24 hours, and has the ability to kill various microorganisms such as viruses in the air. It also has a very obvious effect.

The "low-temperature plasma" technology is an electrochemical process under the comprehensive action of electronics, chemistry, catalysis, etc., and is a new field. It relies on the electric field energy generated by plasma in an instant to ionize and crack the chemical bond energy of gases, thereby destroying the molecular structure of exhaust gas and achieving purification purposes.

2、 Related properties of the integrated photocatalytic plasma purification machine:

The photo generated holes have the ability to acquire electrons, which can react with O2 and H2O adsorbed on the catalyst surface to generate hydroxyl radicals, thereby further oxidizing pollutants. Due to the synergistic effect of a large number of factors such as electron impact, active particles, and ultraviolet radiation in the plasma discharge photocatalytic process, substances in the air can be decomposed and deodorized.

3、 The physical and chemical principles of the integrated photocatalytic plasma purification machine:

The ions, electrons, excited titanium atoms, molecules, and free radicals in the plasma of the photo oxygen plasma purification integrated machine are all reactive substances, which make reactions that are difficult or slow under normal conditions difficult to carry out. They further react with pollutant molecules and ions, thereby degrading pollutants, especially for the treatment of difficult to degrade pollutants.

In addition, due to the downward transition of some excited particles during the discharge of reactive ions and free radical gases, ultraviolet light can be generated. When the energy of photons or electrons is greater than the bandgap width of the semiconductor, they will excite electrons inside the semiconductor, causing electrons to transition from the valence band to the conduction band, forming active electron hole pairs, and further inducing a series of redox reactions.