KR100287839B1 - Ion generation device - Google Patents

Abstract

PURPOSE: A generator for supplying a large amount of ion sufficiently by using a source of direct current having a specified frequency and a blower is provided. Whereby, a good quality of ion is obtained and this apparatus can be applied to an air purifier, sewage treatment unit or the like. CONSTITUTION: The ion generator comprises: one or a plurality of insulation pipes(210) for absorbing air into one end part(211) and discharging to another end part(212) to smoothly move a generated ion; a coil(220) inserted into an inner surface of the insulation pipe to apply a pulse to the electrode; a heat radiating conductor(230) constructed on the outer surface of the insulation pipe to correspond to the coil to radiate heat generated from the coil. The direct current pulse electrode comprises a direct current voltage of 15,000V or more and a frequency of 500Hz or more.

Description

Ion Generator {ION GENERATION DEVICE}

The present invention relates to an ion generating device, and more particularly, to an ion generating device for collecting ions generated using a DC power pulse and a blower.

In general, the ion generating device generates ions by charging between the anode and the cathode and is used for plating.

Therefore, the conventional ion generating device generates and uses ions by exposing and charging the cathode and the anode in a closed confined space.

Recently, air cleaning and wastewater treatment are using ions. Therefore, there is a need for an ion generating device which generates more ions and supplies them smoothly where necessary than conventional ion generating devices generating ions in a limited space for use in plating and the like.

To this end, the present invention has an object to provide an ion generating device for supplying a sufficient amount of ions using a direct current pulse and a blower having a constant frequency.

1 is a block diagram of an ion generating device according to the present invention.

2 is a structural diagram of an ion generating device according to the present invention.

3 is a cross-sectional view of the ion generator of FIG.

4 is an exemplary view of the heat dissipation conductor of FIG.

5 is another embodiment of the heat dissipation conductor of FIG.

6 is another embodiment of the heat dissipation conductor of FIG.

7 is a state diagram of the heat radiation conductor and the insulation tube.

<Explanation of symbols for main parts of drawing>

100: DC pulse supply unit 200: ion generating unit

210: insulated tube 220: coil

230, 410: heat dissipation conductor 240: insulated tube

300: blower 310: blower

320: blower pipe 330: discharge pipe

In order to achieve the above object, the present invention provides one or more insulated tubes through which wind is sucked to one end and discharged to the other end for smooth movement of generated ions; A coil inserted into an inner circumferential surface of the insulator tube to which a DC pulse voltage is applied; Charged and discharged by a DC pulse voltage applied to the coil to function as a cathode to generate ions inside the insulator tube and to discharge heat generated from the coil to correspond to the coil on the outer circumferential surface of the insulator tube. It provides an ion generating device, characterized in that consisting of a heat radiation conductor is installed.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 1 and 2, the ion generating device according to the present invention includes a DC pulse supply unit 100, an ion generating unit 200, and a blowing unit 300.

The DC pulse supply unit 100 supplies a DC pulse voltage at a constant frequency. In particular, the DC pulse supply unit 100 supplies a DC pulse of 15,000 V or more having a frequency of 500 Hz or more to the ion generator 200 to generate a large amount of ions.

The ion generator 200 is for generating ions, and as shown in FIGS. 1 and 3, a coil 220 receiving a DC pulse voltage output from the DC pulse supply unit 100 is inserted into an inner circumferential surface thereof. The heat dissipation conductor 230 for dissipating heat generated by the coil 220 may include one or a plurality of insulating tubes 210 installed on an outer circumferential surface of the coil 220 to correspond to the coil 220.

That is, the ion generator 200 is the one or more insulated tube 210, the insulated tube 210 is the wind is sucked into the general portion 211 and discharged to the other end 212 for the smooth movement of the generated ions. A coil 220 inserted into an inner circumferential surface of the coil 220 and charged / discharged by a DC pulse voltage applied to the coil 220 to function as a cathode to generate ions in the insulation tube 210. The heat dissipation conductor 230 is installed on the outer circumferential surface of the insulation tube 210 to correspond to the coil 220 so as to discharge heat generated from the coil 220.

At this time, the heat dissipation conductor 230 acts as a cathode.

When the ion generator 200 is implemented by a plurality of insulation tubes 210 to generate a large amount of ions, the ion generator 200 is arranged in parallel as shown in FIG. 2.

