RU2002135644A

RU2002135644A - METHOD FOR SYNTHESIS OF OXIDIZER AND ITS APPLICATION

Info

Publication number: RU2002135644A
Application number: RU2002135644/15A
Authority: RU
Inventors: Лее Эдвард СИАМПИ; Грегори Ф. СМИС; Бёрни КНОБЛ
Original assignee: Эй Би Инишио Л. Си
Priority date: 2000-07-14
Filing date: 2001-07-12
Publication date: 2004-06-27

Claims

1. A method for the continuous synthesis of ferrate, comprising a) mixing an aqueous solution containing an iron salt and an oxidizing agent in a mixing chamber, b) delivering at least a portion of the aqueous solution to the reaction chamber, c) continuously generating ferrate in the reaction chamber, d) delivery at least a portion of the ferrate to the place of use adjacent to the reaction chamber; and e) adding an additional aqueous solution to the mixing chamber.

2. The method according to claim 1, further comprising adding a base to the aqueous solution.

3. The method according to claim 1, further comprising repeating steps (b) to (d).

4. A method of treating an aqueous mixture with at least one contamination at the place of use, comprising a) continuously producing ferrate in a reaction chamber adjacent to the place of use, b) contacting the ferrate with the aqueous mixture at the place of use, wherein at least a portion of the contamination is oxidized .

5. A method of treating an aqueous mixture with at least one contamination at the place of use, comprising a) continuously producing ferrate in a reaction chamber adjacent to the place of use, b) contacting the ferrate with the aqueous mixture at the place of use, at least a portion of the contamination coagulated .

6. The method according to claim 4 or 5, in which the step of continuous production of ferrate comprises the steps of a) mixing an aqueous solution containing an iron salt and an oxidizing agent in a mixing chamber, b) delivering at least a portion of the aqueous solution to the reaction chamber, c) continuous production of ferrate in the reaction chamber, d) delivery of at least a portion of the ferrate to the place of use located next to the reaction chamber, and e) adding an additional aqueous solution to the mixing chamber.

7. The method according to claim 6, further comprising adding a base to the aqueous solution.

8. A device for the continuous synthesis of ferrate for delivery to the place of use, containing a) a first tank, b) a second tank, c) a mixing chamber, which is connected with the ability to control the first tank and the second tank and into which the contents are added to form the first mixture the first tank and the contents of the second tank, d) a reaction chamber connected with the possibility of control with a mixing chamber, while the reaction chamber is adapted to receive the first mixture and hold the first mixture over a period of time, e) a ferrate mixture in the reaction chamber, and e) an outlet in the reaction chamber through which the ferrate mixture can be transported to the place of use, the place of use being located close to the reaction chamber.

9. The device of claim 8, in which the mixing chamber further comprises a temperature control device.

10. A method for purifying drinking water, comprising contacting the ferrate produced by the method according to claim 1 with drinking water, in which the contacting is carried out in a place close to the place of production.

11. A method of treating water waste, comprising contacting the ferrate produced by the method according to claim 1, with water waste, in which contacting is carried out in a place close to the place of generation.

12. A method of treating wastewater comprising contacting a ferrate produced by the method of claim 1 with wastewater in which contacting is carried out at a location close to the production site.

13. A method for the continuous synthesis of ferrate, comprising a) providing a mixture of an iron salt and an oxidizing agent, b) continuously delivering at least a portion of the mixture to the heating chamber, c) exposing the mixture to elevated temperatures in the heating chamber, thereby producing ferrate, d) removing at least a portion of the ferrate generated in step b) from the heating chamber, e) adding an additional mixture to the heating chamber.

14. A device for the continuous synthesis of ferrate, containing a) a tank, b) a conveyor connected with the ability to control the tank so that at least part of the contents of the tank is transferred to the conveyor, c) a heating chamber through which at least part of the conveyor moves, d) an outlet in the heating chamber, through which the contents on the conveyor can be transported to the place of use, and the place of use is located near the heating chamber.

15. The device according to 14, in which the heating chamber further comprises a temperature control device.

16. A device for the continuous synthesis of ferrate, containing a) a mixing chamber containing two electrodes and an iron salt solution, while the electrodes provide sufficient electric current to convert the iron salt solution into a ferrate solution, b) a reaction chamber, which is connected to control the mixing a chamber and in which the ferrate solution is held for a period of time, and c) an outlet in the reaction chamber through which the mixture can be transported to the place of use, and the place is used Use is located near the reaction chamber.

17. A method for the continuous synthesis of ferrate, comprising a) continuously supplying an aqueous solution containing an iron salt to the mixing chamber, the mixing chamber containing at least two electrodes, b) supplying at least two electrodes of electric current sufficient to convert at least a portion of the iron salt in the ferrate; c) delivering at least a portion of the ferrate to a place of use that is adjacent to the reaction chamber; and d) adding an additional aqueous solution to the mixing chamber.

18. The method of claim 17, further comprising adding a base to the aqueous solution.

19. A method for synthesizing a ferrate, comprising a) mixing an aqueous solution containing an iron salt and an oxidizing agent in a mixing chamber to form a ferrate solution; b) delivering at least a portion of the ferrate to a place of use in the vicinity of the mixing chamber.