JPH0251401A - Mesh electrode ozonizer and its production - Google Patents

Abstract

PURPOSE:To obtain a mesh electrode ozonizer having low discharge voltage capable of inhibiting generation of NOX as well as having high wear resistance by fixing a discharge electrode of the mesh electrode to a thin ceramic plate with an adhesive agent or by brazing. CONSTITUTION:When a mesh electrode of a mesh electrode ozonizer is fixed with an adhesive agent, the mesh electrode 36 is bonded and fixed with an adhesive agent 50 so as to be bonded at both ends of the mesh electrode 36 to a thin ceramic plate 32. It is necessary to use an adhesive agent 50 which causes scarce deterioration by the elevation of temp. in a stage of discharge. When the mesh electrode is fixed by brazing without using the adhesive agent, Cu or Ag-Pd is metallized by vapor-deposition, etc., as an earthing electrode 38 to a rear side of the thin ceramic plate 32. On the front surface side, a metal layer 60, 60 is formed by metallizing by the vapor-deposition, etc., of Cu or Ag-Pd to both ends of a position where the mesh electrode 36 on the thin ceramic plate 32 is to be bonded and to be fixed. Then, the metal layer 60, 60 formed on the front surface side is brazed to the mesh electrode 36 with a stainless steel solder 62, 62.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to an ozonizer that generates ozone, and in particular to a mesh electrode ozonizer that has a low discharge voltage, suppresses the generation of NO, and has excellent wear resistance. Regarding the manufacturing method.

[Conventional technology]

As a conventional ozonizer, one configured as shown in FIGS. 2(a) to 2(C) is known. Here, FIGS. 2(a) to (C) show the structure of a conventional ozonizer, and (a)
shows a plan view, (b) shows a back view, and (C) shows a side view.

In FIG. 2, reference numeral 12 is an insulating ceramic thin plate, and both sides of this ceramic thin plate 12 are electrically charged. 1
4 and 16 are arranged.

The electrode 14 is a ground electrode, the electric current Ir! 16 is a discharge electrode.

Conventionally, both electrodes 14 and 16 are made of stainless steel plates, or metal electrodes formed by metallization such as vapor deposition or baking. Both types of the ozonizer 10 configured in this way If! High frequency high voltage between 14.16 and 20
When the voltage is applied, a discharge occurs in the peripheral portion 18 of the discharge electrode 16. Therefore, by flowing air or oxygen near this electrode, ozone can be generated.

[Problem to be solved by the invention]

However, according to the conventional ozonizer 10 using the discharge electrode 16 described above, the high frequency high voltage 20 is applied to the electrode 14.
16, the only part that is discharged is the peripheral part 18 of the discharge electrode 16, so the length that contributes to the discharge is only the peripheral length, which is short. Therefore, in order to generate a large amount of ozone, it is necessary to stop the discharge. It is necessary to increase the current strength, and a large current must be passed, resulting in a large local temperature rise in the ozonizer 10. Therefore, N2 in the air becomes more likely to become NOx, and NO
, and the wear of the discharge portion 18 of the electrode 16 increases, resulting in a shortened lifespan.

Furthermore, since the discharge electrode is thin, the capacitance of the discharge space increases, and the applied voltage required for discharge increases.

For this reason, there is also the drawback that the power supply device for the discharge circuit becomes expensive.

Furthermore, because the discharge electrode is thin, it is subject to severe wear due to discharge, so it is important to extend its life! It was also necessary to apply a coating treatment to prevent the electrodes from coming into direct contact with the air.

Therefore, an object of the present invention is to be able to secure a long length of the electrode that contributes to discharge, and also to be able to discharge with a low applied voltage, thereby suppressing local temperature rise and minimizing the amount of NO generated. Furthermore, it is an object of the present invention to provide an ozonizer equipped with a discharge electrode that can maintain a long service life without coating, and a method for manufacturing the same.