At this time, the plurality of insulating tubes 210 are installed vertically, so that when the moisture in the air flows into the insulating tube 210 can be easily discharged to the lower end of the ion generator 200 due to moisture malfunction Can be prevented.

In addition, an insulating layer 240 is formed on the outer circumferential surface of the insulating tube 210 in order to generate more ions in the insulating tube 210, and the insulating layer 240 is mainly an insulating tube or insulating tape. Will be used. That is, the outside of the insulating tube 210 may be wrapped with an insulating tube or insulating tape that is an insulator.

In addition, in order to uniformly generate ions, the interval between the heat dissipation conductor 230 and the coil 220 is constant. For this purpose, the coil 220 is tightly inserted into the inner circumferential surface of the insulation tube 210.

The insulator tube 210 is a tube made of an insulator, for example, a glass tube or a ceramic tube.

The blower 300 supplies air to the general portion 211 of the insulation tube 210 so that ions generated in the insulation tube 210 of the ion generator 200 can move smoothly. As shown in FIG. 2, a blower 310 generating wind and a wind generated from the blower 310 are supplied to one end 211 of the one or more insulating tubes 210. Blow pipe 320 for discharging, and discharge pipe 330 connected to the other end 212 of the insulated pipe 210 to discharge ions discharged from the other end 212 of the one or more insulated pipe 210 )

That is, the blower 300 is a blower pipe 320 for connecting the discharge port through which the wind generated from the blower 310, and one end 211 of each insulation pipe 210, as shown in FIG. The discharge pipe 330 is installed at the other end 212 of each insulation tube 210 so that the generated ions can be supplied where necessary.

Therefore, the blower pipe 320 and the discharge pipe 330 connect the respective insulated pipes 210 of the ion generator 200 with the T-shaped or L-shaped connector 340, so that the inlet and the outlet of the wind become one each. The blower 310 may blow a plurality of insulated pipes 210 and collect and send ions generated where necessary.

The operation of the ion generating device according to the present invention thus constructed will be described.

In order to generate a large amount of ions, the DC pulse supply unit 100 supplies a DC pulse having a frequency of 500 Hz or more to the coil 220 of the ion generator 200.

By supplying a DC pulse of 500 Hz or more and 15,000 V or more, charging and discharging are performed in the coil 220 and the heat dissipation conductor 230, and many ions are continuously generated through the charging and discharging. As described above, supplying a DC power of 500 Hz or more is intended to generate a large amount of ions by rapidly charging and discharging.

That is, since the coil 220 of the positive electrode is charged with the heat dissipation conductor 230 of the negative electrode and an insulator made of the insulating tube 210 is formed therebetween, when the pulse power is supplied, the coil 220 and the heat dissipation conductor 230 are provided. ) Charges and discharges are generated to generate ions.

At this time, the outside of the insulating tube 210 is provided with an insulating tube 240 to properly insulate, so that more ions are generated inside the insulating tube 210. In addition, since the interval between the coil 220 and the heat dissipation conductor 230 is constant, ions are generated evenly distributed in the insulation tube 210.

In addition, the insulating tube 240 formed on the outside of the insulating tube 210 may be formed as a semi-insulator, the insulating tube 240 of the semi-insulating layer so that more ions are generated inside the insulating tube 210. do.

Because ions are generated in the insulator between the anode and the cathode being charged, the ions are generated in the insulation tube 210 between the coil 220 and the heat dissipation conductor 230.

In this case, in order to collect and send ions to a desired place, it is advantageous to generate ions inside the insulating tube 210, so that the insulating tube 24 is a semi-insulating layer which is not completely insulated on the outer wall of the insulating tube 210. Will form.

As such, when ions are generated, sparks are generated at the same time, and the insulation tube 210 becomes very hot, and the heat radiation conductor 230 quickly dissipates heat of the insulation tube 210.

In addition, in the blower 310, the wind enters the inside of the insulated tube 210 through the blower tube 320, and thus the ions generated in the insulated tube 210 exit the insulated tube 210 and discharge the tube. Through 330 is discharged to the outside, that is, necessary.

In other words, the air containing the ions of the insulation tube 210 is supplied to the necessary place through the discharge pipe 330 by the wind blowing from the blower pipe 320. Therefore, the air containing the ions are not mixed with the outside air and the ion content does not fall, so it is possible to supply high quality air having a large amount of ions.

In addition, in order to generate a large amount of ions, as shown in FIG. 2, a plurality of insulating tubes 210 and heat dissipation conductors 230 are used. Arrange with.

