JP3288591B2 - Ionized water production equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to a food processing treatment,
The present invention relates to a method and an apparatus for producing ionized water used for hairdressing, cultivation of agricultural and marine products, and the like.

[0002]

BACKGROUND OF THE INVENTION The present inventor has filed a patent application filed on July 14, 1995 under the title of "Method and Apparatus for Ionized Water Production". No. 7-178410). The present invention provides a method and an apparatus for easily and efficiently producing ionized water, the apparatus comprising a primary coil to which a pulse current is supplied, and a high-voltage generator provided outside the primary coil. An electromagnetic processing device having a spiral pipe formed between the primary and secondary coils, and a pair of discharge electrodes connected to a high-frequency generator and performing a corona discharge. First, water is passed through a spiral pipe to perform electromagnetic treatment,
Next, ionization is performed by dropping between discharge electrodes performing corona discharge.

According to the present invention, a conventional ion generator which has been rather large can be made relatively simple. However, there is a need for a method and apparatus that can more easily and inexpensively produce ionized water.

[0004] In this apparatus, water that has been subjected to electromagnetic treatment is:
Since it is made to drip from the pipe, it comes into contact with the outside air there, but from the viewpoint of hygiene and the like, it is desired to pass through the closed pipe consistently until ionic water is produced.

[0005] An object of the present invention is to provide a method and an apparatus for producing ionized water which can meet such a demand.

[0006]

That is, an apparatus according to the present invention includes an ionization tube through which mist generated from water passes, and a discharge electrode set inside the ionization tube. Discharge means for causing a discharge between
Condensing means for receiving and cooling and condensing the ionized mist passed through the ionization tube to form ionized water, comprising a cooling tube connected to the ionization tube, wherein the ionization tube Communicates a large-diameter primary ionization portion for performing primary ionization on the fog, a large-diameter secondary ionization portion for further ionizing the primary ionization fog, and a primary and secondary ionization portion. And an intermediate portion having a small diameter for performing the operation.

Further, the present invention comprises an ionization tube through which fog generated from water passes, and a pair of discharge electrodes set inside the ionization tube, so as to generate a discharge between the electrodes. Discharge means, and a condensation means for receiving and cooling and condensing ionized mist passed through the ionization tube to produce ionized water, the cooling means having a cooling tube connected to the ionization tube. In addition, there is also provided an ionized water producing apparatus characterized in that one of the discharge electrodes is extended with respect to one of the electrodes so as to surround the one of the electrodes.

Further, the present invention comprises an ionization tube through which fog generated from water passes, and a discharge electrode set inside the ionization tube, and a discharge for generating a discharge between the electrodes. Means for receiving and cooling and condensing the ionized mist passed through the ionization tube to form ionized water, comprising a cooling tube connected to the ionization tube; A pipe is a large-diameter primary ionization part for performing primary ionization on the fog, a large-diameter secondary ionization part for further ionizing the primary ionization fog, and a primary and secondary ionization part. A primary portion and a secondary ionization portion each have a pair of discharge electrodes, and the primary and secondary ionization portions include a pair of discharge electrodes provided on at least one of the primary and secondary ionization portions. , Square other pole of the electrode relative to the poles of the electrodes to provide a ionized water producing apparatus being characterized in that the extend to surround the electrode of one polarity.

[0009] In the above-mentioned ionized water producing apparatus, the electrode of one of the electrodes may be substantially linear, and the electrode of the other electrode may be a spiral electrode extending so as to surround the linear electrode.

[0010]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described below.
This will be described with reference to the accompanying drawings. FIG. 1 shows an outline of an ionization apparatus 10 according to the present invention. That is, the apparatus 10 includes a mist generating apparatus 12 for generating mist by applying ultrasonic vibration to water, and an ionization tube 14 for performing ionization on the mist generated by the mist generating apparatus.
And a cooling pipe 16 for cooling the ionized mist and returning it to ionized water.

The ionization tube 14 has a large-diameter primary ionization section 16 and a secondary ionization section 18, and an intermediate section 22 connecting them. The primary ionization section 16 and the secondary ionization section 18 have discharge electrodes 24, 26, 28, 30 set through their tube walls. The electrode 24 is connected to an electrostatic generator 32 for generating a high voltage, for example, 20 kV static electricity.
0 is a Tesla coil 34 for generating a high-frequency high-voltage current (for example, a voltage value of 50 kV and a frequency of 0.1-1 MHz).
It is connected to the. On the other hand, the electrodes 26 and 28 are both grounded, so that a large potential difference is generated between the electrodes 24 and 26 and between 28 and 30 so that discharge occurs between the respective electrodes. .