[Means to solve the problem]

The mesh electrode ozonizer according to the present invention is an ozonizer that generates ozone by causing air or oxygen to flow through the surface of a discharge electrode to which a high frequency and high voltage is applied. It is characterized by being configured as a discharge electrode of an electrode.

In the mesh electrode ozonizer, the discharge electrode of the mesh electrode can be manufactured by adhesively fixing it to a ceramic thin plate using an adhesive.

Further, it is more preferable to manufacture the ceramic thin plate by metallizing it and then bonding and fixing the metallized metal and the discharge electrode of the mesh electrode by brazing.

[Effect]

According to the mesh electrode ozonizer according to the present invention, by using the mesh electrode as a discharge electrode, even if the discharge electrode has the same area as the conventional one, the entire surface of the mesh electrode is discharged, so the peripheral length is substantially longer than that of a flat plate electrode. Therefore, the length of the discharge section can be increased.

Therefore, the discharge output can be reduced compared to the conventional method while obtaining the same amount of ozone generation as the conventional method.

Furthermore, since the winding of the mesh electrode can be made thicker, the capacitance of the discharge space can be reduced, and the discharge starting voltage can be lowered.

Furthermore, since the winding is thick, it has a long lifespan against wear due to electrical discharge, and there is no need for coating.

The mesh electrode can be easily adhesively fixed to the ceramic thin plate using an adhesive. Further, if the mesh electrode is bonded by brazing after metallizing the ceramic thin plate, the bonding time can be shortened and the bonding reliability can be improved.

〔Example〕

Next, regarding an example of the mesh electrode ozonizer according to the present invention,
A detailed description will be given below with reference to the accompanying drawings.

Figures 1 (a) to (C) show the configuration of a mesh electrode ozonizer showing one embodiment of the present invention, in which (a) is a plan view, (b) is a back view, and (C) is a side view. In FIG. 1, reference numeral 32 is an insulating ceramic thin plate.

A stainless steel net 36 is tightly adhered and fixed to one side of the ceramic thin plate 32, and a stainless steel plate 34 is bonded and fixed to the back side. The stainless steel plate 34 of the mesh electrode ozonizer 30 constructed in this way is used as a ground electrode, and the stainless steel mesh 36 is used as a discharge electrode. When a high frequency high voltage 40 is applied between the picture electrodes 34 and 36, the mesh electrode ozonizer 30 The discharge occurs over the entire surface of the net 36.

In other words, although the area occupied by the discharge electrode with respect to the ceramic thin plate 32 is the same as that of the conventional example, it is possible to ensure a long length that contributes to discharge. Therefore, in order to obtain the same amount of ozone generation as the conventional ozonizer, the discharge may be weak.

Here, a method for adhesively fixing the mesh electrode 36 according to the present invention to the ceramic thin plate 32 will be explained.

FIGS. 3(a) to 3(C) show a method of bonding mesh electrodes using an adhesive. In FIG. 3, (a) shows a plan view of the mesh electrode ozonizer 30, (b) shows a back view, and (C) shows a side view. It can be easily adhesively fixed using the adhesive 50. Here, this adhesive 5
0, it is necessary to use a material that is less susceptible to deterioration due to temperature rise during discharge.

Furthermore, when bonding and fixing the mesh electrode 36 with the adhesive 50, the curing time of the adhesive 50 must be carefully monitored.

FIGS. 4(a) to (C) show an adhesive fixing method when no adhesive is used, and (a) shows the mesh electrode ozonizer 30.
, (b) is a back view, and (C) is a side view.On the back side of the ceramic thin plate 32, copper or silver palladium is metalized by vapor deposition or the like as a ground electrode 38.The ceramic thin plate 32 is on the front side. At both ends of the place where the upper mesh electrode 36 is adhesively fixed, @ or silver palladium is metalized over a width of 3n+i to 51 to form a metal layer 60.60.The metal layer 60.60 is formed on the surface side. 60 and the stainless steel mesh electrode 36 are brazed with stainless steel solder 62.62. Thereby, the adhesive fixation of the net@pole 36 onto the ceramic thin plate 32 is completed quickly and reliably.