On the other hand, one embodiment of the heat dissipation conductor 230 is made up of the upper and lower heat dissipation conductor 410 to facilitate a r as shown in Figure 4, the upper and lower heat dissipation conductor 410 is the insulating tube 210 A coupling groove 411 having a semi-circle shape in the longitudinal direction is inserted into the coupling surface 420 to insert a), and the radiation in the longitudinal direction on the opposite surface of the coupling surface 420 around the coupling groove 411. Shaped heat dissipation wing 412 is formed.

That is, the upper and lower heat dissipation conductors 410 form a plurality of heat dissipation blades 412 to smoothly perform heat dissipation, and form coupling grooves 411 long in the longitudinal direction to correspond to the coil 220. do.

After inserting the insulating tube 210 into the coupling groove 411 of the lower heat dissipation conductor 410, the coupling surface 420 of the upper and lower heat dissipation conductor 410 is coupled to each other by a piece.

In addition, in many embodiments of the heat dissipation conductor 230 is a plurality of heat dissipation blades 412 in the shape of a disk, as shown in Figure 5 coupled to the heat dissipation plate 430 and the inside of the heat dissipation plate 430 ( Insert 210).

In addition, another embodiment of the heat dissipation conductor 230 is a plurality of heat dissipation blades 412 as shown in Figure 6 in the shape of a radial plate and coupled to the heat dissipation tube 430 of the cylindrical shape and the pair of heat dissipation tubes ( Insert the insulating tube 210 between the 430 and then coupled to the piece.

That is, the insulating tube 210 is inserted into the pair of semi-cylindrical heat dissipation blades 412 of the semi-cylindrical heat dissipation plate 430 and fixedly coupled to the piece.

On the other hand, since the insulating tube 210 is made of a very weak material compared to the heat dissipation conductor 230 made of a metal made of glass or ceramic tube, the insulating tube 210 can be easily broken. Therefore, the insertion groove 232 is formed in the end 231 of the coupling groove 411 into which the insulation tube 210 is inserted in the heat dissipation conductor 230, and between the insulation tube 210 and the end 231 of the heat dissipation conductor. Insert the stopper 250.

That is, the stopper 250 is inserted between the insertion groove 232 and the insulating tube 210 to secure the insulating tube 210 while protecting the insulating tube 210, and a molding liquid is inserted between the stopper 250 and the glass tube 210.

At this time, the stopper 250 is made of a cylindrical synthetic resin formed with an insertion portion 251 at the end to be inserted into the insertion groove 232.

As described above, the ion generating device according to the present invention supplies DC power with a frequency of 500 Hz or more and consists of a plurality of insulated pipes, so that not only a large number of ions can be obtained but also ions are generated inside the insulated pipes. By collecting the ions generated by using and supplying them where necessary, the ions can be efficiently used.

Further, the ion generating device according to the present invention can be applied to an air purifying device for removing odor due to the characteristics of ions, and can be applied to a sewage purifying device for purifying clothes by combining with impurities in sewage. That is, the ion generating device according to the present invention can purify the odor and the sewage by spraying the generated ions to the barn, cages, pig farms, landfills, odorous sewage, and sewage treatment plants.

Claims (5)

One or more insulated pipes 210 in which wind is sucked into one end 211 and discharged to the other end 212 for smooth movement of generated ions; A coil 220 inserted into an inner circumferential surface of the insulator tube 210 to which a DC pulse voltage is applied; The battery is charged and discharged by a DC pulse voltage applied to the coil 220 to function as a cathode to generate ions in the insulation tube 210 and to discharge heat generated from the coil 220. Ion generating device, characterized in that consisting of a heat radiation conductor (230) installed corresponding to the coil (220) on the outer peripheral surface of the tube (210). The ion generating device of claim 1, wherein the DC pulse voltage is formed at a frequency of 500 Hz or more at a DC voltage of 15,000 V or more. The ion generating device of claim 1, wherein the plurality of insulating tubes (210) are vertically installed and arranged in parallel so as to easily discharge moisture introduced from the air when inhaling the wind. The ion generating device according to claim 1, wherein an insulating layer (240) is formed between the insulating tube (210) and the heat dissipation conductor (230). The ion generating device according to claim 1, wherein a coil (220) is closely inserted into an inner circumferential surface of the insulating tube (210) in order to maintain a constant distance between the heat dissipating conductor (230) and the coil (220).