JPS62246807A - System for controlling electric power source in ozonizer - Google Patents

Abstract

PURPOSE:To double the yield of ozone by alternately converting the electron accelerating region by an electric field and the flight region by the residual electron energy in the ozonizer having a parallel electrode and an electron orbit controlling magnetic field. CONSTITUTION:Plural cathode-anode assemblies 1, 2, etc., are classified into the odd-numbered assembly and the even-numbered assembly, the respective odd-numbered assemblies and even-numbered assemblies are collected and electrically connected to form a I-group and a II-group, and a parallel electrode 3 is arranged between the I-group and II-group assemblies. Moreover, a combination of the I-group cathode, the II-group anode, and the parallel electrode 3, and a combination of the II-group cathode, the I-group anode, and the parallel electrode 3 can be alternately converted and operated. Consequently, the electron accelerating region by an electric field and the flight region by the residual electron energy can be alternately converted and switched on both sides of the parallel electrode 3, and the space utilization factor in the ozonizing function can be doubled.

Description

[Detailed Description of the Invention] [Field of Industrial Application] This invention is a power supply control method for a device that ozonizes oxygen molecules by a group of electrons generated during silent discharge [Prior art] In order to improve the efficiency, a cathode is placed at the joint between two insulating plates, and a cathode-anode assembly in which the anode and the convex part of the insulating plate are used as generation points of electrons on the outer surface, and parallel electrodes are alternately arranged. With many cathodes parallel to the poles,
In a device that realizes a t-pole configuration of an anode, the space between the cathode and the parallel electrode is operated mainly as an electron acceleration region by an electric field, and the space between the parallel electrode and the anode is mainly operated as a flight region by electron residual energy. By alternating the areas, the area of one electron group generation in the same space can be reduced to 2.
However, no effective charging method has been proposed to operate the system.

[Purpose of the invention]

The purpose of this invention is to control the power supply of an ozone generator that operates by doubling the area of the principal point of electron swarm in the same space by alternating and changing the electron acceleration region caused by the magnetic field and the flight region mainly caused by the electron residual energy. The purpose is to provide a method.

[Key points of the invention]

In the casting of negative and anode assembly, numbers 1 and 2 are sequentially placed.
, Bamboo-・, divided into odd numbers and even numbers,
By electrically connecting the odd-numbered and even-numbered layers all at once, and controlling the combination of a group of cathodes, a group of anodes, and parallel electrodes to be alternately changed and operated, parallel! By alternately converting both sides of the pole into an electron acceleration region caused by an electric field and a flight region mainly caused by residual electron energy,
The ozone 5 generation function can double the space utilization rate.

Furthermore, by applying a minute voltage between the parallel electrodes and the anode, ions generated in the space can be removed with a minute amount of power.

[Embodiments of the invention]

FIG. 1 shows an example of electrode arrangement of an ozone generator according to the present invention. The cathode and anode assemblies 1.2 are made of insulating materials 1a and 2, respectively.
a and the convex portion 1 which is the generation point of the electron group formed on its surface.
b, 2b, and anode IC, 2C provided on the surface excluding this convex portion.
and cathodes 1d and 2d formed inside an insulating material. Among the cathode and anode assembles arranged in parallel, the odd numbered rows are the A/7" metalwork group, and the even numbered rows are the assemble 2.
are set as one group, and these first group and group (1) are electrically connected together. Parallel electrodes 3 are placed between the assemblies of groups (1) and (2).

Fig. 2 is a wiring diagram when, for example, a bridge type full-wave rectifier is used as the power supply. 6 on, 4 off
When this happens, the electrode potential becomes as shown by the dotted line in FIG.

When the above operation is performed in response to the positive/negative changes in the AC power source, the space on both sides of the parallel electrodes is alternately converted into an electron acceleration area due to the electric field, and mainly a flight area due to residual energy, so that in the same space The area where the electron group is generated can be doubled, that is, the ozone generation intensity can be doubled.

In addition, the flight region due to residual energy has almost no electric field, and by applying a minute potential as necessary, the positive and negative ion molecules generated in this region can be recombined or attached to the electrode and consumed with minimal energy consumption. can.

〔Effect of the invention〕

This has the effect of doubling the area of the generation point of electron groups and doubling the amount of ozone generated in the same space.

FIG. 2 is a power supply wiring diagram, and FIG. 3 is a diagram showing an electrode potential conversion situation.

1... Anode assembly (group I).

2... Anode assembly (Ire).

3...Parallel electrodes.

Figure 1 3-Electrify 11,000 cm ↑

Claims (1)

[Claims] When oxygen molecules are ozonated by a group of electrons generated during silent discharge, in the space formed by the cathode and anode,
An ozone generator having parallel electrodes and a magnetic field for electron trajectory control, characterized in that the electron acceleration region due to the electric field and the flight region mainly due to electron residual energy are alternately converted by switching the operating period of the cathode and anode. Power control method for ozone generator.