Note that the thicker the wires forming the mesh electrode 36, the longer the lifespan against wear and the smaller the capacitance of the discharge space.

〔Effect of the invention〕

As is clear from the embodiments described above, according to the present invention,
By using a mesh electrode as the ozonizer's discharge electrode, the discharge occurs over the entire surface of the mesh, so a longer discharge length can be secured compared to conventional flat plate electrodes, and the discharge output is increased even though the same amount of ozone is generated with the same electrode area. can be weakened. Therefore, the local temperature rise becomes smaller and NOx
can reduce the occurrence of Since the discharge output becomes weaker, the wear of the mesh electrode itself due to discharge is also reduced.

Furthermore, since the strands of the #I electrode can be made thicker, it has a longer lifespan against wear due to discharge, and there is also the effect that the conventional coating treatment on the electrode is not necessary. If the strands are made thicker, the capacitance of the discharge space becomes smaller and discharge starts at a lower applied voltage, which simplifies the configuration of the ozonizer's power transformer and high-frequency, high-voltage circuit, and keeps costs low.

The mesh electrode used in this mesh electrode ozonizer can be manufactured at low cost and easily, since the wire mesh serving as the electrode can be adhesively fixed onto a thin ceramic plate using an adhesive.

Also, after metallizing the ceramic thin plate, the metallized metal and the wire mesh that will become the electrode are bonded and fixed by brazing.#! If the J electrode manufacturing method is used, the bonding time is significantly shortened compared to the case using the above-mentioned adhesives, and it is excellent in mass production. It is also resistant to temperature rise during discharge, and the reliability of bonding is also significantly improved. be able to.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited to the above embodiments. For example, if mesh electrodes are bonded to both sides of a ceramic thin plate, an ozonizer that discharges on both the front and back sides can be created. Instead of a wire mesh, a metal evaporated electrode with a mesh pattern (or a screen 4) is used.

The same effect of discharging on the mesh surface can be obtained even if a metal electrode (using the metal electrode method) is used, and therefore, it goes without saying that various design changes can be made without departing from the spirit of the present invention.

[Brief explanation of the drawing]

FIGS. 1(a), (b), and (c) are a plan view, a back view, and a side view, respectively, and FIGS. 2(a) and (b) show an example of the configuration of a mesh electrode ozonizer according to the present invention. (C) is a plan view, a back view, a side view, and FIG. 3(a) showing the configuration of a conventional ozonizer. (b) and (C) are a plan view, a back view, and a side view, respectively, showing a configuration example in which the mesh electrode of the ozonizer according to the present invention is manufactured using an adhesive; C) is a plan view, a rear view, and a side view, respectively, showing an example of a configuration in which the mesh electrode of the ozonizer according to the present invention is manufactured using metallization and brazing. 10...Conventional ozonizer 12...Ceramic thin plate 4...Ground electrode 6...Discharge electrode 8...Discharge part (surrounding part) O...High frequency high voltage 0...Mesh electrode ozonizer 2 ... Ceramic thin plate 4 ... Ground electrode 6 ... Mesh electrode 8 ... Ground electrode 0 ... High frequency high voltage 0 ... Adhesive 0 ... Metallized metal layer 2 ... Brazing The markings are solder u, ink b I, I

Claims (3)

[Claims] (1) In an ozonizer that generates ozone by passing air or oxygen across a discharge electrode surface to which a high frequency and high voltage is applied, at least one of the two electrodes that sandwich a ceramic thin plate is configured as a mesh discharge electrode. A mesh electrode ozonizer characterized by: (2) The method for manufacturing a mesh electrode ozonizer according to claim 1, characterized in that the discharge electrode of the mesh electrode is adhesively fixed to the ceramic thin plate using an adhesive. (3) The method of manufacturing a mesh electrode ozonizer according to claim 1, characterized in that after metallizing the ceramic thin plate, the metallized metal and the discharge electrode of the mesh electrode are bonded and fixed by brazing.