The cooling pipe 16 is provided with a spiral pipe (not shown) for passing cooling water around the pipe wall, whereby the cooling pipe 16 is cooled. A storage tank 36 for collecting ionized water condensed and generated in the cooling pipe is set at a position below the cooling pipe.

The main structure of the ionized water producing apparatus according to the present invention is as described above. Preferably, as shown by the dashed line, these main structural elements are formed by an ultraviolet lamp 3.
It is preferable to set and store in a sterilization box 40 provided with the above.

When producing ionized water using this apparatus, pure water is charged into a mist generator and atomized.
-1 micron). The atomized water is guided through the conduit 42 into the ionization tube 14 where the primary ionization portion 16
The inside is guided downward, and primary ionization is performed by receiving a discharge performed between the discharge electrodes 24 and 26. The primary ionized mist is passed through the middle portion 22 of the ionization tube, guided further down in the secondary ionization portion 18 and between the discharge electrodes 28 and 30 in that portion, and is generated there. It is further ionized by the plasma discharge.

The mist passed through the secondary ionization section is passed through a cooling pipe 16 and cooled. Therefore, the mist passed through the cooling pipe 16 is cooled and condensed, and is generated as ionized water. The generated ionized water drops from the lower end outlet of the cooling pipe, falls into the storage tank 36, and is collected.

FIG. 2 shows another configuration of the discharge electrode. That is, one electrode is helical and extends to surround the other linear electrode. By doing so, the volume electric field ratio of the fog can be increased, and ionization can be performed efficiently.

[0017]

As is clear from the above description, compared to the invention disclosed in the aforementioned Japanese Patent Application No. Hei 7-178410, it is possible to produce ionized water without requiring an electromagnetic treatment device having primary and secondary coils. Therefore, compared to the invention according to the prior application, ionized water can be produced more simply and at lower cost. In addition, since there is no water dripping between the electromagnetic processing device and the plasma discharge device, which is required in the prior application, it is possible to consistently treat the ionized water in a sealed tube until it is produced. Further, by making water into fine mist of 0.1-1 micron, more efficient processing can be performed.

[Brief description of the drawings]

FIG. 1 is a side view showing an outline of an apparatus for producing ionized water according to the present invention.

FIG. 2 is a diagram showing another embodiment of a discharge electrode. 14 --- ionization tube; 16--condensation means (cooling tube).

Claims (4)

(57) [Claims] 1. An ionization tube through which fog generated from water passes, a discharge electrode provided inside the ionization tube, and discharge means for generating a discharge between the electrodes; Condensing means for receiving and cooling and condensing the ionized mist passed through the pipe for ionization, comprising a cooling pipe connected to the ionization pipe, wherein the ionization pipe is Communicating a large-diameter primary ionization portion for performing primary ionization on the mist, a large-diameter secondary ionization portion for further ionizing the primary ionization mist, and a primary and secondary ionization portion. Water producing apparatus having a small-diameter intermediate portion for use in the production. 2. An ionization tube through which fog generated from water passes, and a pair of discharge electrodes set inside the ionization tube, and discharge means for generating a discharge between the electrodes. A condensing means for receiving and cooling and condensing ionized mist passed through the ionization tube to form ionized water, the cooling electrode being connected to the ionization tube; An ionized water producing apparatus characterized in that an electrode of one of the electrodes extends with respect to an electrode of the other of the electrodes so as to surround the electrode of the one of the electrodes. 3. An ionization tube through which fog generated from water passes, a discharge electrode provided inside the ionization tube, and discharge means for generating a discharge between the electrodes; Condensing means for receiving and cooling and condensing the ionized mist passed through the pipe for ionization, comprising a cooling pipe connected to the ionization pipe, wherein the ionization pipe is Communicating a large-diameter primary ionization portion for performing primary ionization on the mist, a large-diameter secondary ionization portion for further ionizing the primary ionization mist, and a primary and secondary ionization portion. A primary portion and a secondary ionization portion each having a pair of discharge electrodes, and one of the pair of discharge electrodes provided on at least one of the primary and secondary ionization portions. Ionized water producing apparatus, wherein a electrode of the other electrode was set to extend so as to surround the electrodes of one polarity relative to the poles of the electrode. 4. The electrode according to claim 2, wherein the electrode of the one pole is substantially linear, and the electrode of the other pole is a spiral electrode extending so as to surround the linear electrode. 3. The ionized water production apparatus according to 3.